This standard applies to all outdoor places of employment. In addition, the following industries are subject to additional requirements in high heat (temperature that equals or exceeds 95 F)
(see Q&A No. 8a and 8b):
The standard's provisions apply at all times when workers work outdoors. Some provisions are triggered at specific times, for instance, the shade requirement described in Q&A No. 7 and the High-Heat Procedures addressed by Q&A No. 8a.
The term indoor is defined in California Code of Regulations Title 8 section as follows: “Indoor” refers to a space that is under a ceiling or overhead covering that restricts airflow and is enclosed along its entire perimeter by walls, doors, windows, dividers, or other physical barriers that restrict airflow, whether open or closed.
Generally, any workplace with a roof and enclosed sides is considered an indoor workplace. Work areas that are not indoors are considered outdoors and covered by California Code of Regulations Title 8, section , Heat Illness Prevention in Outdoor Places of Employment.
For example, a building that provides sufficient ventilation and cooling, either by natural or mechanical means, and blocks exposure to direct sunlight will be considered an indoor workplace. Partial structures such as lean-tos and structures with one or more open sides are outdoor workplaces.
Open areas like agricultural fields, forests, parks, equipment and storage yards, outdoor utility installations, tarmacs, and roads are obvious examples of outdoor workplaces. Outdoor workplaces also include construction sites in which no building shell has been completed and areas of construction sites that are outside of any building shells that may be present. Outdoor areas adjacent to buildings (e.g., loading docks) may also be considered outdoor places of employment.
Yes. They include requirements for employers to provide for drinking water, first aid, and emergency response. There are also requirements tailored to specific industrial operations. Areas where these regulations overlap or augment 8 CCR § will be noted in the more specific sections below.
Some requirements of the standard are triggered by outside temperatures. It is, therefore, critical that employers track the weather and routinely check for approaching heat waves. Heat waves are one of the main causes of heat-related illnesses and fatalities in the state. For example, according to an analysis by Cal/OSHA of heat related illnesses in , 84% of the confirmed occupational heat illnesses in occurred during the July heat wave.
This analysis also identified the key role that supervisors play in preventing worker fatalities due to heat illness. This finding highlights the value of training supervisors so that they can make the fullest use of their supervisory power to control safety on the job. Knowing how to monitor weather reports, making it a daily practice to do so, and taking appropriate action in response to predicted hot weather are all an essential part of a supervisor's training, hence the requirement that this training be provided to all supervisors whose workers perform outdoor work.
The National Weather Service forecasts the temperature in various locations in California. In addition, the National Weather Service’s Heat Risk map provides a forecast risk of heat-related impacts for the week.
The supervisor should use a thermometer to keep track of the temperature at the worksite on hot days. A simple thermometer available at hardware stores can be used to measure the outdoor ("dry bulb") temperature, as long as it is taken in an area where there is no shade. The temperature measurement must be taken in an area with full sunlight and the bulb or sensor of the thermometer should be shielded from direct contact with sunlight (with the hand or some other object) while taking the measurement.
Adequate water is required at all times, regardless of outdoor temperature and must be made available at no cost to the worker.
Water is the body's single best defense against heat other than removing heat exposure itself. In conditions of high heat and strenuous work, the human body can lose over a quart of fluid per hour just by sweating. Continuous replacement of this lost fluid is critical to allowing the body to maintain the life-preserving cooling benefits of perspiration. This is why it is so important to ensure the presence of, ready access to, and consumption of pure, fresh, and cool drinking water.
The water must be potable (i.e., fit to drink), fresh, pure, suitably cool, and provided to workers free of charge. Water must be located as close as practicable to the areas where workers are working. The purpose of these requirements is to encourage workers to drink water often and avoid making the workers interrupt their work in order to do so. To ensure that water is fresh, pure, and suitably cool, Cal/OSHA advises employers or supervisors to visually examine and smell/taste the water and pour some on their skin.
Water must be potable (i.e., fit to drink) and free from odors that would discourage workers from drinking it. If an employer supplies individual water containers, the containers must be clean, and a source of potable water (e.g., a municipal water source) must be readily available. Water from non-approved or non-tested water sources (e.g., untested wells) is not acceptable. If hoses or connections are used, they must be manufacture-approved for potable drinking water systems, as shown on the manufacturer's label.
Water provided to workers, whether by Igloo® or other container, is not required to be maintained at a specific temperature. Rather, the employer should ensure that the water is cool enough to be pleasant and not so cool as to cause discomfort. In hot weather, it is recommended that employers have ice on hand to keep the water cool.
Potable drinking water must always be placed in locations readily accessible to all workers, so that workers can easily drink while working. When a worker has to interrupt work in order to drink, the chances go down that the worker will drink enough water to protect fully against heat illness. Employers are, therefore, encouraged to consider creative means of placing water near working workers (for instance, on harvesting machinery).
During a Cal/OSHA inspection, the inspector may ask the supervisor to describe the factors the employer considered in deciding where to place water. For example, although the employer may state it is impossible to place water stations within rows of crops where workers are working, it may be possible to place the water stations at the end of rows. Because water containers are smaller than shade structures, they can be placed closer to workers than shade structures. Placing water only in designated shade areas or where toilet facilities are located may not be sufficient. When workers are working across large areas, water should be placed in multiple locations. For example, on a multi-story construction site, water should be placed in a safely accessible location on every floor where workers are working.
Employers may supply workers with individual water bottles/containers (preferably insulated) provided hygiene is ensured (i.e., clean bottles for each worker) and a source for water replenishment is readily available. It is not permissible for an employer to require workers to supply their own water or water containers, even if the employer reimburses the workers for the cost.
When unlimited drinking water is not immediately available from a plumbed system or otherwise continuously supplied, the employer must provide enough water for every worker to be able to drink one quart of water, or four eight-ounce cups, per hour.
If an employer chooses not to provide the full-shift quantity of drinking water at the start of a work shift (e.g., two gallons per worker for an eight-hour shift), the standard requires effective written procedures for drinking-water replenishment allowing each worker to drink one quart per hour. In other words, a sufficient quantity of water must always be present and readily accessible allowing every worker to consume at least one quart of water per hour until the water supply has been replenished.
A water-supply procedure that depends on replenishment during the work shift is out of compliance if it is not reliable. An employer is also out of compliance if at any time drinking water is not available to workers, or if the practice is to wait until the water vessel is empty to replenish it. It is similarly impermissible for an employer to replenish the drinking-water supply only when requested by workers.
The standard requires not only that water be provided, but that employers encourage workers to drink it frequently. The importance of this cannot be overstated. Workers are there to work, and many of them may not feel how urgently their bodies need water. The Cal/OSHA Heat Illness analysis showed that although 90% of the worksites had drinking water at the site, 96% of the workers suffering from heat illnesses were dehydrated.
The tendency of workers to be unaware of and/or not respond to their body's need to hydrate is an unfortunate but preventable cause of heat illness.
In their worker training sessions, employers must emphasize the importance of drinking water frequently throughout the day, especially in high heat. By removing any barriers that may exist to access, making the access distance as short as reasonable, and making the water station inviting by using ice and shade, employers can actively facilitate and encourage the frequent drinking of water.
Yes. The following Title 8 standards apply to the provision of drinking water:
These standards require employers to provide sufficient quantities of drinking water in the work settings covered by the particular standard.
When temperatures exceed 80 F, shade structures must be erected if no other shade is readily available. Even if temperatures do not exceed 80 F, employers must still provide timely access to shade if requested by a worker. It is helpful to have the shade erected if the weather is hot enough that the shade can help workers cool off. Employers should monitor predicted weather temperatures in advance (on television, radio or the internet) to know when the temperature is likely to exceed 80 F. Employers are expected to know if the temperature is in fact exceeding 80 F at the worksite.
Shade may be provided by any natural or artificial means that do not expose workers to unsafe or unhealthy conditions and do not deter or discourage use.
For example, buildings, canopies, lean-tos, or other partial or temporary structures that are either ventilated or open to air movement may provide shade for breaks or preventative cool-down rests for outdoor workers. Trees can also provide shade that is superior to artificially provided shade and are accepted as compliant sources of shade if the following conditions are met:
Spots of sunlight are acceptable as long as, overall, the shade provides substantially complete blockage of sunlight. Where trees or other vegetation are used to provide shade, the thickness and shape of the canopy must, given the changing angles of the sun, result in a sufficient shadow being cast to protect workers from the sun during the entire shift.
The interior of a vehicle may not be used to provide shade unless the vehicle is air-conditioned and the air conditioner is running throughout the workday. Similarly, metal storage sheds and other outbuildings do not provide protection from sunlight which meets the definition of shade unless they provide a cooling environment comparable to shade in open air (i.e., they must be mechanically ventilated or open to air movement).
Shade is blockage of direct sunlight. Blockage is sufficient when objects do not cast a shadow in the shaded area. An enclosed area used to provide shade must allow cooling at least comparable to the cooling that would be provided in a shaded unenclosed area in the same location.
Shade must be easy for workers to reach and its location must not deter or discourage access or use. Workers should not have to encounter any obstacles or hazardous or unreasonably unpleasant conditions to reach the shade or while resting in it. For example, workers should not have to cross traffic or waterways to reach the shade nor should it be located next to portable toilet facilities or where workers would sit on wet or muddy ground or come in contact with branches, brush, and thorns.
The shaded area must let workers assume a comfortable posture and must not cause exposure to another health or safety hazard. Therefore, the shade requirement cannot be met by using areas underneath mobile equipment, like a tractor, or areas that require workers to crouch in order to sit fully in the shade.
The shade, whether natural or structural, must be as close as practicable to where workers are working, given the working conditions and layout of the worksite. During a Cal/OSHA inspection, the inspector may ask the supervisor to describe the factors the employer considered in deciding where to place shade structures. Because shade is more portable than bathroom facilities, it can and should be placed closer to where workers work. This may involve placing shade structures in multiple areas over large worksites and/or moving the structures as the work area changes (such as movement across fields and rows).
Employers must ensure there is enough shade for all workers taking a rest and recovery period (breaks) at any one time to sit comfortably and fully in the shade without touching each other. This does not mean that employers are required to provide enough shade to accommodate all of the workers on the shift at the same time. Employers may, for example, rotate the breaks among workers. They may also erect additional structures on an as-needed basis. Any such procedure must be clearly and accurately described in the employer's written Heat Illness Prevention Plan.
The rules and recommendations described above for breaks also apply to meal breaks. The only difference is that employers are required to provide shade for all workers who choose to remain in the general area of work or in areas designated for recovery and rest periods. Employers may rotate workers in and out of meal periods, like with recovery and rest periods. Employers are not required to provide shade for workers who choose to spend meal periods in their own air-conditioned vehicles. However, employers may not require or pressure workers to eat their lunch in their own vehicles or go off site to eat.
When providing a shade structure would be unsafe or infeasible, the employer may provide alternate access to shade that provides equivalent protection.
For example, it may be unsafe to erect a shade structure near the edge of a trench or ravine, or when high winds could cause a shade structure placed near workers to blow away and hit them or create a hazard to others in the area. Furthermore, establishing a shade structure on a continuous basis may be infeasible for workers who constantly move from site to site (e.g., meter readers or irrigation installers). In these cases, the employer must document this determination and specify what alternatives to shade will be provided to afford equivalent protection.
Nonagricultural employers may provide cooling measures other than shade if they can demonstrate that the alternative is at least as effective as shade.
For example, misting machines are acceptable when the employer can demonstrate that they are at least as effective as shade at allowing the body to cool.
The employer is required to allow and encourage workers to take a cool-down rest in the shade for a period of no less than five minutes at a time when they feel the need to do so to protect themselves from overheating. Waiting until symptoms appear before seeking shade and recovery creates a significant risk of developing heat illness. It is crucial that workers not be rushed while taking the cool-down rest, since the purpose of the cool-down rest in the shade is to reduce heat stress on the worker. Shade removes sunlight as a source of heat, and since people produce more metabolic heat while working, resting out of direct sunlight reduces heat stress while also reducing the heart rate.
Encouraging workers to take a cool-down rest in the shade is of primary importance particularly for workers who are paid on a piece-rate basis, as they would be less inclined to use this preventive rest. Water should be available in the rest area so that workers are encouraged to drink more water.
Workers must be monitored during a cool-down rest and asked if they are experiencing any symptoms of heat illness, including simple fatigue. If any signs or symptoms of heat illness are observed or reported, the employer must not order the worker back to work and must continuously observe the worker until the signs or symptoms have abated. Common early signs and symptoms of heat illness may include pale skin, heavy sweating, headache, muscle cramps, and fatigue. If no sign or symptom of heat illness is observed or reported, monitoring may be periodic, rather than continuous.
If a worker exhibits or complains of any sign or symptom of heat illness, appropriate first aid, and emergency response procedures (if necessary) should be initiated without delay. Progression to more serious illness can be rapid and can include altered coordination and speech, mental confusion, unusual behavior, nausea, vomiting, hot dry skin, unusually profuse sweating, loss of consciousness, and seizures. The affected worker may be unable to self-diagnose these problems.
If heat illness is suspected, emergency medical personnel should be contacted immediately. No worker with signs or symptoms of heat illness should be left unattended or sent home without being offered onsite first aid or provided emergency medical services, as discussed in subsection (f) of 8 CCR § (see Q&A No.9).
"Preventative cool-down rest periods" at agricultural worksites are discussed in subsection (e) of 8 CCR § (see Q&A No.8d).
High heat procedures apply to the following industries:
When temperatures reach or exceed 95 F, employers listed in the industries noted above must implement the high-heat preventive procedures listed in subsection (e) of 8 CCR § and described below:
During periods of high heat, it is crucial that workers be monitored for early signs and symptoms of heat illness to help ensure that sick workers receive treatment immediately and progression to serious illness is arrested. If a worker suffers syncope (fainting), disorientation, loss of consciousness, or other symptoms of heat illness while working unobserved, initial medical treatment may be delayed, resulting in a serious or fatal illness.
Because each worksite is unique, the standard gives employers options and flexibility in observing and monitoring workers. When workers work in small groups of no more than 20 workers, direct observation by a supervisor or designee may be sufficient. When there are too many workers to allow direct observation, the employer may use the buddy system and pair up workers. With the buddy system, the employer must train the workers to stay in contact, observe each other throughout the day, and immediately report any signs or symptoms of heat illness. For workers who are required to work alone, the employer may communicate with the worker by radio or cell , provided there is adequate coverage. The worker must be contacted regularly and as frequently as practicable throughout the day, since a worker in distress may not be able to summon help on his or her own.
Employers may use different methods to monitor for heat illness. Whatever method is used, the employer must be able to ascertain the condition of workers at regular intervals and provide emergency services when a worker reports symptoms of heat illness or is unable to respond.
All workers must be trained to recognize the signs and symptoms of heat illness and must be allowed to call for emergency medical services when necessary. If, however, all workers in a crew are designated to call for emergency medical services, many will be reluctant to do so. Therefore, employers should specifically assign one or a small number of workers per crew to call for emergency medical services. A designated worker may be either supervisory or non-supervisory.
Pre-shift meetings are meant to provide supervisors and workers with a brief review of high-heat procedures. The meetings are not meant to review every element previously covered in regular training or in orientation. The employer may determine whether the training is required based on the predicted temperature in the area.
Topics that should be covered in pre-shift meetings include staying hydrated and taking cool-down rests, identifying the workers who should call for emergency medical services when needed, and how workers will be observed. For workers working remotely, the employer may conduct pre-shift meetings by cell or radio.
When temperatures reach or exceed 95 F, employers must provide one ten-minute "preventative cool-down rest period" every 2 hours. During the first 8 hours of a shift, the cool-down periods may be provided at the same time as the rest periods already required by Industrial Welfare Commission Order No. 14 (8 CCR §). Such rest periods must be counted as hours worked.
If workers work longer than 8 hours, the employer must provide an additional 10-minute cool-down rest period every 2 hours. For example, if the shift extends beyond 8 hours, an additional rest period is required at the end of the eighth hour of work. If the shift extends beyond 10 hours, another is required at the end of the tenth hour.
Employers must ensure that workers actually take the cool-down rest periods required under this section. Merely offering the opportunity for a break is not enough.
Employers are required to provide additional breaks as soon as the temperature equals or exceeds 95 F. For example, even if the temperature does not reach 95 F until the last half of an eight-hour shift, the employer must ensure that workers take cool-down rest periods starting at the end of the eighth hour of work if the shift will last longer than eight hours.
Cal/OSHA does not require employers to keep records of breaks issued under this section, but doing so is the best practice and would benefit them.
The importance of rapidly and effectively obtaining emergency medical services in the event of a serious injury or illness cannot be overstated. Particularly at non-fixed worksites or at sites that are difficult to locate or access, the employer, having evaluated whether the worksite is served by the 911 system, needs to be ready to contact and communicate with emergency responders.
Emergency medical services must be provided as quickly as possible if a worker suffers heat illness. The employer's procedures must include contacting emergency medical services when necessary, as well as taking immediate steps to keep a stricken worker cool and comfortable once emergency service responders have been called. The goal is to stop the rapid progression to more serious illness, which can include mental confusion, loss of consciousness, and seizures.
As a result, employers must ensure that supervisors and workers are trained to recognize the signs and symptoms of heat illness, take steps immediately to prevent the progression of heat illness, provide basic first aid (such as cooling towels and shade), obtain emergency medical services, and not allow a worker with signs or symptoms of heat illness to be left alone or sent home without being offered onsite first aid or provided with emergency medical services. Employers, however, are not required to provide medical personnel on site, and supervisors and workers are not expected to have medical expertise to diagnose heat illness.
Establishing emergency response procedures is particularly important at non-fixed or remote worksites or worksites that are difficult to locate or access. If workers cannot reach emergency medical services directly (because cell coverage is inadequate, for example), the employer must designate a person who can immediately contact emergency services on behalf of the workers and can provide emergency services with accurate directions to the worksite. The workers must be able to reach this person quickly (such as by radio) to request that emergency medical services be summoned.
If, however, workers are able to contact emergency medical services directly, they must be allowed to do so in an emergency and must not be required to contact a supervisor first.
Employers must be prepared to transport workers safely to a place where they can be reached by an emergency medical provider where necessary. Mobile crews must be provided with a map of their location or detailed, clear, and precise directions that can be given to emergency responders.
Employers should also be aware that the following title 8 regulations require first aid and emergency responses in specific industries:
Acclimatization is a process by which the body adjusts to increased heat exposure. The body needs time to adapt when working in hotter environments. Workers are more likely to develop heat illness if they are not allowed or encouraged to take it easy when a heat wave strikes or when starting a job that newly exposes them to heat. Acclimatization is fully achieved in most people within 4 to 14 days of regular work involving at least 2 hours per day in the heat.
Employers must be vigilant, especially with new workers who are not acclimatized and during heat waves. A supervisor or designee must closely observe workers. The commonly-understood definition of “observation” includes verbal communication as well as visually checking on a worker. Best practices include finding ways to lessen the intensity of workers' work during a heat wave and during their first two weeks work in a hot environment.
For purposes of this section, "heat wave" means any day in which the predicted high temperature for the day will be at least 80 F and at least 10 degrees Fahrenheit higher than the average high daily temperature for the preceding five days.
Employers must train all workers, both supervisory and nonsupervisory, on the risk factors for heat illness, signs and symptoms of heat illness, methods to prevent heat illness, and policies and procedures established to comply with this regulation. Training must be provided before the beginning of work involving a risk of heat illness. Training that is given close in time to the hot season is more effective than training given during colder seasons without follow-up refresher training. As a best practice, some employers use a daily "tailgate meeting" approach for the refresher training, starting out each work shift with a brief safety reminder about issues considered particularly relevant to the work to be performed that day.
The basic test of training is its effectiveness. Cal/OSHA evaluates compliance by examining both content and how it is presented. To be effective, training must be understood by workers and given in a language the workers understand. The test of compliance is whether training has occurred, whether the required content has been provided, and whether the training has been effective in communicating the essentials to workers.
To evaluate compliance, Cal/OSHA personnel ask supervisory and nonsupervisory workers about required training elements. The questions are designed to determine whether workers received training through methods generally recognized as effective and whether they understood its content. Inspectors will not expect all answers to be correct but will look for indicators that the employer has made a good-faith effort to communicate all the essential information.
Employers must ensure that their work procedures are consistent with the information provided in the training.
Cal/OSHA recommends that employers maintain records of the training required in this subsection, as specified in 8 CCR § (on Injury and Illness Prevention Programs).
There are additional topics that supervisors must be trained on. Such training is crucial: the Cal/OSHA Heat Illness analysis showed that 63% of the supervisors of workers who died from heat stroke had not been trained in the prevention of heat illnesses.
The additional topics for supervisors are as follows:
All workers and supervisors must be trained on every detail of the employer's emergency response procedures.
The employer must develop, put in writing, and implement effective procedures for complying with the requirements of this standard. A compliant Heat Illness Prevention Plan (HIPP) includes the following subsections of 8 CCR §:
A heat illness prevention plan that is little more than a restatement of the safety orders does not satisfy the standard; instead, it must be specific and customized to the employer’s operations. Workers and supervisors must be trained in these procedures so they understand and can implement the employer's plan. The most successful employers teach and make their system work using a teamwork approach.
The HIPP must be written both in English and in the language understood by the majority of workers. It must be available to workers at the work site, as well as to representatives of Cal/OSHA upon request. The plan will be considered available at the work site if, for example, it is accessible on a cell or other electronic device that is available for workers to use for this purpose upon request.
The HIPP may be integrated into the employer's Injury and Illness Prevention Program required under 8 CCR §.
Cal/OSHA offers a Written Model Program that can be used to help develop an HIPP.
These questions and answers address a number of questions that have been brought to the attention of the Joint Committee for Medicinal Products for Human Use / Committee for Medicinal Products for Veterinary Use Quality Working Party (QWP) by marketing-authorisation holders (MAHs) or European Economic Area (EEA) competent authorities, on matters related to the quality of medicines. They have been developed and are maintained by the QWP.
They provide the EEA's harmonised position on issues that can be subject to different interpretation or require clarification, typically arising from discussions or correspondence during assessment procedures.
If a question is not addressed, marketing-authorisation holders are encouraged to contact the European Medicines Agency (EMA) for further information.
These questions have been produced to provide clarification or additional information, and should be read in conjunction with the European Pharmacopoeia, quality guidelines and other guidance documents.
Key:
The Q&A applies to patients of any age. It elaborates on the issue raised in the Guideline on pharmaceutical development of medicines for paediatric use.
When the feasibility of administering a particular medicinal product through an enteral feeding tube is to be investigated, feasibility studies should address the following:
Ease of administration
Product modification
Tube blocking
Dose recovery & flush volumes
Physicochemical compatibility
General considerations for feasibility studies
It is not necessary to include all combinations of tube type (commonly used tubes are sufficient), dose and flush volumes; an appropriate design of experiments, with justified bracketing and/or worst-case approach, could be acceptable. For example, a worst-case approach to study ease of administration and tube blocking might consider a large dose of the medicinal product administered via a small lumen tube, with a closed end and holes at the side (a common design of enteral tube).
Where feasibility studies have been performed with enteral tubes, the following should be included in the product information:
SmPC Section 4.2 Posology and method of administration
SmPC Section 6.6 Special precautions for disposal and other handling
Patient Information Leaflet (PL) Section 3 (How to take [name of the medicinal product])
The PL should provide relevant information for patients/caregivers on administration of the medicinal product through an enteral feeding tube.
The QWP considers that two different tablet appearances (tablet shape, dimensions or colour) of the same product (same name, same packaging details, same marketing authorisation number) may confuse patients (or users of veterinary medicinal products). Such confusion is considered to have a negative effect on therapeutic adherence and therefore considered as a risk to public and/or animal health. Acceptance of such different tablet appearances in the specification of a single strength product would formally also allow the company to dispense these two appearances in the same container/blister, which may even cause greater confusion. In addition, it is not clear to which extent such different appearances would have an effect on patient / user acceptability.
Moreover, the introduction to the variation classification guidelines (/C 223/01) includes the following statement: "References in this Annex to changes to the marketing authorisation dossier mean addition, replacement or deletion, unless specifically indicated." For the purpose of illustration and comparison, change code B.II.a.1 (Change or addition of imprints, bossing or other markings including replacement, or addition of inks used for product marking.) includes specific reference to addition, which means that tablet markings can be added if not currently present. However, change code B.II.a.2 (Change in the shape or dimensions of the pharmaceutical form) does not include any reference to addition. Therefore, in view of this specific absence and taking into account the highlighted introductory text, this could be interpreted as meaning that any change to the shape or dimensions of the pharmaceutical form cannot include the addition of an additional/alternative shape but only replacement. This is also true for A.2 (Change in the (invented) name of the medicinal product) where only a change is referred to and where only replacement is possible.
In the case of applications for more than one tablet strength, the different tablet strengths should be distinguishable at a level sufficient to avoid mistakes between the different strengths by the final user. Distinguishing tablet strengths by colour / shape and marking / embossing is preferable.
No. The mixing of active substances that can exist and are produced on their own should be considered as the first step of the manufacture of the finished product.
It should be noted that the definition of active substance given in part II of the European Union (EU) good-manufacturing-practice (GMP) guide (active substances) states that an active substance is a substance or a ‘mixture of substances’, but this definition takes into account cases when active substances are not single chemically defined substances (e.g. herbal extracts) and it is not meant to allow a mixture of chemically defined active substances to be considered as a single active substance.
As a consequence of what is stated above, the mixing of active substances is subject to compliance with part I of the EU GMP Guide (finished products) and it is not possible to present a single active substance master file for the mixture.
Batch-to-batch consistency of the finished product and compliance with the ± 5% limit on active substance content specified by Regulation (EU) /6 should be ensured unless otherwise justified. When the active substance has a range of greater than ± 5% permitted in the active substance specification, rendering it impossible for the finished product to comply with the Regulation requirement, or situations when the assay method is a microbiological one and it is not possible to correlate activity to weight, the inclusion of excipient(s) is strongly recommended to address the issue. This will ensure that the active substance content is in line with the Regulation requirements and therefore ensure the correct dosage of the veterinary medicinal product.
Data on the in-use stability of such products should be generated through a dedicated in-use stability study under long-term conditions when there is an indication from stability and/or stress studies that the drug product may be susceptible to deterioration. If there are no such indications, in-use stability studies do not need to be undertaken.
The length of the in-use stability studies will be dependent on the intended use of the drug product. An in-use shelf life should only be set if necessary, i.e. when significant changes as defined in ICH Q1A (R2), or veterinary VICH GL3 as relevant, are observed.
Yes. Storage without the protection of the immediate container is considered as a worst case scenario, and can in some instances be used to assess the need for an in-use shelf life. Such studies are relevant as, in clinical practice, oral solid dosage forms may need to be stored in multi-compartment compliance aids or multi-dose dispensing packages to ensure adequate drug adherence, avoid medication errors and/or ease medication management. If no relevant change is observed after 3 months of open dish storage, no in-use shelf life is necessary. If there are relevant changes, normal in-use studies with repeated opening and closing of the container as outlined above are required to establish an in-use shelf life. The conditions of the open dish studies should be controlled in order for the results to be comparable. Open-dish studies at 25 °C/60% RH are considered to be acceptable without further justification as constant exposure to humidity can be regarded as a worst-case scenario.
An in-use shelf-life should only be claimed when significant changes as defined in ICH Q1A (R2), or veterinary VICH GL3 as relevant, are observed.
Examples
To comply with this Q the in-use study should be performed according to Questions 2 or 3 at the applicant’s discretion. When no relevant deterioration is observed an in-use shelf-life is not necessary. No claims should be made in the SPC and questions on the introduction of an in-use shelf-life should not be raised by the Authorities.
In this example an in-use shelf-life of x months in the SPC would be warranted.
An assessment should be made on a case-by-case taking into account the intended use of the medicinal product (see Question 2).The assessment should be based on the overall stability of the drug product and the rate of degradation observed in the in-use studies. An in-use shelf-life should be set if out of specification results are expected based on the observations made. Too short in-use studies, where the intended use of the medicinal product has not been taken into account, are not an acceptable justification for a short in-use shelf life.
No, this decision is not at the applicant’s discretion. Such limitations should be introduced only when strictly necessary, due to the possible implications of in-use shelf lives to patients and to the National Health Care Systems.
The quality of finished products containing known active substances must be addressed in the application file in the same way as for products containing new active substances. Literature data, if available, can be used to address active substance/product related issues such as polymorphism data, active substance-excipient incompatibility data, etc.
The Marketing Authorisation Holder/Applicant must take full responsibility for the finished product, including active substance(s), especially for those aspects, which rely on product knowledge and competence, including development, manufacturing, quality control and stability data. As is the case in all product applications, it is the responsibility of the Marketing Authorisation holder/ Applicant to provide sufficient documentation, justification and data to support their application.
The quality documentation should be assessed based on its own merit in accordance with the principles laid down in the current quality (V) ICH/EU guidelines and Ph. Eur., where applicable. In the specific case of generic or hybrid products, for comparability with reference product, the Applicant should refer to the bioequivalence guideline (CPMP/EWP/QWP//98 for Human & EMA/CVMP/016/ for Veterinary) and substantiate the link between the generic and the reference product in the quality part of the generic or hybrid application.
Impurity levels in finished products containing known active substances should be justified by the Ph. Eur. monographs and by taking into account, the principles described in the current (V) ICH/EU guidelines.
It is possible for a generic or hybrid product to have a different impurity profile from the reference product if the differences do not lead to a safety concern.
Where an impurity exceeds the qualification threshold as per ICH Q3B/VICH GL11, full toxicological qualification or other adequate information about the safety of this impurity (for example reference to published literature) should be provided.
In addition, a specification limit above the qualification threshold can be justified by demonstrating that the relevant impurity is present in the generic or hybrid product at/or below the level determined in the reference product. To carry out this comparison with the reference product, it is recommended to select samples of the reference product close to the end of shelf life, which have been stored in accordance with the conditions of storage described in the reference product SmPC/SPC. Identification of the impurity should be performed in an unequivocal way (e.g. LC/MS) in both the reference and generic or hybrid product. The analytical method used to perform the comparison should be fully validated. The impurity may be considered as qualified at the levels observed in the reference product and it should be assured that these levels are not exceeded at the end of estimated shelf life of the generic or hybrid product.
This Q&A outlines the quality requirements for co-processed excipients (CoPE) used in solid oral dosage forms in both human and veterinary medicinal products. The use of CoPEs in pharmaceutical formulations is considered to have a higher degree of risk than using individual excipients due to several factors: for example complexity of composition, quality control, formulation development and stability issues. The Q&A aims to harmonise and quality clarify dossier requirements for CoPEs using a risk-based approach. It defines three risk categories for the CoPE and the risk factors the MAH/applicant should consider to identify the adequate risk category, and the related quality dossier requirements, which need to be provided by the MAH/applicants as part of new MAA or variations.
The chapters of the European Pharmacopoeia (Ph. Eur.) that describe materials and containers are not exhaustive with regard to all different types of plastic materials and additives. Reference to the specifications published in the Ph. Eur. is therefore not always possible. As outlined in the Ph. Eur. general notices 1.3, it is not obligatory that only materials complying with a given specification in a chapter of the Ph. Eur. can be used as immediate packaging materials. Materials with a different formulation, complying with a different specification may be used, if justified, and subject to agreement by the competent authority.
For solid oral dosage forms and solid active substances, it has been agreed by the Joint Committee for Medicinal Products for Human Use / Committee for Medicinal Products for Veterinary Use Quality Working Party that plastic materials compliant with the relevant European Union (EU) food legislation relating to plastic materials and articles intended to come into contact with foodstuffs are considered acceptable. A specification elaborated in accordance with the provisions described in the EU Guideline on plastic immediate packaging materials should be laid down.
Does the European Medicines Agency / Committee for Medicinal Products for Veterinary Use guideline on development pharmaceutics for veterinary medicinal products and its annex decision trees for the selection of sterilisation methods prevent the use of heat-labile plastic packaging materials and aseptic processing for sterile veterinary medicinal products? VUpdate January : This Q&A has been superseded by the Guideline on the sterilisation of the medicinal product, active substance, excipient and primary container. Please refer to this guideline for further information.
Ensuring the sterility of medicinal products is the main issue when considering the packaging for sterile products, and therefore the method of choice for the production of any sterile products should be terminal sterilisation.
The European Medicines Agency / Committee for Medicinal Products for Veterinary Use Note for guidance: Development pharmaceutics for veterinary medicinal products and its annex Superseded annex to note for guidance on development pharmaceutics: Decision trees for the selection of sterilisation methods currently state in the introduction to the annex that, “the use of an inappropriate heat-labile packaging material cannot in itself be the sole reason for adoption of aseptic processing. Manufacturers should choose the best sterilisation method achievable for a given formulation and select the packaging material for the product accordingly. However, it may be that the choice of a packaging material for a given product has to take into account factors other than the method of sterilisation. In such cases these other factors need to be clearly documented, explained and scientifically justified in the marketing authorisation dossier.”
Aseptic processing cannot be considered as a simple replacement for terminal sterilisation. The European Pharmacopoeia (Ph. Eur.) general text 5.1.1: methods of preparation of sterile products states that, “wherever possible, a process in which the product is sterilised in its final container (terminal sterilisation) is chosen,” and that, “if terminal sterilisation is not possible, filtration through a bacteria-retentive filter or aseptic processing is used; wherever possible, appropriate additional treatment of the product (for example, heating of the product) in its final container is applied.” Such a combination of aseptic processing with non-standard lower temperature heat treatments, either before aseptic filling, or after aseptic filling, should be pursued where possible in line with the recommendations of the Ph. Eur.
The guideline therefore does not prevent the use of heat-labile packaging materials for sterile products, but there must be justified reasons for having such packaging for sterile products, and these must be supported by the overall benefit:risk balance of the product.
Update January : This Q&A has been superseded by the Guideline on the sterilisation of the medicinal product, active substance, excipient and primary container. Please refer to this guideline for further information.
Terminal sterilisation of the primary packaging, used subsequently during aseptic processing of the finished product, is a critical process and the sterility of the primary container is a critical quality attribute to ensure the sterility of the finished product. Both need to be assured for compliance with relevant Pharmacopoeial requirements for the finished product and product approval.
The site where sterilisation of the packaging materials takes place may not have undergone inspection by an EU authority and consequently may not hold an EU GMP certificate in relation to this activity1.
When GMP certification is not available, certification that the sterilisation has been conducted and validated in accordance with the following ISO standards would be considered to provide an acceptable level of sterility assurance for the empty primary container:
It is the responsibility of the user of the manufacturer of the medicinal product, to ensure the quality, including sterility assurance, of packaging materials. The site where QP certification of the finished product takes place, and other manufacturing sites which are responsible for outsourcing this sterilisation activity, should have access to the necessary information to demonstrate the ongoing qualification status of suppliers of this sterilisation service. This should be checked during inspections.The Competent Authorities may also decide, based on risk, to carry out their own inspections at the sites where such sterilisation activities take place.
Dossier requirements
The following details regarding the sterilisation of the packaging components should be included in the dossier:
In the absence of GMP certification or confirmation that the component is a CE-marked Class Is medical device, certification that the sterilisation process has been conducted and validated in accordance with the relevant ISO standards should be provided.
1Sites located in the EU which perform sterilisation of primary packaging components only are not required to hold a Manufacturer’s/Importer’s Authorisation (MIA). Sites located in the EU, which carry out sterilisation of medicinal products, are required to hold a MIA in relation to these activities.
The Q&A relates to interpretation of the Note for Guidance: Maximum shelf-life for sterile products for human use after first opening or following reconstitution (CPMP/QWP159/96 corr.). These Q&As should be followed to provide consistent in-use storage details in the Product Information for parenteral products, as described in the note for guidance.
The proposed in-use shelf life should preferably be covered by the results of chemical and physical in-use stability tests; however other scientific rationale could be acceptable. The companies should investigate in-use shelf-life periods and establish how long the sterile products are stable after first opening or following reconstitution and/or dilution, in terms of physical, chemical aspects, while ensuring that microbiological stability is assured and meets the needs in actual (e.g. hospital) practice.
Unless otherwise justified stability after first opening / reconstitution / dilution should be investigated at least at room temperature (about 25°C) as well as in refrigerator (2 to 8°C) to determine if, for how long and at which conditions, the prepared ready to administer product can be stored until actual application to the patient.
Where a product is reconstituted and then diluted separate studies should be performed accordingly, taking into account the worst-case scenario (e.g. using suitable solvents for drug product at highest and lowest concentrations in different packaging materials etc.).
The outcomes of the studies should be incorporated into the Product Information. If it has been demonstrated that reconstituted/diluted product cannot be refrigerated the statement “Do not refrigerate” should be included in product information.
Even though the current Note for Guidance on In-use stability testing of human medicinal products (CPMP/QWP//99) is applicable for medicines in multidose containers similar principles could be applied also for sterile products that require supporting data after first opening or following reconstitution or dilution. Furthermore, the following is referenced in this guidance: As far as possible the test should be designed to simulate the use of the product in practice taking into consideration the filling volume of the container and any dilution/reconstitution before use.
Companies should provide data that support product specific scenarios which could be anticipated in actual practice such as time needed between first opening/reconstitution in the hospital pharmacy and administration to the patient. The applied in-use shelf-life requested to be included in the SPC should not be longer than what is needed in actual practice.
In principle, only the texts provided in the guideline should be used in the Product Information. Thus, depending on the product type and length of in-use shelf-life period demonstrated adequate wording as foreseen in Note for Guidance should be used. The in-use shelf life should be clearly and unequivocally stated.
It is always important to highlight that in-use storage times and conditions are the responsibility of the user and it is also preferred that sterile products for human use after first opening or following reconstitution or dilution are to be used immediately. However, the MAH should establish in-use shelf-life periods based on the needs in actual practice for the cases the method of opening/reconstitution/dilution precludes the risk of microbial contamination and the prepared ready to administer product can be stored for longer periods.
It should also be noted that storage in a refrigerator after first opening/reconstitution/dilution is best practice unless it has been demonstrated that the product cannot be refrigerated (the warning is accordingly added in the Product Information).
If the product is photosensitive, also considering after reconstitution/dilution, appropriate precautionary measures needed to mitigate exposure to light has to be described.
The “General” text should be used for unpreserved sterile products (including also preparations for infusion or injection) where
In these cases, the text ”longer than 24 hours, unless reconstitution” and/or ”at 2 to 8°C” of the “Specific text for preparations for infusion or injection” does not apply and that option can thus not be used.
Example
Data provided in the dossier demonstrated chemical and physical in-use stability for 12 hours at 25°C, and that the product after first opening / reconstitution / dilution is not stable at +2°C to +8°C.
Recommended wording:
“Chemical and physical in-use stability has been demonstrated for 12 hours at 25°C.
From a microbiological point of view, unless the method of opening/ reconstitution/ dilution precludes the risk of microbial contamination, the product should be used immediately.
If not used immediately, in-use storage times and conditions are the responsibility of user.”
“Do not refrigerate”
The “Specific text for preparations for infusion or injection” should be used for unpreserved sterile products for infusion or injection where
Example
Data provided in the dossier demonstrated chemical and physical in-use stability for 36 hours at +2°C to +8°C and for 18 hours at +25 °C.
Recommended wording:
“Chemical and physical in-use stability has been demonstrated for 36 hours at 2 to 8°C or for 18 hours at 25 °C.
From a microbiological point of view, the product should be used immediately. If not used immediately, in-use storage times and conditions prior to use are the responsibility of the user and would normally not be longer than 24 hours at 2 to 8°C, unless reconstitution / dilution (etc.) has taken place in controlled and validated aseptic conditions.”
NB! It should be kept in mind that the prepared ready to administer product can be stored up to 36 hours at +2°C to +8°C or for 18 hours at +25 °C only if reconstitution / dilution (etc.) has taken place in controlled and validated aseptic conditions. In all other cases the product has to be used within 24h and it has to be stored only in refrigerator.
This wording applies for multidose sterile products which contain preservative and for sterile products which are intrinsically self-preserving e.g. eye drops.
Preservative effectiveness (according to the Ph. Eur.) should be demonstrated during development using drug product samples where the preservative concentration is at or below its lower specification limit and also when intrinsic self-preserving properties are claimed.
The in-use stability declared in the Product Information should be based on the results of chemical, physical, and microbiological in-use stability tests demonstrated in the MA dossier. This should always include evidence or scientific rationale to justify whether the product can or cannot be stored at 2 to 8ºC.
The in-use shelf life should be clearly stated and be based on either physical and chemical stability or microbiological stability, whichever is shorter.
Example
Data provided in the dossier demonstrated microbiological stability 28 days and chemical and physical stability of 3 days.
The acceptable in-use shelf-life is 3 days. 28 days should in this case not be mentioned in the Product Information.
If the reconstituted/diluted product cannot be refrigerated the statement “Do not refrigerate” should be added.
The recommended wording:
“Chemical and physical in-use stability has been demonstrated for 3 days at 25°C. Once opened, the product may be stored for a maximum of 3 days at 25°C. Other in-use storage times and conditions are the responsibility of the user.
Do not refrigerate (if applicable).”
No, in principle it is not acceptable to compensate for insufficient quality of raw materials (glass containers, rubber stoppers) or insufficient product development (which results in, for example, the formation of glass particles or the introduction of rubber in the finished product) by a user instruction to apply a specific filter prior to administering the product to a patient (or animal).
It is the responsibility of the applicant to develop a product of adequate quality and this includes the container-closure system. In certain cases a modification of the original formulation might be required to assure optimal compatibility with the primary packaging material. This responsibility cannot be partially transferred to the user/patient by an avoidable instruction. The use of a specific filtration step for this purpose may only be considered acceptable by the competent authorities in specific circumstances, for example, temporarily during redevelopment of a product with a high medical need.
The use of a specific filtration step for other purposes is not within the scope of this Q
Where relevant, the issue of glass delamination should be addressed in sections 3.2.P.2 and 3.2.P.7 (or veterinary equivalent) of the Marketing Authorisation dossier. It is noted that available scientific data indicate that glass delamination is commonly related to insufficient quality and consistency of glass vial manufacturing, and that data suggest that intra-batch consistency of a batch of vials may not always be guaranteed. In addition, certain formulations (especially those containing citrate, phosphate, or acetate or having a high ionic strength) seem to introduce an inherent risk.
This Q&A provides points to consider for the requirements of multidose containers for preservative-free eye drops designed to prevent microbial contamination of the sterile contents and to minimise microbial growth on the internal and external wet surfaces of the dropper nozzle throughout the in-use shelf life.
For other aspects of eye drop container quality and safety e.g. usability, extractables and leachables, see other guidance, including QWP Q&A “What information on the functional qualities of plastic containers for eye drops should be included in the MAA dossier?”
1.1.1. An explanation should be provided how the container throughout the in-use shelf life:
Specifically, the delivery mechanism and functions of the container, and if applicable the inclusion of antimicrobial substances (e.g. silver), should be described.
1.1.2 For containers relying on a physical barrier feature, such as valve and pump systems, the flow path of the product out of the container and air intake into the container should be clearly delineated. The mechanism for ensuring sterility of air entering the container (venting) should be described.
Video models of air and liquid flow may also be used to provide information in an easy, understandable manner.
Appropriately scaled cross-sectional drawings should be provided.
1.2.1 A failure mode and effects analysis, or equivalent, should be performed with respect to the container consistently delivering eye drops of appropriate microbiological quality, throughout the in-use shelf-life, including consideration of inappropriate use and storage or damaged product (e.g. drop test and testing in a range of appropriate orientations of the container).
1.2.2 The design and functions of the container, including physical and microbial integrity, should be regularly tested throughout storage during shelf life.
Containers should be stored in various orientations during stability to determine the effect of orientation.
1.2.3. If an antimicrobial substance is present as a container design feature, then the amount in dispensed eye drops should be toxicologically qualified. If necessary, patient safety warnings should be included in the product information.
1.2.4. It should be shown that the sterilisation of the container components does not affect the container design features and functions.
Microbiological stress testing consists of challenging with a high inoculum of suitable micro-organisms.
The range of test organisms should be according to EP 5.1.3, supplemented by other strains or species that may represent likely contaminants to the eye preparations. Each microbial challenge study should include appropriate positive and negative controls to demonstrate effectiveness of the challenge protocol and detection methodology
Validation studies to demonstrate the suitability of the tests employed, microbial recovery and limits of detection should be reported, discussed and justified.
Microbiological stress testing should be conducted throughout the in-use shelf-life.
The following should be considered:
(a) Microbiological stress testing of each element of the container’s design and functions, for example the microbial barrier functions, venting function.
(b) Microbiological stress testing to demonstrate the antimicrobial efficacy of container components with an antimicrobial substance design feature.
(c) Microbiological stress testing of the whole product to show that the container:
(d) Following microbiological stress testing, the internal and external wet surfaces of the dropper nozzle should be examined for biofilm formation.
For container components necessary for each design feature and function:
(a) The name, description (including part number if necessary) and composition should be provided.
The combination of individual components to form a part-assembly should be stated, where applicable.
(b)The critical quality attributes of each component and part-assembly should be identified and specifications provided and justified.
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1.5.1. To minimise the risk of microbial contamination and growth, the in-use shelf-life should be in accordance with product posology, acute or chronic use and pack size. The in-use shelf life should not exceed 28 days, unless otherwise justified and authorised.
1.5.2. The product literature (SmPC and PL) should refer to patient training, if required for the safe and appropriate use of the product.
1.5.3. It is recommended that eye infections are monitored in the PSUR. Misuse, medication error and device failure arising from product quality issues might also be monitored in the PSUR if the potential for these safety concerns is sufficiently substantiated for specific products.
Although some parameters should always be tested on receipt by the finished product manufacturer e.g. diethylene glycol in glycerol, what is actually tested on receipt is fully covered under good manufacturing practice and should be justified based upon risk assessments, based on historical data backed by supplier audit. Consequently, the relevant registered specifications in the marketing-authorisation application should not include any reference at all to reduced testing on receipt by the finished product manufacturer.
Commission Regulation (EU) /63 of 14 January amending Annexes II and III to Regulation (EC) No / of the European Parliament and of the Council as regards the food additive titanium dioxide (the Regulation) entered into force following its publication in the Official Journal of the European Union on 18 January .
On 6 May , EFSA published a scientific opinion on the safety assessment of titanium dioxide (TiO2) as a food additive, which concluded that based on all evidence available, a concern for genotoxicity could not be ruled out.
The Regulation foresees that TiO2 remains for the time being on the list of authorised additives to allow its use in medicinal products as a colourant. One of the reasons for that decision is to avoid shortages of medicinal products containing TiO2 as this could impact public health and animal health and welfare. The replacement of TiO2 requires investigation and testing of suitable alternatives to ensure that quality, safety and efficacy of medicines are not negatively affected.
The function of TiO2 is typically described as a ‘colourant’ although TiO2 exhibits multiple functionalities from a pharmaceutics perspective (e.g. opacity, enhancing contrast, inertness, protection from UV light and the finish/smoothness of the resulting product) .
The Regulation is applicable to all medicinal products containing TiO2 independent of its pharmaceutical form.
The Regulation also foresees a review clause after three years, meaning that the Commission will re-evaluate the situation within 3 years of the date of entering into force of the Regulation, on the basis of an updated assessment by the EMA which is to be provided by April . It further calls on the pharmaceutical industry to make all possible efforts to accelerate the research and development of alternatives and to replace TiO2 in both new and already authorised products.
In case an applicant has applied for a marketing authorisation or an application is close to submission and development work has already started, for the time being the proposed composition can include TiO2. Nevertheless, applicants are reminded to make all possible efforts to accelerate the research and development of alternatives and to replace TiO2. However, if applicants decide to replace or remove TiO2, this should either be done prior to applying for marketing authorisation or via a variation procedure (i.e. after marketing authorisation is granted), but not during an on-going marketing authorisation procedure.
Changes in the composition of medicines to replace/remove TiO2 will require new formulations to be developed. The data requirements when replacing an excipient are elaborated in the Note for Note for guidance on development pharmaceutics and in the Note for guidance: Development pharmaceutics for veterinary medicinal products. These guidelines state that the choice and characteristics of an excipient should be justified with respect to its purpose in the medicine and that the quality of the excipient should be guided by its role in the formulation and the proposed manufacturing process. In cases where a novel excipient is used (i.e. an excipient used for the first time in a finished product, or via a new route of administration in the EU), full details of the manufacture, characterisation and relevant safety data should be provided1.
1 Section 4.6. of the guideline on excipients in the dossier for application for marketing authorisation of a medicinal product, EMEA/CHMP/QWP//. Commission Delegated Regulation (EU) /805 amending Annex II to Regulation (EU) /6 EUR-Lex - R - EN - EUR-Lex (europa.eu)
MAHs are reminded to make all possible efforts to accelerate the research and development of alternatives and to replace TiO2 in their authorised products.
In this respect, it is essential that manufacturers collaborate with each other regarding research and development of alternatives for replacement, especially when it comes to replacing TiO2 for similar products.
Regarding the scientific data required to support the change once an alternative has been found, see response on Question 4.
The development aspects outlined under Question 2 should be considered.
The removal or replacement of TiO2 may go beyond a simple change and constitute a product/process re-development to a greater or lesser extent.
It is also important to note that these product development steps are product specific.
As mentioned in Question 2, in cases where a novel excipient is used (i.e. an excipient used for the first time in a finished product, or via a new route of administration in the EU), full details of the manufacture, characterisation and relevant safety data should be provided.
Scientific data requirements to support a change in excipient(s) to remove or replace TiO2 vary between products and depend on the function of TiO2 in the individual medicine. Each medicinal product will need an individual review and assessment, which will require investigation of alternatives, reformulation, generation of new quality data (e.g. related to manufacture, dissolution, stability etc.) and potentially new clinical data (e.g. generation of bioequivalence studies).
In cases where TiO2 is incorporated only to improve overall appearance of the medicinal product, the omission of TiO2 with minor adjustment of the quantitative composition of the finished product where relevant, may be an acceptable option. The relevant supporting data in this case are:
In other cases, the MAH/applicant may need to find alternative excipient(s) to replace TiO2 in the product composition, and in addition to the requirements detailed above, the inclusion of excipient(s) should be supported by the relevant data as detailed below:
For human medicinal products
From the regulatory point of view, the EC variation classification guideline includes a classification for such a change (B.II.a.3)1. The conditions and documentation to be supplied differ depending on the type of change, type of product, and the potential impact of the proposed change to the quality/safety/efficacy of the product.
In addition to the main variation change required, i.e. B.II.a.3. change in the composition (excipients) of the finished product, for coated tablets and capsules, it is likely that variation B.II.a.4 “Change in coating weight of oral dosage forms or change in weight of capsule shells” may also be required. This change may be a type IA, IB or II, depending on the type of product and fulfilment of the guideline conditions.
Furthermore, it can also be envisaged that other variations may be warranted for individual products as a direct consequence of implementing the excipient change. For example:
It is recommended that all variations that are a consequence of the deletion or replacement of TiO2 are submitted together as a grouped variations.
Work-sharing and collaboration among marketing authorisation holders and national competent authorities should be explored.
For veterinary medicinal products
Removal or replacement of TiO2 from an already authorised veterinary medicinal product should be carried out in accordance with Regulation (EU) /6 for veterinary medicinal products.
In the simplest cases, removal of TiO2 could be achieved via a variation not requiring assessment2 (“VNRA”) category B.3.i – deletion of a component or components of the flavouring or colouring system.
In most cases, the main variation category would be ‘Change(s) in the composition (excipients) of the finished product’ which depending on the pharmaceutical form would be a VNRA (category B.18 c)) for non-sterile dosage forms or a VRA (category F.II.a.3) for sterile dosage forms or non?sterile dosage forms that do not fulfil the conditions of VNRA B.18 c). Within category F.II.a.3 the sub-category applicable to the specific change should be selected including, if appropriate, the ‘z’ sub-category.
It can also be envisaged that other VRAs/VNRAs may be warranted for individual products as a direct consequence of implementing the excipient change. For example:
The specific type of variations, the conditions to be fulfilled and documentation to be supplied differ depending on the type of product, the type of change and the potential impact of the proposed change on the quality/safety/efficacy of the product.
It is recommended that all VRAs that are a consequence of the deletion or replacement of TiO2 are submitted together as a grouped VRA. MAHs are reminded that VNRAs cannot be included in grouped VRA submissions and where the replacement of TiO2 requires a mix of VRAs and VNRAs, it is advisable that the recording of VNRA (s) in the Union Product Database is coordinated with the submission of the VRA(s).
In accordance with Article 65 of Regulation EU /6 "Work-sharing procedure" where one or more VRA identically apply to one or several marketing authorisations which are held by the same marketing authorisation holder and which have been granted by different competent authorities or by the Commission, an identical application shall be submitted to the competent authorities in all relevant Member States and, where a variation to a centrally authorised veterinary medicinal product is included, to the Agency.
1 B.II.a.3. Change in the composition (excipients) of the finished product of the Guideline on the details of the various categories of variations, on the operation of the procedures laid down in Chapters II, IIa, III and IV of Commission Regulation (EC) No / of 24 November concerning the examination of variations to the terms of marketing authorisations for medicinal products for human use and veterinary medicinal products and on the documentation to be submitted pursuant to those procedures .
2See Commission Implementing Regulation (EU) /17 establishing a list of variations not requiring assessment; EMA Guidance on variations not requiring assessment (veterinary medicines); and CMDv Best Practice Guide for variations not requiring assessment BPG VNRA
Individual impurities:
Total impurities:
Dropping of the device should be investigated as part of the robustness study defined in the Guideline on the pharmaceutical quality of inhalation and nasal products (section 4.2.18).
The product performance should be investigated under conditions to simulate use by patients.
The delivery device should be carried between use and actuated at the frequency indicated in the instructions for use. Simulation of dropping the delivery device and the robustness of any lockout mechanism should be investigated. The dropping simulation should be performed towards the end of the life of the product (e.g. at dose 180 for a 200-dose product) in order to assess the effect of drug accumulated on the mouthpiece, or any other part of the device, during the lifetime of the device being dislodged. If the device is designed to have the mouthpiece removed for periodical cleaning, testing should be performed both with the mouthpiece removed and cleaned in accordance with instructions for use during the test, and, as a worst case, without removal and cleaning. Significant variations in the delivered dose and/or fine particle mass should be fully discussed in terms of the safety and efficacy of the product. Appropriate handling instructions to the patients should be established, based on the results obtained.
For inhalation powders in hard capsules the capsule shell is considered as an excipient and the components should be stated in section 6.1. of the SmPC under a separate subheading “Capsule shell”.
What are the requirements for the graduation of measuring devices for medicinal products for human use that are administered to patients as liquid preparations, in particular in relation to the suitability of the graduation of the measuring device regarding dosing accuracy and precision, and the suitability of the measuring device for its intended use? H
November question reworded and response supplemented with guidance on the measurement of small volumes
The points discussed below are applicable to new Marketing Authorisation (MA-)applications or fully reformulated existing medicinal products. These points should be considered when referring to the graduation of a measuring device for a liquid preparation for human use in the Common Technical Document section 3.2.P.2: pharmaceutical development. They should form part of the justification of the suitability of the graduation of the measuring device for dosing the preparation under application. The measuring device shall comply as well with the relevant parts of the Essential Requirements given in Annex I of the Medical Device Directive 93/42/EEC, or with the General Safety and Performance Requirements given in Annex I of the Medical Device Regulation (EU) /745, as and when applicable, and with International Organization for Standardization (ISO) standards.
Measuring devices may be required to deliver a variety of liquid preparations to patients through different routes of administration, e.g. oral, parenteral, nasal, vaginal and rectal. The related medicinal products may already be a liquid upon marketing (e.g. ready to use solutions, suspensions, emulsions) or the products may be marketed as a solid or a concentrate where the liquid preparation needs to be prepared prior to use. The measuring device can be marketed together with the medicinal product (e.g. syringes without needles to administer oral liquid preparations, measuring cups, spoons or beakers, pipette applicators) or can be incorporated as integral part of the medicinal product (e.g. prefilled syringes).
In general, the minimum volume of a liquid measured with any measuring device should not be lower than 10% of the maximum capacity (e.g. 0.10 ml for a 1 ml syringe). However, this percentage may not be acceptable in situations where dosing accuracy and precision are considered to be critical, e.g. for active substances with a small therapeutic range. When the minimum volume that is measured increases up to 25% of the maximum capacity (e.g. 0.25 ml for a 1 ml syringe), usually no issues with regards to accuracy and precision are expected. This should be confirmed during pharmaceutical development.
The recommendation of the minimum volume of a liquid to be measured (in milliliters) is not applicable to devices that measure insulin as they are graduated in insulin units.
Manner of graduation
The graduation should be applied to the measuring device in such a manner that accurate and precise dosing is guaranteed. The graduation can be embossed or debossed on the measuring device, or printed on it.
This precision and accuracy of dosing should be guaranteed from release throughout storage until the end of shelf life, and also during the use of the particular measuring device under the conditions recommended in the Summary of Product Characteristics and Package Leaflet (SmPC/PL). Attention should be paid to the possibility of the printing ink fading. Gluing of a label with a printed graduation to the measuring device is not generally favoured, because of the potential for dislocation of the glued label during storage and use. If a glued label is used, the effectiveness of the adhesive / label system under normal conditions of storage and use should be demonstrated.
Graduated scale
The graduated scale should correspond with the way the dose or product strength is declared in the SmPC/PL. Generally, graduation in ‘ml’ is preferred as commonly available measuring devices are most often graduated in units of volume and as in many regions, health care professionals are more familiar with this type of graduation. This applies in principle to all measuring devices. For example, attention should be paid to the following:
European or international standards (European Committee for Standardization or ISO) may be available, e.g. for syringes recommendations are given on tolerances, graduated capacity, and graduated scale in ISO standards. These recommendations can be applied without further justification.
Suitability of a measuring device for a liquid preparation derived from/of a medicinal product: The suitability of the measuring device should be addressed. Attention should be paid to the following:
Furthermore, the suitability of the measuring device and its graduation for the intended patient population should also be taken into account.
Acceptance criteria
The graduation of the measuring device should be suitable to meet the acceptance criteria of the dose of the liquid preparation derived from/of the medicinal product under application, as measured with the measuring device under application. These acceptance criteria should be in line with European Pharmacopoeia (Ph. Eur.) requirements, if applicable (for example Ph. Eur. 2.9.27: uniformity of mass of delivered doses from multi-dose containers), or other accepted pharmacopoeias. For single-dose containers where only a portion of the content needs to be administered to the patient, the same requirements can be applied as for multi-dose containers.
Measuring small volumes
Liquid preparations are intended to be administered with a measuring device that is commonly available in the European Union. If this is not the case, a measuring device should be supplied with the product by the MA-holder.
In order to ensure accurate dosing, the maximum capacity (size) of a measuring device should be appropriate for the volume to be dosed. For example, the smallest size of syringes that are graduated in ml and that are commonly available in hospitals and pharmacies throughout the European Union are 1 ml syringes with 0.01 ml dosing increments. Where commonly available 1 ml syringes are not considered suitable for dosing a liquid preparation with sufficient accuracy and precision, the company should develop an alternative administration strategy that would enable the use of a 1 ml syringe, e.g. a lower strength product. Where this approach is not an option, it is expected that (a) suitable dedicated measuring device(s) will be co-packed with the product and that the company will demonstrate acceptable accuracy and precision with such (a) device(s).
If the volume is too small to be measured accurately, (serial) dilution may be considered. However, this practice is prone to error. If dilution is considered necessary, this must be justified in the development pharmaceutics. In addition, and to avoid error, the dilution steps should be described in the SmPC/PL.
In the absence of clinical data, the results of in vitro observations with alcohol (ethanol) may be considered, as a minimum, evidence of a possible physicochemical incompatibility with alcoholic drinks. The possibility of such an incompatibility with alcoholic drinks should be considered for all modified release products.
The general methods of in vitro release testing are considered capable of providing sufficient evidence of alcohol incompatibility. In the case where in vitro alcohol incompatibility of the drug product is demonstrated, then appropriate warnings should be included in the summary of product characteristics, in line with current guidelines.
The interaction with alcohol observed in vitro should be considered as a physicochemical incompatibility of the drug product. In line with current regulatory practice, reference to this incompatibility, albeit dietary rather than medicinal, has been included in the product literature to supplement the current pharmacological warning to avoid alcohol.
In vitro studies investigating the effect of alcohol / ethanol on dissolution / release are recommended for all opioid modified-release products where applicants consider the potential for incompatibility with alcohol exists.
To minimise the risk, it is recommended that the product design, if possible and practical, should be such that a physicochemical incompatibility with alcohol is avoided. This advice is especially important for drug substances with a narrow therapeutic index.
Is it considered that in vitro studies investigating the effect of alcohol / ethanol on dissolution / release might also be required for oral prolonged release formulations containing active substances other than opioids? If so, should they be required only where rapid dose dumping of the active substance might be expected to cause clinically hazardous overdose, or should they be required for all oral prolonged-release products containing any active substance? HWhere there are scientific grounds that the defined-release characteristics of the oral drug may be adversely affected by the presence of alcohol, then alcohol physicochemical incompatibility should be considered by the applicant. This would apply to all oral prolonged- (and delayed- and modified-) release products.
At this point in time, it is not possible to provide authoritative methodological requirements.
In vitro studies are considered sufficient to show evidence of alcohol incompatibility, with a consequential effect on the quality of the drug product, with respect to release performance.
It is noted that in vitro release testing primarily relates to the quality control of drug products, with limits set to be in line with those batches used for clinical studies for which satisfactory safety and efficacy has been established.
Taking this into account, if the presence of alcohol in the dissolution medium of the in vitro release test produces out of specification results, then this may be considered sufficient evidence of an incompatibility with alcohol, i.e. that alcohol adversely affects the quality of the drug product.
In the first instance, the applicant should consider the possibility of physicochemical incompatibility with alcohol. This should include a discussion of the solubility of the release controlling excipients in alcohol and the impact this may have on the in vitro release performance of the drug product. Where solubility or other information cannot exclude the possibility of physicochemical incompatibility with alcohol, then in vitro release data should also be provided to assess the extent of interaction.
The dissolution medium should be the same as that proposed for routine testing, but with a justified range of alcohol added. The range of alcohol in the medium should mimic levels that are likely to be reached in the fluid of the stomach and proximal gastrointestinal tract following alcohol consumption e.g. 5%, 10% and 20%.
The applicant should discuss the significance of any out of specification results, particularly at the early time points, together with consideration of the risks of dose dumping and accelerated release. Appropriate warnings in the summary of product characteristics should be proposed and justified.
Are further measures needed to gain better understanding of the release characteristics of oral prolonged-release products in the presence of alcohol and their relevance to the clinical situation, for example by in vitro – in vivo correlation? If in vitro testing demonstrates a potential for alcohol to enhance opioid / active product release, should the applicant be required to investigate the clinical relevance of the effect in in vivo studies? H AprilIt should be acknowledged that the clinical relevance of physicochemical incompatibility with co-administered alcohol is debatable, at the present time. The published literature is limited.
Where incompatibility with alcohol is evident, it is currently sufficient to address safety or other concerns by the inclusion of appropriate warnings in the product literature unless serious concerns are raised with respect to efficacy and safety.
Needle stick injuries commonly occur in the following cases: (1) before administration, when the cap is vigorously removed using two hands (holding the syringe/pen injector with one hand and removing the cap with the other); (2) during or after administration, when the patient or healthcare professional are distressed; (3) when an attempt is made to recap the needle after administration; (4) when sharps containers are overfilled and not disposed of in time.
The potential consequences of needle stick injury vary greatly from minor (e.g. pain or swelling around the stick site) to very serious (e.g. transmission of infectious disease such as HIV). The risks ensuing from needle stick injury are dependent upon a large number of factors such as: the nature of the active ingredient and excipients (e.g. cytotoxic substances), the indication (e.g. anti-retroviral medicines), the method of administration (self-administration by the patient vs. administration by a caregiver vs. administration by a healthcare professional), the target patient group (e.g. high-risk patient groups such as patients with infectious disease), and the setting where the medicine is administered (e.g. administration in emergencies).
No. Directive /32/EU implements a framework agreement on the prevention from sharps injuries in the hospital and healthcare sectors signed by the European Hospital and Healthcare Employers’ Association (HOSPEEM) and the European Public Services Union (EPSU). It applies to employers whose primary activity is to organise, manage and provide healthcare, including where care is provided in the patients’ own homes.
Yes. The overall benefit-to-risk evaluation of a medicinal product includes assessment of the suitability of its medical device component(s).
Device components incorporating a needle are expected to comply with the requirements of Annex I (known as “The Essential Requirements”) to Directive 93/42/EEC (the Medical Devices Directive). Sections 1, 2, 8.1 and 13 thereof state that: (1) the design of the device should not compromise the safety of the patient, user (patient, caregiver, healthcare professional) and other persons; (2) risks (including the risk of infection) should be eliminated as far as possible and (3) state-of-the-art technology should be considered. Therefore, the decision on the suitability of the device component will be product-specific and risk-based, and will reflect current state-of-the-art technologies.
No. Regulatory authorities may grant a marketing authorisation for a medicinal product that does not contain a needle safety system. However, the development and use of needle safety systems is encouraged and highly recommended.
Needle safety information is expected in case of new marketing authorisation applications, and where appropriate relevant variation applications, concerning medicinal products incorporating a safety feature. The development of the needle safety system and any risk assessments performed should be included in Module 3.2.P.2 Pharmaceutical Development. The technical details should be submitted in Module 3.2.P.7 Container Closure System. Information regarding the needle safety of the product should be communicated to users in the Summary of Product Characteristics (SmPC) and Packaging Leaflet (PL).
In cases where the medicinal product incorporates a needle without a safety feature, the company would be expected to justify why this approach is acceptable for the intended use of the medicinal product in the intended setting and patient group. The justification, along with the company's product-specific risk assessment should be submitted in Module 3.2.P.2 Pharmaceutical Development. Overall, the same principles are applied to the assessment of needle safety systems (or their absence) as to the assessment of other device components in medicinal products.
For already approved medicinal products with a needle safety system, the information on the needle safety feature may not yet be included in the SmPC/PL. It is recommended that the missing reference is added with the next variation affecting the SmPC/PL to align the dossier with the current regulatory standards.
In line with the current regulatory standards, separate EU numbers will be required where the product is provided with and without a needle safety system.
The needle safety system should be listed in:
Furthermore, handling instructions related to the needle safety system should be described in:
The FPD and other relevant aerodynamic particle size distribution (APSD) ranges are critical quality parameters as they represent the fraction(s) of the dose with a larger probability to reach the lungs (unless partially eliminated by mucocilliary clearance), absorbed systematically from the lungs and exert a local effect. According to the guideline on the pharmaceutical quality of inhalation and nasal products (EMEA/CHMP/QWP// Corr), the specification limit of FPD should be based on the batches used in clinical studies (pivotal clinical and/or comparative studies). The proposed specification range(s) should always be discussed and justified in the dossier. Normally, it is considered that a specification range of up to ±25% is adequate for quality control of most inhalation products, based on the manufacturing process and the variability of the analytic methods. Ranges wider than ±25% should be sufficiently justified by in vitro or in vivo data. The proposed specification limits should take into account the shelf-life performance of the FPD/APSD of the product. If the application is covering several strengths, the specification range(s) for each of the strengths should normally not be overlapping.
The batch(es) of the comparator used in clinical studies should be representative of the commercial batches available on the market, including consideration for different ages or shelf-life of the product. The test product has to be representative of future batches and therefore the specification limits are critical to ensure similar characteristics even at the end of the shelf-life.
How the representative batch(es) is chosen should be fully discussed and justified in the dossier, preferably in Module 3. For some inhalers the FPD/APSD may decrease over time and in these cases ageing of the product should be considered. Characterisation of several batches of the comparator from different markets should be performed. A minimum of 5 to 6 batches may be sufficient if suitably justified. However, if the comparator shows great variability and/or degradation, a larger number of batches are needed. The FPD/APSD of the reference batch(es) chosen for clinical studies should be as close as possible to the median of the observed values. A deviation within ±15% is reasonable.
According to the OIP guideline Guideline on the requirements for clinical documentation for Orally Inhaled Products including the requirements for demonstration of therapeutic equivalence between two inhaled products for use in treatment of asthma and chronic obstructive pulmonary..., dose proportionality should be demonstrated to establish therapeutic equivalence clinically with only one strength. In vitro proportionality should be demonstrated for the whole APSD although groups of stages could be used if a pooling strategy is justified from a clinical perspective. The different strengths should be compared with a ±15% acceptance range in each stage. If the different strengths of the test and the comparator are not shown to be proportional in vitro in the range of relevant flow-rates, in vivo equivalence should be demonstrated with a bracketing approach. Bracketing should include the strengths most similar and most different from an in vitro perspective.
Healthy adult volunteers are easier to recruit and less variable than patients. In addition, patients may be less discriminatory since lung depositions are mostly central due to bronchoconstriction. PK studies in healthy volunteers to investigate systemic exposure and lung deposition may be acceptable if the test and the comparators have shown a) no flow-rate dependency or b) similar flow-rate dependency in vitro determined through evaluation of FPD and APSD for both test and comparator. The flow-rate interval to be studied should be justified based on e.g. resistance of the device or the trigger threshold of the device and the flow-rate observed in the healthy adult volunteers and patients populations. Normally, a flow-rate interval of 30-90 L/min is acceptable.
Reference to relevant paragraphs of the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) is given for each question.
Safety considerations should be taken into account. The limits should be supported by the impurity profiles of batches of active substance used in non-clinical and clinical studies. Results between batches should be consistent (or the clinical batches should show better purity results than non-clinical and previous clinical batches).
Compliance with International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) requirements is not required, if proper justification is provided.
Where specifications are set for potential genotoxic impurities, the guidance given in questions and answers on the guideline on limits of genotoxic impurities (EMEA/CHMP/SWP//) should be taken into consideration (question 6: staged threshold-of-toxicological-concern approach).
Reference to relevant paragraphs of the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) is given for each question.
The table in the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) gives examples of what should be notified as substantial amendments and of changes where a notification will not be necessary. The list is not exhaustive, and the sponsor should decide on a case-by-case basis if an amendment is to be classified as substantial or not.
For non-substantial amendments documentation should not be proactively submitted, but the relevant internal and study documentation supporting the change should be recorded within the company and if appropriate, at the investigator site. At the time of an overall investigational medicinal product dossier update or submission of a substantial amendment the non-substantial changes can be incorporated into the updated documentation. There is no need to use the notification of amendment form for these changes.
Reference to relevant paragraphs of the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) is given for each question.
The criteria based on which it is intended to extend shelf life during an ongoing study should be given. The information should include extension protocol limiting the maximum time period for extrapolation. In the case of any significant negative trend for stability data observed during long-term and accelerated testing, the sponsor should commit to notify any shelf-life extension as a substantial amendment.
Reference to relevant paragraphs of the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) is given for each question.
No, tabulated batch results are sufficient. Data for representative batches should be included in the batch analysis table of the investigational medicinal product dossier. Results for batches controlled according to previous, wider specifications are acceptable if the results comply with the specification for the planned clinical trial. The results should cover the relevant strengths, but the batches do not need to be the same that will be used in the clinical trial.
Reference to relevant paragraphs of the guideline on the requirements to the chemical and pharmaceutical quality documentation concerning investigational medicinal products in clinical trials (CHMP/QWP//) is given for each question.
Data from representative batches should be provided. This implies that data should be provided for each proposed site. However, where one legal entity has multiple sites (in the same country), then batch data from one site only would be sufficient.
For non-substantial amendments documentation should not be proactively submitted, but the relevant internal and study documentation supporting the change should be recorded within the company and if appropriate, at the investigator site. At the time of an overall investigational medicinal product dossier update or submission of a substantial amendment the non-substantial changes can be incorporated into the updated documentation. There is no need to use the notification of amendment form for these changes.
The functional aspects of plastic containers for eye drops products should be qualified as part of development pharmaceutics, incorporating the usability engineering design principles (Annex I Medical Devices Directive /47/EC; BS EN : Medical Devices – Application of usability engineering to medical devices).
These functional aspects should include usability, dose delivery performance, the controls for quality of the container and rationale for choice and optimisation of the design, including size and shape of the container closure system. It is known that the size and shape of the container can affect ease of handling and dispensing of drops by patients, especially those with impaired dexterity such as the elderly.
Usability, i.e. that the container can be used safely to deliver the required dose by the target patient population or representative subject group, should be discussed for all eye drop medicinal products.
It is recommended that a formal usability study is undertaken, in accordance with a valid protocol to systematically observe and evaluate the usability of the eye drop medicinal product, particularly for novel containers and containers that are required to be used in a specific (non-intuitive) way. The usability study may be integrated into clinical or therapeutic equivalence studies. In the absence of such study data, evidence of usability should be supported by published or other data, if available, and risk assessment.
Dose delivery performance should be qualified by evaluation of accuracy and reproducibility of dose delivery from the dropper in various orientations such as inverted or inclined. The force required to dispense a drop should be correlated with physical capabilities of the target patient population. Evaluation of dose delivery performance should be performed with containers manufactured by the same process and stored in same condition as proposed in the marketing authorisation; for example stored at 2-8 ?C, if a cold storage product.
In addition to the general information to be provided on quality of containers (Ph Eur monograph 3.2.2 Plastic containers and closures for pharmaceutical use; ICH M4Q(R1): Quality; CHMP/CVMP guideline on plastic immediate packaging materials (CPMP/QWP//03, EMEA/CVMP/205/04)), the specification of plastic containers for eye drops for human or for veterinary use should also include a qualitative test for surface defects such as excessive burrs and sharp edges around the dropper tips.
Plastic containers manufactured by blow-fill-seal process are particularly prone to surface defects and the specification should include tests for:
These tests should form part of in-process control checks of the blow-fill-seal process.
Appropriate acceptance criteria and standards for control of excessive burrs, sharp edges container opening characteristics should be established and outlined in the dossier, including photographs as necessary. The sample size should be adequate and justified.
Close-up photographs of intact and opened containers should be included in the dossier.
The product information texts (SmPC, Patient Information Leaflet, Labels) should include appropriate instructions based on the development data and studies undertaken.
Samples of the drug product should be provided to the Competent Authorities, on request, to enable independent assessment and reporting on the quality of the container.
The European Pharmacopeia (Ph. Eur.) general monograph “Substances for pharmaceutical use” and VICH guideline GL10 (impurities in new veterinary drug substances) both define the following thresholds for reporting, identification and qualification of impurities in substances used for veterinary medicinal products as follows:
Active substances for pharmaceutical use have to comply with the Ph. Eur. general monograph “Substances for pharmaceutical use”. Pharmacopoeial active substances should also comply with their specific monograph.
The active substance can only be considered as “Veterinary use only” in the following cases:
It is not considered acceptable to declare the active substance as “Veterinary use only” for example, purely on the basis of an active substance manufacturer declaration that they produce that substance only for veterinary use, or it is declared by the applicant that the active substance is used in a veterinary only dosage form.
Ideally, compendial grade excipients should be used in new veterinary medicinal products.
Premixes for medicated feeding stuffs should comply with the requirements of the European Pharmacopeia (Ph. Eur.) general chapter 5.1.4: microbiological quality of non-sterile pharmaceutical preparations and substances for pharmaceutical use. It is expected that these products comply with the requirements for non-aqueous preparations for oral use.
If it is not possible to comply with these limits, premixes containing excipients of natural (animal, vegetal or mineral) origin should comply with the requirements of “Special Ph. Eur. provision for oral dosage forms containing raw materials of natural (animal, vegetal or mineral) origin for which antimicrobial pretreatment is not feasible and for which the competent authority accepts…….”.
However, if justification is provided that these limits cannot be met, then the requirements of the “Special Ph. Eur. provision for premixes for medicated feeding stuffs for veterinary use using excipients of plant origin for which antimicrobial treatment is not feasible.” are applicable.
In cases where an oral powder and a premix for medicated feedingstuffs have the identical composition, it would be expected that the same microbiological limits would be applied to both pharmaceutical forms. In this case the stricter limits are applicable (normally those for oral powders requested in chapter 5.1.4: non-aqueous preparations for oral use).
Could a recommendation be added in the summary of product characteristic / product information that, for solubility reasons, the pH of the drinking water has to be adjusted with acid / base before adding medicinal product? V
The guideline on quality aspects of pharmaceutical veterinary medicines for administration via drinking water (EMEA/CVMP/540/03-Rev.1) sets out how the solubility of a product in drinking water should be tested (soft water / low pH with a pH range from 5.0 to 7.0 and hard water / high pH with a pH range from 8.0 to 9.0).
In principle, a veterinary medicinal product can only be authorised if it fully dissolves (and remains in solution) without further aid in drinking water of the usual pH range (which is usually a pH range between 5.0 and 9.0). If a pH adjustment of the drinking water is necessary this should be done with excipients (acid, base or buffer) included as part of the authorised veterinary medicinal product. Exclusions are only acceptable if justified (e.g. it has been shown that other formulation principles have been excluded).
The use of unlicensed acids or alkalis for the pH adjustment of the drinking water before (or after) adding the veterinary medicinal product in order to achieve the necessary solubility is not acceptable unless justified.
Such an example would be considered to be two different pharmaceutical forms (and also in this specific problem case, routes of administration) and therefore to need two different marketing authorisation (sub)numbers, as well as two different summaries of product characteristics.
In the European Union, different marketing authorisations (sub)numbers are necessary for different pharmaceutical forms. See the guideline on the categorisation of new applications versus variation applications.
Another reason is that using multidose containers for both intramammary and parenteral use may result in an increased risk of microbial contamination of the product in its multidose container.
Rubber stoppers (bungs) used for vial closures for multidose veterinary injectables are often punctured many times during use. Therefore suitable criteria regarding fragmentation (and self-sealing) are required. Problems can mainly arise in large multidose injectables, which can be used for different target species and / or ages of animals, but particularly for smaller animals where dose volumes are small, and so the pack could be punctured many times (e.g. in extreme cases in excess of 100 punctures). Should the general chapter on rubber closures for containers for aqueous parenteral preparations, for powders and for freeze-dried powders (3.2.9) be applied in these cases? Which criteria for the maximum number of rubber fragments are deemed acceptable for a test design which is a multiple of the number of punctures described by Ph. Eur. 3.2.9? Should a worst-case scenario be used? V
The general chapter on rubber closures for containers for aqueous parenteral preparations, for powders and for freeze-dried powders (3.2.9) is not mandatory on its own. If suitable justification is provided, the requirement (maximum of five fragments) contained in this chapter does not necessarily need to be applied. It is noteworthy that the European Pharmacopoeia (Ph. Eur.) test is designed to demonstrate that a stopper fulfills the general minimum requirements that are expected for rubber stoppers for medicinal products, but this can of course not cover all their potential uses.
The pack concerned should be proven to meet the requirements of the Ph. Eur. test modified to use the maximum number of punctures expected in relation to the target species, dose and route of administration (using the appropriate needle size for that scenario). Note that the maximum number of fragments expected remains exactly as in the Ph. Eur. test.
The summary of product characteristics (SmPC) and other product information should then reflect the number of punctures for which the closure has been demonstrated to meet the requirements of the Ph. Eur. test. For example, if the closure has been shown capable of withstanding X punctures with fragmentation and self-sealing characteristics which meet the relevant Ph. Eur. requirements. That is, with no additional increase in fragments for the increased number of punctures.
Risk-management tools
Some examples of advice (if necessary in combination) which could be included in the SmPC (section 4.9) and other product literature to reduce potential damage to the stopper from excessive numbers of punctures:
The functional aspects of plastic containers for eye drops products should be qualified as part of development pharmaceutics, incorporating the usability engineering design principles (Annex I Medical Devices Directive /47/EC; BS EN : Medical Devices – Application of usability engineering to medical devices).
These functional aspects should include usability, dose delivery performance, the controls for quality of the container and rationale for choice and optimisation of the design, including size and shape of the container closure system. It is known that the size and shape of the container can affect ease of handling and dispensing of drops by patients, especially those with impaired dexterity such as the elderly.
Usability, i.e. that the container can be used safely to deliver the required dose by the target patient population or representative subject group, should be discussed for all eye drop medicinal products.
It is recommended that a formal usability study is undertaken, in accordance with a valid protocol to systematically observe and evaluate the usability of the eye drop medicinal product, particularly for novel containers and containers that are required to be used in a specific (non-intuitive) way. The usability study may be integrated into clinical or therapeutic equivalence studies. In the absence of such study data, evidence of usability should be supported by published or other data, if available, and risk assessment.
Dose delivery performance should be qualified by evaluation of accuracy and reproducibility of dose delivery from the dropper in various orientations such as inverted or inclined. The force required to dispense a drop should be correlated with physical capabilities of the target patient population. Evaluation of dose delivery performance should be performed with containers manufactured by the same process and stored in same condition as proposed in the marketing authorisation; for example stored at 2-8 ?C, if a cold storage product.
In addition to the general information to be provided on quality of containers (Ph Eur monograph 3.2.2 Plastic containers and closures for pharmaceutical use; ICH M4Q(R1): Quality; CHMP/CVMP guideline on plastic immediate packaging materials (CPMP/QWP//03, EMEA/CVMP/205/04)), the specification of plastic containers for eye drops for human or for veterinary use should also include a qualitative test for surface defects such as excessive burrs and sharp edges around the dropper tips.
Plastic containers manufactured by blow-fill-seal process are particularly prone to surface defects and the specification should include tests for:
These tests should form part of in-process control checks of the blow-fill-seal process.
Appropriate acceptance criteria and standards for control of excessive burrs, sharp edges container opening characteristics should be established and outlined in the dossier, including photographs as necessary. The sample size should be adequate and justified.
Close-up photographs of intact and opened containers should be included in the dossier.
The product information texts (SmPC, Patient Information Leaflet, Labels) should include appropriate instructions based on the development data and studies undertaken.
Samples of the drug product should be provided to the Competent Authorities, on request, to enable independent assessment and reporting on the quality of the container.
It is not possible to have a product in both powdered and granulated forms under the same marketing authorisation. The two different pharmaceutical forms require different SPCs, labelling, etc, and have different marketing authorisation numbers.
The reasons for this are:
(Note: If authorised via the centralised system the two different pharmaceutical forms would be authorised under the same marketing authorisation, but with different MA sub-numbers and different SPCs, labelling, etc.)
Article 58 of Regulation (EC) 726/ widens the scope of the European Medicines Agency and the Committee for Medicinal Products for Human Use to include applications for certain medicinal products intended exclusively for markets outside the Community, e.g. for antiretroviral therapy:
“1. The Agency may give a scientific opinion, in the context of cooperation with the World Health Organization, for the evaluation of certain medicinal products for human use intended exclusively for markets outside the Community. For this purpose, an application shall be submitted to the Agency in accordance with the provisions of Article 65. The Committee for Medicinal Products for Human Use may, after consulting the World Health Organization, draw up a scientific opinion in accordance with Articles 6 to 9. The provisions of Article 10 shall not apply.”
For these applications, it is of great importance to apply standards that ensure the same adequate product quality as for products to be marketed in the European Union (EU). In this context, stability data need to be submitted by the applicant that demonstrate stability of the medicinal product throughout its intended shelf-life under the climatic conditions prevalent in the target countries, i.e. countries in climatic zones III and IV. Merely applying the same requirements as for the use in the EU, i.e. countries in climatic zone I / II, could potentially lead to substandard products when marketed in climatic zones III and IV.
The guideline ICH: Q 1 F: Stability data package for registration in climatic zones III and IV was officially withdrawn by the International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) steering committee in June due to controversial discussions about the adequacy of storage conditions defined. The World Health Organization (WHO) expert committee on specifications for pharmaceutical preparations has decided to split climatic zone IV into zone IVa (hot and humid) with storage conditions of 30°C/65% relative humidity (RH) and zone IVb (hot and extremely humid) with storage conditions of 30°C/75% RH; the WHO stability guideline will be revised accordingly.
When evaluating applications under Article 58 of Regulation EC/726/, it has to be assumed that the respective medicinal product will be used in all sub-zones of climatic zones III and IV, unless otherwise confirmed by the applicant. Therefore, in order to safeguard product quality throughout its entire intended shelf-life, stability studies under the conditions defined for climatic zones IVb need to be performed, i.e. the shelf-life needs to be established based on long-term data at 30°C/75% RH, supported by SIX months of data at 40°C/75% RH. The principles of extrapolation described in the ICH: Q 1 E: Evaluation of stability data - Step 5 as well as reduced testing designs as described in the ICH: Q 1 D: Bracketing and matrixing designs for stability testing of drug substances and drug products - Step 5 may be applied. In cases where these data demonstrate stability over the required period of time, no special storage conditions need to be labelled.
If an application under Article 58 of Regulation EC/726/ only contains data adequate for climatic zones I / II, the list of questions should request the respective data appropriate for climatic zones III and IV. If the data show stability problems at 30°C/75% RH with regard to humidity, the circulation and use of the product should preferably be restricted to those countries and regions that are covered by data, e.g. the product should only be used in countries within climatic zones III and IVa. As an alternative, storage conditions need to be labelled, including humidity, e.g. 'keep protected from ambient humidity' as, especially for climatic zone IVb, humidity may be the stability-limiting factor.
However, it has to be noted that due to the technical equipment and logistics available in some of the climatic zone-IV countries as well as the education and compliance of patients in the respective area, exposure of medicinal products to higher temperatures and humidity cannot be ruled out. This needs to be taken into account when defining shelf-life and storage conditions. For products to be stored at 'normal conditions', i.e. stable at 30°C, submission of accelerated data, i.e. 40°C/75% RH, can not be waived as they are needed to assess the impact of extreme temperature or humidity conditions that may occur in climatic zone IV, even though a product may not be stable for six months at these storage conditions.
Please note that for aqueous products in semipermeable containers to be marketed in climatic zone III, i.e. regions of extreme temperature, long-term testing should be performed at 30°C/35% RH. As an alternative, the calculation factors described in section 2.2.7.3 'drug products packaged in semi-permeable containers' of the ICH: Q 1 A (R2): Stability testing of new drug substances and products - Step 5 may be applied.
As foreseen by the Guideline on declaration of storage conditions, when a product needs to be stored refrigerated, the wording 'store in a refrigerator' should be used in the labelling, and a reference to the temperature range, e.g. 2°C to 8°C, should be included in the summary of product characteristics (SmPC) and in the package leaflet.
According to the same note for guidance, when the need for refrigerated transport (cool chain), in addition to refrigerated storage, is envisaged, the following statement should be used: 'store and transport refrigerated'.
Guidance can be found in the Note for guidance on start of shelf-life of the finished dosage form (annex to note for guidance on the manufacture of the finished dosage form)
(annex to note for guidance on the manufacture of the finished dosage form) and the Committees for Mutual Recognition and Decentralised Procedures and Quality Review of Documents product information templates. In summary, the expiry date should be calculated from the date of release or in case the period between the date of production and the date of release exceeds 30 days, from the date of production. The expiry date should be expressed as MM/YYYY. The product expires at the end of the specified month.
In the worst case, this method of calculation results in an extension of the expiry date of two months:
Table 1: Example of the calculation of the expiry date of a tablet with a shelf life of 24 months
Date of first blending stepDate of packagingDate of releaseExpiry dateInterpretation fit for useTotal time from start of manufacture to end of shelf-lifeRecalculated expiry date28/01//01//01//Until 31 January years 3 days01//01//01//01//Until 31 January years 28 days12//01//07/*21/07//Until 31 January years 28 days12//01//01//02//Until 28 February years 56 days01/*The bulk compressed tablets have been stored for six months. It is expected that a shelf life for the intermediate product is detailed in the dossier and stability data to support this are also presented in the dossier.
Particularly for products with a shelf-life of less than twelve months, this is not considered acceptable. The expiry date should therefore be calculated on a DD/MM/YYYY basis starting from the date of release, or if applicable from the date of production, and rounded up or down to MM/YYYY according to the following example: 14/01/ becomes 12/ and 15/01/ becomes 01/. See table 1 for recalculated expiry dates.
1Note: This question and answer was first published in July with a mistake (the recalculated date for examples 3 and 4 were mixed-up). Later the mistake was identified by QWP and in March the present corrected version was published.
When a veterinary medicinal product requires administration on a daily basis and no stability issues have been identified for the whole tablet, no in-use shelf-life data is required for tablet fractions. No in-use shelf life can be stated in the PI. However, it needs to be stated in the PI that the remaining tablet fraction(s) should be used at the next administration(s).
When a veterinary medicinal product requires long administration intervals (e.g. only once or twice a year), no in-use shelf-life data is required for tablet fractions. No in-use shelf life can be stated and the PI needs to include instructions that any unused tablet fractions should be discarded.
In those exceptional cases where in-use shelf life of tablet fractions is relevant, data should be provided to support it, and the in-use shelf life and storage precaution should be stated in the PI.
Endotoxin testing is not requested at the end of shelf life, taking into account the fact that it is not considered a stability-indicating parameter. The shelf-life specification should be completed with a footnote stating that endotoxins are not tested during stability studies.
Sterility is part of the shelf-life specification.
Sterility testing should be performed at least at the end of shelf life but it can be replaced by testing of the container closure integrity. Depending on the nature of the container, intermittent integrity testing might be envisaged, independent of whether the sterility testing is replaced or not.
In principle, each product will be assessed on its own merits and differences may exist. However, when the difference in in-use stability and/or compatibility potentially leads to detrimental medication errors in daily practice, such a difference cannot be accepted. Each difference will be assessed in relation to the products at issue and the context in which the products are used, in line with the CHMP position paper on potential medication errors in the context of benefit-risk balance and risk minimisation measures, EMA/CHMP//. Although the CHMP position paper relates only to medicinal products for human use, the same principles can be applied if necessary to veterinary medicinal products when there is a known or demonstrated potential for medication errors.
In principle, each product will be assessed on its own merits and differences may exist. However, when the difference in storage temperature potentially leads to detrimental medication errors in daily practice, such a difference cannot be accepted. This will be assessed on a case by case basis in relation to the products at issue and the context in which the products are used, in line with the CHMP position paper on potential medication errors in the context of benefit-risk balance and risk minimisation measures, EMA/CHMP//. Although the CHMP position paper relates only to medicinal products for human use, the same principles can be applied if necessary to veterinary medicinal products when there is a known or demonstrated potential for medication errors.
Yes, as long as the selected design is explained and justified. The International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) guideline ICH: Q 1 D: Bracketing and matrixing designs for stability testing of drug substances and drug products - Step 5, is applicable to new drug substances and products used in human medicine. However, veterinary companies may elect to follow this guideline. Where the guideline is followed, all aspects of the guideline should be followed.
Finished product stability guidance does not address storage of bulk product during the manufacturing process. The purpose of these questions and answers is to address the information to be provided in the marketing-authorisation dossier to support storage and / or transportation of bulk product during the manufacturing process.
Good-manufacturing-practice guidance indicates that bulk products should be stored under 'appropriate conditions' and therefore, the data provided in the dossier should be aimed to demonstrate the suitability of these conditions in relation to the intended storage and / or transportation arrangements of a bulk product and the effect of these on the quality of the given finished product over its declared shelf-life.
The objective is to increase the transparency of the supporting data required and not to introduce any new regulatory requirements.
The data required will depend on the type of product and the activities performed (i.e. prolonged storage or transportation) and a risk-based approach is encouraged in order to demonstrate the suitability of the data generated in each individual case.
The described framework is intended to cover all pharmaceutical bulk products. However, it is understood that the requirements for some specific types of products (e.g. biological products) may require additional data relevant to the type of product and this should be taken into consideration depending on the characteristics of that particular product.
The question most frequently arises in relation to solid oral dosage forms (particularly tablet cores before coating or packaging) but could be applicable at any stage in the manufacturing process of any pharmaceutical product where bulk is held in storage prior to further processing (e.g. bulk solution prior to filling, granulates, etc.).
In general, the level of information to be provided will be dependent on the nature of the bulk product. The qualitative and quantitative (if required) composition of the bulk container should be described in the dossier and its control specification stated (module 3.2.P.3.4 or part 2.B).
It should be stated whether the bulk product is to be stored (and if relevant, transported) under controlled or non-controlled storage conditions.
Where bulk product is transported between manufacturing sites, the transportation arrangements should be described in general terms (bulk container / storage and transportation conditions / monitoring arrangements) in the dossier (module 3.2.P.3.4 or part 2.B).
According to the guideline on good distribution practice, the following should be taken into consideration:
Principle:
Storage:
The maximum storage interval for the bulk product should be declared in the marketing-authorisation dossier, or alternatively, the maximum batch manufacturing time from start of product manufacture to completion of packaging in the final primary container for marketing.
When storage is prolonged (i.e. more than 30 days for solid oral dosage forms; more than 24 hours for sterile products), evidence of the suitability of the proposed container, storage interval or transportation arrangements should be included in the dossier. The data to be provided will be dependent on results of development studies that represent the conditions proposed.
In line with the principles described for finished products in the relevant International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) or International Cooperation on Harmonisation of Technical Requirements for Registration of Veterinary Products (VICH) guidelines, it is expected that data from pilot scale batches (minimum of two batches) stored under conditions that represent the storage conditions for the bulk product will be provided to support the storage of bulk products. Unless provided in the dossier, these data should be verified in post-approval stability commitments on commercial scale batches.
Where transportation of bulk between manufacturing sites is proposed, the impact of excursions outside of the original storage conditions should be discussed and, where necessary, supported by accelerated stability data.
Calculation of the product's shelf-life should be in accordance with the Note for guidance on start of shelf-life of the finished dosage form (annex to note for guidance on the manufacture of the finished dosage form)
(annex to note for guidance on the manufacture of the finished dosage form). If other methods are proposed, these should be declared and justified through inclusion of batches that represent the full proposed holding intervals of the bulk product (intermediate) in the finished product stability programme.
It is not necessary to conduct stability studies on bulk according to International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use (ICH) or International Cooperation on Harmonisation of Technical Requirements for Registration of Veterinary Products (VICH) recommendations (temperature or humidity). Stability studies on bulk should reflect real storage conditions in the standard container foreseen at the manufacturing site.
In the event that more than one manufacturing site is involved, the stability studies should also cover any transportation (duration and conditions).
During product development, the effect of orientation should be investigated in the priming and repriming studies according to the Guideline on the pharmaceutical quality of inhalation and nasal products. If storage orientation has a significant effect on the delivered dose during these studies (i.e. different repriming periods / number of actuations are required for re-priming when stored in different orientations), a storage orientation recommendation should be added to the product information (summary of product characteristics, package leaflet and label). The preferred storage orientation should be detailed.
As it cannot be guaranteed that the product will always be stored in the preferred orientation, the repriming instructions in the product information should be based on the worst-case scenario (i.e. the orientation which requires the shortest repriming period or the highest number of repriming actuations).
According to European Union legislation, pharmaceutical manufacturers are required to use European Pharmacopoeial standard water in the manufacture of medicinal products.
The European Pharmacopoeia (Ph. Eur.) has recently introduced a chapter making reference to the acceptability of rapid microbial methods to replace the standard Pharmacopoeial methods provided appropriate validation has been performed.
Following discussions at the QWP and the ad hoc good-manufacturing-practice inspectors' group, it is suggested that the introduction of such methods might require specific review to ensure that the appropriate validation steps have been followed and that the water continues to meet the Ph. Eur. specifications. Since, in the case of water, the validation will not be product specific, it is suggested that a company could request the supervisory authority to carry out a specific site inspection. The performance of such an inspection would be at the discretion of the supervisory authority and could involve a pharmaceutical assessor where necessary.
Since it is expected that the water will continue to meet Ph. Eur. specifications, if tested, no change to dossier requirements* (variations) would be involved and therefore no regulatory impact on individual products would normally be anticipated.
Sterility is part of the shelf-life specification.
Sterility testing should be performed at least at the end of shelf life but it can be replaced by testing of the container closure integrity. Depending on the nature of the container, intermittent integrity testing might be envisaged, independent of whether the sterility testing is replaced or not.
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