Pharmaceutical drug

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A pharmaceutical drug, also referred to as medicine, medication or medicament, can be loosely defined as any chemical substance intended for use in the medical diagnosis, cure, treatment, or prevention of disease.[1][2]

Classification

Medications can be classified in various ways,[3] such as by chemical properties, mode or route of administration, biological system affected, or therapeutic effects. An elaborate and widely used classification system is the Anatomical Therapeutic Chemical Classification System (ATC system). The World Health Organization keeps a list of essential medicines.

A sampling of classes of medicine includes:

  1. Antipyretics: reducing fever (pyrexia/pyresis)
  2. Analgesics: reducing pain (painkillers)
  3. Antimalarial drugs: treating malaria
  4. Antibiotics: inhibiting germ growth
  5. Antiseptics: prevention of germ growth near burns, cuts and wounds

Types of medications (type of pharmacotherapy)

For the gastrointestinal tract (digestive system)

For the cardiovascular system

For the central nervous system

Drugs affecting the central nervous system include: hypnotics, anaesthetics, antipsychotics, antidepressants (including tricyclic antidepressants, monoamine oxidase inhibitors, lithium salts, and selective serotonin reuptake inhibitors (SSRIs)), antiemetics, anticonvulsants/antiepileptics, anxiolytics, barbiturates, movement disorder (e.g., Parkinson's disease) drugs, stimulants (including amphetamines), benzodiazepines, cyclopyrrolones, dopamine antagonists, antihistamines, cholinergics, anticholinergics, emetics, cannabinoids, and 5-HT (serotonin) antagonists.

For pain & consciousness (analgesic drugs)

The main classes of painkillers are NSAIDs, opioids and various orphans such as paracetamol, tricyclic antidepressants and anticonvulsants.

For musculo-skeletal disorders

The main categories of drugs for musculoskeletal disorders are: NSAIDs (including COX-2 selective inhibitors), muscle relaxants, neuromuscular drugs, and anticholinesterases.

For the eye

For the ear, nose and oropharynx

sympathomimetics, antihistamines, anticholinergics, NSAIDs, steroids, antiseptics, local anesthetics, antifungals, cerumenolyti

For the respiratory system

bronchodilators, NSAIDs, anti-allergics, antitussives, mucolytics, decongestants
corticosteroids, Beta2-adrenergic agonists, anticholinergics, steroids

For endocrine problems

androgens, antiandrogens, gonadotropin, corticosteroids, human growth hormone, insulin, antidiabetics (sulfonylureas, biguanides/metformin, thiazolidinediones, insulin), thyroid hormones, antithyroid drugs, calcitonin, diphosponate, vasopressin analogues

For the reproductive system or urinary system

antifungal, alkalising agents, quinolones, antibiotics, cholinergics, anticholinergics, anticholinesterases, antispasmodics, 5-alpha reductase inhibitor, selective alpha-1 blockers, sildenafils, fertility medications

For contraception

For obstetrics and gynecology

NSAIDs, anticholinergics, haemostatic drugs, antifibrinolytics, Hormone Replacement Therapy (HRT), bone regulators, beta-receptor agonists, follicle stimulating hormone, luteinising hormone, LHRH
gamolenic acid, gonadotropin release inhibitor, progestogen, dopamine agonists, oestrogen, prostaglandins, gonadorelin, clomiphene, tamoxifen, Diethylstilbestrol

For the skin

emollients, anti-pruritics, antifungals, disinfectants, scabicides, pediculicides, tar products, vitamin A derivatives, vitamin D analogues, keratolytics, abrasives, systemic antibiotics, topical antibiotics, hormones, desloughing agents, exudate absorbents, fibrinolytics, proteolytics, sunscreens, antiperspirants, corticosteroids

For infections and infestations

antibiotics, antifungals, antileprotics, antituberculous drugs, antimalarials, anthelmintics, amoebicides, antivirals, antiprotozoals

For the immune system

vaccines, immunoglobulins, immunosuppressants, interferons, monoclonal antibodies

For allergic disorders

anti-allergics, antihistamines, NSAIDs

For nutrition

tonics, iron preparations, electrolytes, parenteral nutritional supplements, vitamins, anti-obesity drugs, anabolic drugs, haematopoietic drugs, food product drugs

For neoplastic disorders

cytotoxic drugs, therapeutic antibodies, sex hormones, aromatase inhibitors, somatostatin inhibitors, recombinant interleukins, G-CSF, erythropoietin

For diagnostics

contrast media

For euthanasia

An euthanaticum is used for euthanasia and physician-assisted suicide.

Euthanasia is not permitted by law in many countries, and consequently medicines will not be licensed for this use in those countries.

Legal considerations

Depending upon the jurisdiction, medications may be divided into over-the-counter drugs (OTC) which may be available without special restrictions, and prescription only medicine (POM), which must be prescribed by a licensed medical practitioner. The precise distinction between OTC and prescription depends on the legal jurisdiction. A third category, behind-the-counter medications (BTMs), is implemented in some jurisdictions. BTMs do not require a prescription, but must be kept in the dispensary, not visible to the public, and only be sold by a pharmacist or pharmacy technician. Doctors may also prescribe prescription drugs for off-label use - purposes which the drugs were not originally approved for by the regulatory agency. The Classification of Pharmaco-Therapeutic Referrals helps guide the referral process between pharmacists and doctors.

The International Narcotics Control Board of the United Nations imposes a world law of prohibition of certain medications. They publish a lengthy list of chemicals and plants whose trade and consumption (where applicable) is forbidden. OTC medications are sold without restriction as they are considered safe enough that most people will not hurt themselves accidentally by taking it as instructed. Many countries, such as the United Kingdom have a third category of pharmacy medicines which can only be sold in registered pharmacies, by or under the supervision of a pharmacist.

For patented medications, countries may have certain mandatory licensing programs which compel, in certain situations, a medication's owner to contract with other agents to manufacture the drug. Such programs may deal with the contingency of a lack of medication in the event of a serious epidemic of disease, or may be part of efforts to ensure that disease treating drugs, such as AIDS drugs, are available to countries which cannot afford the drug owner's price.

Prescription practice

Drugs which are prescription only are regulated as such because they can impose adverse effects and should not be used unless necessary. Medical guidelines and clinical trials required for approval are used to help inform doctors' prescription of these drugs, but errors can happen. Reasons to not prescribe drugs such as interactions or side effects are called contraindications.

Errors include overprescription and polypharmacy, misprescription, contraindication and lack of detail in dosage and administrations instructions. In 2000 the definition of a prescription error was studied using a Delphi method conference; the conference was motivated by ambiguity in the what a prescription error and a need to use a uniform definition in studies.[4]

Development

Drug development is the process by which a drug is created. Drugs can be extracted from natural products (pharmacognosy) or synthesized through chemical processes. The drug's active ingredient will be combined with a "vehicle" such as a capsule, cream, or liquid which will be administered through a particular route of administration. Child-resistant packaging will likely be used in the ultimate package sold to the consumer.

Blockbuster drug

A blockbuster drug is a drug generating more than $1 billion of revenue for its owner each year.[5]

A recent report from Urch Publishing estimated that about one third of the pharma market by value is accounted for by blockbusters. About 100 products are blockbusters. The top seller was Lipitor, a cholesterol-lowering medication marketed by Pfizer with sales of $12.2 billion.

Beyond this purely arbitrary financial consideration,

"In the pharmaceutical industry, a blockbuster drug is one that achieves acceptance by prescribing physicians as a therapeutic standard for, most commonly, a highly prevalent chronic (rather than acute) condition. Patients often take the medicines for long periods."[6]

Leading blockbuster drugs

Drug Trade name Company Sales[7][8] (billion $), year
Atorvastatin Lipitor Pfizer 12 (2007) >
Clopidogrel Plavix Bristol-Myers Squibb and sanofi-aventis 5.9 (2005)
Enoxaparin Lovenox or Clexane Sanofi-Aventis
Celecoxib Celebrex Pfizer 2.3 (2007)
Omeprazole Losec/Prilosec AstraZeneca 2.6 (2004)
Esomeprazole Nexium AstraZeneca 3.3 (2003)
Fexofenadine Telfast/Allegra Aventis 1.87 (2004)
Quetiapine Seroquel AstraZeneca 1.5 (2003)
Metoprolol Seloken/Toprol AstraZeneca 1.3 (2003)
Budesonide Pulmicort/Rhinocort AstraZeneca 1.3 (2003) (plus some fraction of the $0.6bn sales of Symbicort)

Environmental impact

Since the 1990s water contamination by pharmaceuticals has been an environmental issue of concern.[9] Most pharmaceuticals are deposited in the environment through human consumption and excretion, and are often filtered ineffectively by wastewater treatment plants which are not designed to manage them. Once in the water they can have diverse, subtle effects on organisms, although research is limited. Pharmaceuticals may also be deposited in the environment through improper disposal, runoff from sludge fertilizer and reclaimed wastewater irrigation, and leaky sewage.[9] In 2009 an investigative report by Associated Press concluded that U.S. manufacturers had legally released 271 million pounds of drugs into the environment, 92% of which was the antiseptics phenol and hydrogen peroxide. It could not distinguish between drugs released by manufacturers as opposed to the pharmaceutical industry. It also found that an estimated 250 million pounds of pharmaceuticals and contaminated packaging were discarded by hospitals and long-term care facilities.[10]

Pharmacoenvironmentology is a branch of 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, while Ecopharmacology is concerned with the entry of chemicals or drugs into the environment through any route and at any concentration disturbing the balance of ecology (ecosystem), as a consequence. Ecopharmacology is a broad term that includes studies of “PPCPs” irrespective of doses and route of entry into environment.[11][12][13]

History

Ancient pharmacology

Using plants and plant substances to treat all kinds of diseases and medical conditions is believed to date back to prehistoric medicine.

The Kahun Gynaecological Papyrus, the oldest known medical text of any kind, dates to about 1800 BCE and represents the first documented use of any kind of medication.[14][15] It and other medical papyri describe Ancient Egyptian medical practices, such as using honey to treat infections.

Ancient Babylonian medicine demonstrate the use of prescriptions in the first half of the 2nd millennium BC. Medicinal creams and pills were employed as treatments.[16]

On the Indian subcontinent, the Atharvaveda, a sacred text of Hinduism whose core dates from the 2nd millennium BCE, although the hymns recorded in it are believed to be older, is the first Indic text dealing with medicine. It describes plant-based medications to counter diseases.[17]. The earliest foundations of ayurveda were built on a synthesis of selected ancient herbal practices, together with a massive addition of theoretical conceptualizations, new nosologies and new therapies dating from about 400 BCE onwards.[18]. The student of Āyurveda was expected to know ten arts that were indispensable in the preparation and application of his medicines: distillation, operative skills, cooking, horticulture, metallurgy, sugar manufacture, pharmacy, analysis and separation of minerals, compounding of metals, and preparation of alkalis.

The Hippocratic Oath for physicians, attributed to 5th century BCE Greece, refers to the existence of "deadly drugs", and ancient Greek physicians imported medications from Egypt and elsewhere.[19]

The first drugstores were created in Baghdad in the 8th century CE. The injection syringe was invented by Ammar ibn Ali al-Mawsili in 9th century Iraq. Al-Kindi's 9th century CE book, De Gradibus, developed a mathematical scale to quantify the strength of drugs.[20]

The Canon of Medicine by Ibn Sina (Avicenna), who is considered the father of modern medicine,[21] reported 800 tested drugs at the time of its completion in 1025 CE.[citation needed] Ibn Sina's contributions include the separation of medicine from pharmacology, which was important to the development of the pharmaceutical sciences.[22] Islamic medicine knew of at least 2,000 medicinal and chemical substances.[23]

Medieval pharmacology

Medieval medicine saw advances in surgery, but few truly effective drugs existed, beyond opium and quinine. Folklore cures and potentially poisonous metal-based compounds were popular treatments. Theodoric Borgognoni, (1205–1296), one of the most significant surgeons of the medieval period, responsible for introducing and promoting important surgical advances including basic antiseptic practice and the use of anaesthetics. Garcia de Orta described some herbal treatments that were used.

Modern pharmacology

For most of the nineteenth century, drugs were not highly effective, leading Oliver Wendell Holmes, Sr. to famously comment in 1842 that "if all medicines in the world were thrown into the sea, it would be all the better for mankind and all the worse for the fishes".[24]:21

During the First World War, Alexis Carrel and Henry Dakin developed the Carrel-Dakin method of treating wounds with an irrigation, Dakin's solution, a germicide which helped prevent gangrene.

In the inter-war period, the first anti-bacterial agents such as the sulpha antibiotics were developed. The Second World War saw the introduction of widespread and effective antimicrobial therapy with the development and mass production of penicillin antibiotics, made possible by the pressures of the war and the collaboration of British scientists with the American pharmaceutical industry.

Medicines commonly used by the late 1920s included aspirin, codeine, and morphine for pain; digitalis, nitroglycerin, and quinine for heart disorders, and insulin for diabetes. Other drugs included antitoxins, a few biological vaccines, and a few synthetic drugs. In the 1930s antibiotics emerged: first sulfa drugs, then penicillin and other antibiotics. Drugs increasingly became "the center of medical practice".[24]:22 In the 1950s other drugs emerged including corticosteroids for inflammation, rauwolfia alkloids as tranqulizers and antihypertensives, antihistamines for nasal allergies, xanthines for asthma, and typical antipsychotics for psychosis.[24]:23-24 As of 2008, thousands of approved drugs have been developed. Increasingly, biotechnology is used to discover biopharmaceuticals.[24]

In the 1950s new psychiatric drugs, notably the antipsychotic chlorpromazine, were designed in laboratories and slowly came into preferred use. Although often accepted as an advance in some ways, there was some opposition, due to serious adverse effects such as tardive dyskinesia. Patients often opposed psychiatry and refused or stopped taking the drugs when not subject to psychiatric control.

Governments have been heavily involved in the development and sale of drugs. In the U.S., the Elixir Sulfanilamide disaster led to the establishment of the Food and Drug Administration, and the 1938 Federal Food, Drug, and Cosmetic Act required manufacturers to file new drugs with the FDA. The 1951 Humphrey-Durham Amendment required certain drugs to be sold by prescription. In 1962 a subsequent amendment required new drugs to be tested for efficacy and safety in clinical trials.[24]:24-26

Until the 1970s, drug prices were not a major concern for doctors and patients. As more drugs became prescribed for chronic illnesses, however, costs became burdensome, and by the 1970s nearly every U.S. state required or encouraged the substitution of generic drugs for higher-priced brand names. This also led to the 2006 U.S. law, Medicare Part D, which offers Medicare coverage for drugs.[24]:28-29

As of 2008, the United States is the leader in medical research, including pharmaceutical development. U.S. drug prices are among the highest in the world, and drug innovation is correspondingly high. In 2000 U.S. based firms developed 29 of the 75 top-selling drugs; firms from the second-largest market, Japan, developed eight, and the United Kingdom contributed 10. France, which imposes price controls, developed three. Throughout the 1990s outcomes were similar.[24]:30-31

See also

References

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External links

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  1. US Federal Food, Drug, and Cosmetic Act, SEC. 210., (g)(1)(B). Accessed 17 August 2008.
  2. Directive 2004/27/EC of the European Parliament and of the Council of 31 March 2004 amending Directive 2001/83/EC on the Community code relating to medicinal products for human use. Article 1. Published March 31, 2004. Accessed 17 August 2008.
  3. www.epgonline.org database of prescription pharmaceutical products including drug classifications [1]
  4. Lua error in package.lua at line 80: module 'Module:Citation/CS1/Suggestions' not found.
  5. ""Blockbuster medicine" is defined as being one which achieves annual revenues of over US$ 1 billion at global level." in European Commission, Pharmaceutical Sector Inquiry, Preliminary Report (DG Competition Staff Working Paper), 28 November 2008, page 17 (pdf, 1.95 MB).
  6. Finkelstein, Temin "Reasonable Rx: Solving the Drug Price Crisis" 11 January 2008
  7. Pharmaceutical Market Trends, 2006-2010, from Urch Publishing
  8. Blockbuster Drugs 2006: Executive Overview, from Report Buyer
  9. 9.0 9.1 Lua error in package.lua at line 80: module 'Module:Citation/CS1/Suggestions' not found.
  10. Donn J. (2009). Tons of Released Drugs Taint U.S. Water. AP.
  11. 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
  12. S Z Rahman, R A Khan, Varun Kumar, Misbahuddin, Pharmacoenvironmentology–A Component of Pharmacovigilance, Environmental Health 2007, 6:20 (24 Jul 2007)
  13. 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
  14. Griffith, F. Ll. The Petrie Papyri: Hieratic Papyri from Kahun and Gurob
  15. The Kahun Gynaecological Papyrus
  16. H. F. J. Horstmanshoff, Marten Stol, Cornelis Tilburg (2004), Magic and Rationality in Ancient Near Eastern and Graeco-Roman Medicine, p. 99, Brill Publishers, ISBN 9004136665.
  17. See Atharvaveda XIX.34.9
  18. Kenneth G. Zysk, Asceticism and Healing in Ancient India: Medicine in the Buddhist Monastery, Oxford University Press, rev. ed. (1998) ISBN 0195059565
  19. Heinrich Von Staden, Herophilus: The Art of Medicine in Early Alexandria (Cambridge: Cambridge University Press, 1989), pp. 1-26.
  20. Felix Klein-Frank (2001), Al-Kindi, in Oliver Leaman and Hossein Nasr, History of Islamic Philosophy, p. 172. Routledge, London.
  21. Cas Lek Cesk (1980). "The father of medicine, Avicenna, in our science and culture: Abu Ali ibn Sina (980-1037)", Becka J. 119 (1), p. 17-23.
  22. Bashar Saad, Hassan Azaizeh, Omar Said (October 2005). "Tradition and Perspectives of Arab Herbal Medicine: A Review", Evidence-based Complementary and Alternative Medicine 2 (4), p. 475-479 [476]. Oxford University Press.
  23. Information taken from the abstract of Hadzović, S (1997). "[Pharmacy and the great contribution of Arab-Islamic science to its development] (Article in Croatian)". Medicinski arhiv. 51 (1–2): 47–50. ISSN 0350-199X. PMID 9324574. 
  24. 24.0 24.1 24.2 24.3 24.4 24.5 24.6 Finkelstein S, Temin P (2008). Reasonable Rx: Solving the drug price crisis. FT Press.