Pharmacovigilance

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Pharmacovigilance (abbreviated PV or PhV) is the pharmacological science relating to the detection, assessment, understanding and prevention of adverse effects, particularly long term and short term side effects of medicines.[1] Generally speaking, pharmacovigilance is the science of collecting, monitoring, researching, assessing and evaluating information from healthcare providers and patients on the adverse effects of medications, biological products, herbalism and traditional medicines with a view to:

  • identifying new information about hazards associated with medicines
  • preventing harm to patients.

The etymological roots are: pharmakon (Greek), “drug;” and vigilare (Latin), “to keep awake or alert, to keep watch.”

Pharmacovigilance is particularly concerned with adverse drug reactions, or ADRs, which are officially described as: "A response to a drug which is noxious and unintended, and which occurs at doses normally used… for the prophylaxis, diagnosis or therapy of disease, or for the modification of physiological function."[2]

Pharmacovigilance is gaining importance for doctors and scientists as the number of stories in the mass media of drug recalls increases.[citation needed]

Because clinical trials involve several thousand patients at most; less common side effects and ADRs are often unknown at the time a drug enters the market. Even very severe ADRs such as liver damage are often undetected because study populations are small. Postmarketing pharmacovigilance uses tools such as data mining and investigation of case reports to identify the relationships between drugs and ADRs.

Pharmacoenvironmentology

A branch of environmental pharmacology and a form of pharmacovigilance which deals entry of chemicals or drugs into the environment after elimination from humans and animals post-therapy. It deals specifically with those pharmacological agents that have impact on the environment via elimination through living organisms subsequent to pharmacotherapy[3][4][5]

Risks of medical treatment

  • While medicines have led to major improvement in the treatment and control of diseases, they also produce adverse effects on the human body from time to time.
  • While many drugs are precisely targeted to the causes and mechanisms of disease, they may also have minor or distressing effects on other parts of the body, or interact negatively with the systems of the particular individual or with other drugs or substances they are taking, or not work well or at all for some, many or all of those who take them for illness.
  • There are risks in any intrusion into the human body, whether chemical or surgical. Nothing in this field is entirely predictable as the interaction between chemicals and the human body may produce surprises.

Terms commonly used in drug safety

  • Benefits are commonly expressed as the proven therapeutic good of a product, but should also include the patient’s subjective assessment of its effects.
  • Risk is the probability of harm being caused, usually expressed as a percent or ratio of the treated population; the probability of an occurrence.
  • Harm is the nature and extent of the actual damage that could be caused. It should not be confused with risk.
  • Effectiveness is used to express the extent to which a drug works under real world circumstances, i.e., clinical practice (not clinical trials).
  • Efficacy is used to express the extent to which a drug works under ideal circumstances (i.e., in clinical trials).

Finding the risks of drugs

Pharmaceutical companies are required by law in all countries to perform clinical trials, testing new drugs on people before they are made generally available. The manufacturers or their agents usually select a representative sample of patients for whom the drug is designed — at most a few thousand — along with a comparable control group. The control group may receive a placebo and/or another drug that is already marketed for the disease.

The purpose of clinical trials is to discover:

  • if a drug works and how well
  • if it has any harmful effects, and
  • its benefit-harm-risk profile - does it do more good than harm, and how much more? If it has a potential for harm, how probable and how serious is the harm?

Clinical trials do, in general, tell us a good deal about how well a drug works and what potential harm it may cause. They provide information which should be reliable for larger populations with the same characteristics as the trial group - age, gender, state of health, ethnic origin, and so on.

The variables in a clinical trial are specified and controlled and the results relate only to the population of which the trial group is a representative sample. A clinical trial can never tell you the whole story of the effects of a drug in all situations. In fact, there is nothing that could tell you the whole story, but a clinical trial must tell you enough; "enough" being determined by legislation and by contemporary judgements about the acceptable balance of benefit and harm.

Spontaneous reporting

Spontaneous reporting is the core data-generating system of international pharmacovigilance, relying on healthcare professionals (and in some places consumers) to identify and report any suspected adverse drug reaction to their national pharmacovigilance center or to the manufacturer.[6] Spontaneous reports are almost always submitted voluntarily.

One of this system’s major weaknesses is under-reporting, though the figures vary greatly between countries and in relation to minor and serious ADRs (also referred to as ICSRs, individual case safety reports).

Another problem is that overworked medical personnel do not always see reporting as a priority. If the symptoms are not serious, they may not notice them at all. And even if the symptoms are serious, they may not be recognised as the effect of a particular drug.

Even so, spontaneous reports are a crucial element in the worldwide enterprise of pharmacovigilance and form the core of the World Health Organization Database, which includes around 4.6 million reports (January 2009)[7], growing annually by about 250,000.[8]

Other reporting methods

Some countries legally oblige spontaneous reporting by physicians. In most countries, manufacturers are required to submit,through its Qualified Person for Pharmacovigilance QPPV, all the reports they receive from healthcare providers to the national authority. Others have intensive, focused programmes concentrating on new drugs, or on controversial drugs, or on the prescribing habits of groups of doctors, or involving pharmacists in reporting. All of these generate potentially useful information. Such intensive schemes, however, tend to be the exception.

International collaboration

The principle of international collaboration in the field of pharmacovigilance is the principal basis for the WHO International Drug Monitoring Programme, through which over 90 member nations have systems in place which encourage healthcare personnel to record and report adverse effects of drugs in their patients. These reports are assessed locally and may lead to action within the country. Through membership of the WHO Programme one country can know if similar reports are being made elsewhere. (The European Union also has its own scheme.)

Member countries send their reports to the Uppsala Monitoring Centre where they are processed, evaluated and entered into the WHO International Database. When there are several reports of adverse reactions to a particular drug this process may lead to the detection of a signal — an alert about a possible hazard communicated to members countries. This happens only after detailed evaluation and expert review.

Pharmacovigilance of Herbal Medicines

The safety of herbal medicines has become a major concern to both national health authorities and the general public[9]. The use of herbs in Traditional medicines continues to expand rapidly across the world. Many people now take herbal medicines or herbal products for their health care in different national health-care settings. However, mass media reports of adverse events tend to be sensational and give a negative impression regarding the use of Herbal medicines in general rather than identifying the causes of these events, which may relate to a variety of issues[10].

Pharmacovigilance by region

Europe

The pharmacovigilance effort in Europe is coordinated by the European Medicines Agency (EMA) and conducted by the national competent authorities (NCAs). The main responsibility of the EMA is to maintain and develop the pharmacovigilance database consisting of all suspected serious adverse reactions to medicines observed in the European Community. The system is called EudraVigilance and contains separate but similar databases of human and veterinary reactions.

Europe requires the individual marketing authorisation holders (drug companies), to submit all received adverse reactions in electronic form (save in exceptional circumstances). The reporting obligations of the various stakeholders are defined in the Community legislation, in particular:

Reporting can be performed with software developed for the purpose or with a web utility called EVWEB accessible through the EudraVigilance homepage. Registration for use of EVWEB is necessary.

In 2002 Heads of Medicines Agencies[11] agreed on a mandate for an ad hoc Working Group on establishing a European risk management strategy. The Working Group considered the conduct of a high level survey of EU pharmacovigilance resources to promote the utilisation of expertise and encourage collaborative working.

Japan

In Japan, pharmacovigilance is regulated by the PMDA and MHLW.

United States

Three primary branches of pharmacovigilance in the U.S. include the FDA, the pharmaceutical manufacturers, and the academic/non-profit organizations (such as RADAR and Public Citizen).

See also

References

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External links

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  1. Source: The Importance of Pharmacovigilance, WHO 2002
  2. WHO Technical Report No 498 (1972)
  3. SZ Rahman, RA Khan, V Gupta & Misbahuddin. Pharmacoenvironmentology – Ahead of Pharmacovigilance. In: Rahman SZ, Shahid M & Gupta A Eds. An Introduction to Environmental Pharmacology (ISBN # 978-81-906070-4-9). Ibn Sina Academy, Aligarh, India, 2008: 35-42
  4. S Z Rahman, R A Khan, Varun Kumar, Misbahuddin, Pharmacoenvironmentology – A Component of Pharmacovigilance, Environmental Health 2007, 6:20 (24 Jul 2007)
  5. Ilene Sue Ruhoy, Christian G. Daughton. Beyond the medicine cabinet: An analysis of where and why medications accumulate. Environment International 2008, Vol. 34 (8): 1157-1169
  6. Lindquist M. Vigibase, the WHO Global ICSR Database System: Basic Facts. Drug Information Journal, 2008, 42:409-419.
  7. http://www.who-umc.org/DynPage.aspx?id=13140&mn=1514, accessed 10 February 2009.
  8. Pharmacovigilance. Mann RD, Andrews EB, eds. John Wiley & Sons Ltd, Chichester, 2002.
  9. WHO guidelines on safety monitoring of herbal medicines in pharmacovigilance systems, World Health Organization, Geneva, 2004
  10. S Z Rahman & K C Singhal, Problems in pharmacovigilance of medicinal products of herbal origin and means to minimize them, Uppsala Reports, WHO Collaborating Center for ADR monitoring, Uppsala Monitoring Centre, Sweden, Issue 17 January 2002: 1-4 (Supplement)
  11. http://heads.medagencies.org/