Pharmacognosy

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Pharmacognosy is the study of medicines from natural sources. The American Society of Pharmacognosy[1] defines pharmacognosy as "the study of the physical, chemical, biochemical and biological properties of drugs, drug substances or potential drugs or drug substances of natural origin as well as the search for new drugs from natural sources".

The word "Pharmacognosy" derives from the Greek words pharmakon (drug), and gnosis or knowledge.

The term was used for the first time by the Austrian physician Schmidt in 1811. Originally - during the 19th century and the beginning of the 20th century - pharmacognosy was used to define the branch of medicine or of commodity sciences ("Warenkunde" in German), which dealt with drugs in their crude, or unprepared, form.

A "crude drug" means a dried unprepared natural material of plant, animal or mineral origin, which is used for medicine. The term drug derives from the Lower Saxon/Dutch "Droog", which means "dried" as in dried herbs (and has little to do with the modern pharmaceutical meaning of the term).

The term "Pharmakognosie" and it discipline developed in German speaking areas of Europe - where it is a synonym of "Drogenkunde" ("science of the crude drugs").

Contents

  • 1 Pharmacognosy Today
  • 2 Issues in Pharmacognosy
    • 2.1 Lack of Studies Proving Traditional Uses
    • 2.2 Controversy about Active Constituents
    • 2.3 Standardization
    • 2.4 Quality
    • 2.5 Safety
    • 2.6 Herb and Drug Interactions
    • 2.7 Confusion of Constituents with Whole Products
    • 2.8 Studies done Without Proper Identification of Assay of Plant Materials
    • 2.9 Studies Done with Non-Inert Placebos[25]
    • 2.10 Standards for Random Clinical Trials
    • 2.11 Indexing Issues and Megastudies
    • 2.12 Loss of Species
    • 2.13 Sustainable Sources of Plant and Animal Drugs
    • 2.14 Need for Pharmacognosy Education
    • 2.15 External links
    • 2.16 References

[edit] Pharmacognosy Today

Prior to the 1950’s every pharmacy student learned about crude drugs in pharmacognosy class. Pharmacognosy includes the study of the proper horticulture, harvesting and uses of the raw medicinals found in nature. Its scope includes the identification or authentication of crude drugs (using macroscopical, microscopical, radiological or chemical methods), and their bio-pharmacological and clinical evaluations.

Most of the pharmacognostic studies are focused on medicinal plants/herbal medicines.

Pharmacognosy is interdisciplinary, drawing from a broad spectrum of biological and even socio-scientific subjects: botany, ethnobotany, marine biology, microbiology, herbal medicine, chemistry (phytochemistry), pharmacology, pharmaceutics, clinical pharmacy and pharmacy practice related to the evaluation and clinical uses of medicines from natural sources, as well as their implications in health care management and public health.

In a few academic contexts, the term has been artificially extended to cover also the study of pure, isolated substances of natural origin as well as the search for new drugs from natural sources (although that should be considered a branch of the organic chemistry known as "natural product chemistry").

Although today pharmacognosy is still taught in a small number of university pharmacy schools in US and in the UK, this subject is still obligatory within the pharmacy curricula in all universities of continental Europe. As more Americans are engaging in the use of herbal medicine, traditional Chinese medicine and other uses of natural products, there is increasing pressure to revive pharmacognosy training in pharmacy and medical schooling.

[edit] Issues in Pharmacognosy

[edit] Lack of Studies Proving Traditional Uses

This is especially an issue in the United States where the use of herbal medicine has fallen out of use since the Second World War and was considered suspect since the Flexner Report of 1910 led to the closing of the eclectic medical schools where botanical medicine was exclusively practiced. Without an intact tradition of the use of herbal products, and contrasted to the presence of studies for pharmaceutical drugs, doctors and pharmacists lack a level of confidence in herbal and other crude drugs. This is further complicated by most herbal studies in the latter part of the 20th Century having been published in languages other than English such as German, Dutch, Chinese, Japanese, Korean and Farsi. The US Food and Drug Administration "FDA" does not draw upon most foreign language publications or international assessments of drug safety in its determinations of drug safety. As a result one erroneously hears that herbal medicine is unstudied. The costs of testing drugs are sizable, and without the patent protection available to synthetic drugs, companies are reluctant to test herbal medicines. In 1994 the US Congress passed the Dietary Supplement Health and Education Act (DSHEA), regulating labeling and sales of herbs and other supplements. As a result most of the 2000 US companies making herbal or natural products[2] choose to market their products as food supplements that do not require substantial testing.

[edit] Controversy about Active Constituents

In herbal medicine circles the very concept of "active ingredient" is controversial since most phytopharmaceuticals rely upon constituent synergy for their activities. Plants with high levels of assumed active constituents like ginsenosides or hypericin may not correlate with the strength of the herbs. Many herbs are poorly characterized or while well-characterized will rely upon the synergy of otherwise weak principles. In phytopharmaceutical or herbal medicine the active ingredient may be either unknown or may require cofactors in order to achieve therapeutic goals. One way manufacturers have attempted to indicate strength is to engage in standardization to a marker compound. companies use different markers, or different levels of the same markers, or different methods of testing for marker compounds. Many herbalists believe that the active ingredient in a plant is the plant itself.[3]

[edit] Standardization

In herbal medicine standardization refers to providing processed plant material that meets a specified concentration of a specific marker constituent. However plant constituents have synergy and even active constituent concentrations may be misleading measures of potency if cofactors are not present. A further problem is that the important constituent is often unknown. For instance St. Johnswort is often standardized to the antiviral constituent hypericin which is now known not to be the "active ingredient" for antidepressant use. Other companies standardize to hyperforin or both, although there may be some 24 known possible constituents. Only a minority of chemicals used as standardization markers are known to be active constituents. Standardization has not been standardized yet: different companies use different markers, or different levels of the same markers, or different methods of testing for marker compounds. Herbalist and manufacturer David Winston points out that whenever different compounds are chosen as "active ingredients" for different herbs, there is a chance that suppliers will get a substandard batch (low on the chemical markers) and mix it with a batch higher in the desired marker to compensate for the difference.[4]

[edit] Quality

Quality in the use of crude drugs or plant medicines depends upon a variety of factors: genetically strong seed, correct species, maturity of the plant at harvest, good soils, air quality, climate, organoleptic factors such as intensity of color, flavor and odor, processing after harvest and a variety of other factors. These conditions have been noted in historical herbals such as Culpepper's Complete Herbal [5] or the The Shen Nong or Divine Farmer's Materia Medica[6] This was standard pharmacognosy curriculum for many years. Storage after collection is a factor worthy of study: Researchers in Nara, Japan have stored samples of ginseng root (Panax ginseng), licorice root (Glycyrrhiza glabra) and rhubarb root (Rheum emodi) that have been shown to retain their active properties for over 1,200 years. [7]

In modern times the foregoing aspects are no less important, but have been neglected with the advent of laboratory testing, although it generally is true that only certain constituents are identified and measured. Processes like HPLC (High performance liquid chromatography), GC (gas chromatography), UV/VIS (Ultraviolet/Visible spectrophotometry) or AA (Atomic Absorption spectroscopy)are used to identify species, measure bacteriological contamination, assess potency and eventually creating Certificates of Analysis for the material.

Quality should be overseen by either authorities ensuring Good Manufacturing Practices or regulatory agencies by the US FDA. In the United States one frequently sees comments that herbal medicine is unregulated, but this is not correct since the FDA and GMP regulations are in place. In Germany, the Commission E has produced a book of German legal-medical regulations which includes quality standards . [8]

[edit] Safety

The political issues around the safety of crude drugs vary from considering natural remedies "safe" regardless of potential dangers to considering them a dangerous unknown.[9] In fact, noted USDA researcher and scientist Dr. James Duke estimates the dangers of herbal medicine relative to other dangers in the United States as follows:

  • Herbs 1 in 1,000,000
  • Supplements 1 in 1,000,000
  • Poisonous Mushrooms 1 in 100,000
  • NSAID's 1 in 10,000
  • Hospital Surgery 1 in 10,000
  • Car Accident 1 in 5,000
  • Improper Use of Medication 1 in 2,000
  • Angiogram 1 in 1,000
  • Alcohol 1 in 500
  • Cigarettes 1 in 500
  • Properly Prescribed Medications 1 in 333
  • Medical Mishap 1 in 250
  • Iatrogenic Hospital Infection 1 in 80
  • Bypass Surgery 1 in 20
[10]

In a 19 year analysis of poison control calls in the United States, 44.6% were due to pharmaceuticals and only 2.4% were due to plants. This includes not only ingestion of herbs but exposure to poison ivy, children eating houseplants and allergic responses. The vast majority did not involve herbal medicines. [11] More recent compilations of calls to poison control centers in the US found only 37 deaths in the highest year, but the data were not vetted in order to see whether herbs were actually involved: one death counted as "ephedra related" involved the death by automobile accident of a person with three times the legal blood alcohol level who had an unopened bottle of ephedra in the front seat, although there was no evidence that the drunk driver had ever taken ephedra.[12] [13]

As Paul Bergner, Editor of the journal Medical Herbalism and author of several articles on herbal toxicity recently pointed out:

Approximately 8% of all hospital admissions in the U.S. are due to adverse reactions to synthetic drugs. That's a minimum of 2,000,000. At least 100,000 people a year die from them. That's just in the U.S., and that's a conservative estimate. That means at least three times as many people are killed in the U.S. by pharmaceutical drugs as are killed by drunken drivers. Thousands die each year from supposedly "safe" over-the-counter remedies. Deaths or hospitalizations due to herbs are so rare that they're hard to find. The U.S. National Poison Control Centers does not even have a category in their database for adverse reactions to herbs.[14]

Similar figures apply in the United Kingdom. Hepatoxicity, where perhaps the strongest case against some herbs lies, the statistics show that over 80% of cases of fulminant hepatic failure presenting for liver transplant (or death) over ten years in the UK were due to poisoning by freely available non-prescription NSAID's, such as paracetomol and aspirin. Not one case was due to ingestion of medicinal herbs.[15]

While there are certainly poisonous plants which have limited medicinal use, most are not sold in material doses in the United States or are available only to trained practitioners. These include Aconite, Arnica, Belladonna, Bryonia, Datura, Gelsemium, Henbane, Male Fern, Phytolacca, Podophyllum, and Veratrum. Secondly, are herbs with powerful actions, often causing nausea, sweating vomiting, (that usually were traditionally prized for this action)which are perfectly safe used under appropriate conditions, like Lobelia, Ephedra and Eonymus. Third are plants with specific toxicity like hepatotoxic pyrrolizidine alkaloids like Comfrey or Petasites. There are other plant medicines which require caution or can interact with medications including St. Johnswort or grapefruit. [16]

[edit] Herb and Drug Interactions

Although herbs and drugs have been combined for centuries in Asia and Europe, and worldwide most drugs are herbal, the disrupted relationship between traditional herbal medicine and pharmaceutical allopathic medicine in the United States has created a climate whereby herbs are considered dangerous to combine with pharmaceuticals and information developed in other countries is not readily available. As a result websites like that of the University of Maryland Medical Center, which purport to show information on herbal safety show cases that may lack the appropriate pharmacokinetics to produce the adverse results inferred. The Sloan Kettering Memorial Cancer Center site is even more problematic, suggesting that antioxidants interfere with chemotherapy despite numerous studies to the contrary.[17][18] A study of herb drug interactions indicated that the vast majority of drug interactions occurred in four classes of drugs with narrow therapeutic windows, the chief class being blood thinners, but also including protease inhibitors, cardiac glycosides and certain antibiotics like cyclosporin. [19] [20]

The major herbs that have caused interactions include St. Johnswort, which will counteract immunosupressive drugs and interfere with digoxin and protease inhibitors. A complete list can be found at: http://www.herbological.com/images/SJW_table.pdf Ginkgo biloba may have anti-platelet effects, although the results are not clear as it also contains flavanoids that improve blood function. Although constituents of garlic, peppermint and milk thistle have been shown to have effects on the CYP3A4 enzymes in vitro, it is not clear that the whole herb will have a similar effect in vivo. Many herbs that are listed as "potentiating" merely have an additive effect, and including laxative herbs as antagonistic to anti-diarrheal medications is tautological. [21]

[edit] Confusion of Constituents with Whole Products

One characteristic of crude drug material is that constituents may have an opposite, moderating or enhancing effect. Hence when any constituent is isolated it does not follow that its actions represent the whole herb. For instance, ephedra has constituents that increase the heart rate and constituents that decrease it. The drug ephedrine only used the constituents that increased the heart rate and had side effects absent from the traditional preparation of the herb. A significant number of studies have been done on plant isolates for the pharmacological industry, but they are frequently mischaracterized as representing the actions of the herb as a whole. This is particularly true in indexing in services such as Medline. [22]

[edit] Studies done Without Proper Identification of Assay of Plant Materials

With the decline in pharmacognosy education in the United States, it has been common for herbal research to be done on plants that have not been botanically identified, which have not been assayed for strength and which do not allow for proper understanding of the herb named in the research. For instance, Eleutherococcus senticosus is frequently identified as "ginseng" although it is not part of the Panax species and has significantly different medicinal characteristics. Echinacea has been "debunked" in studies where no attempt had been made to ensure that the species was proper, the correct part of the plant had been used or that a standard dosage had been used. [23] As Jonathan Treasure, NIMH, has written, "Inaccurate spelling of herb names is not uncommon in medical literature as all herbalists can attest, but more frequently there is a complete failure to use proper scientific nomenclature for botanicals. This is not a trivial issue, because without a validated description of a herb by its binomial name (and preferably the naming Authority) the identity of the herb cannot be established." [24] Studies have often been done on herbs with adulterants or where long storage has weakened constituent levels. It is not uncommon for scientists completely lacking clinical experience in using medicinal herbs to design studies to test the efficacy of herbs, without the expertise of a consulting herbalist and thus to fail at basics like using a species correctly for the use intended, chosing medicinally appropriate forms of the herb, chosing high quality herb or using a medicinally active dosage.

[edit] Studies Done with Non-Inert Placebos[25]

The loss of knowledge about the effects of plant materials has led to clinical trials being done with plant material designated as "placebo" when in fact it is not inert. In some cases the placebo was chosen to match the color, aroma or flavor of an herb when color, aroma or flavor may be correlated with biochemical constituents of similar activity. (For example yellow color correlates with the presence of berberine, an antimicrobial compound found in plants ranging from goldenseal to phellodendron to yellow root.) Since all plant-based medicinal systems tend to stereotype the actions of a plant, based upon local availability or the presence of a more potent alternative, the researcher with a casual knowledge of herbal medicine may be unaware of less common uses of plants designated as placebos. And there are medicinal aspects to sugar pills, recognized from western medicine to Ayurveda and Traditional Chinese medicine.

[edit] Standards for Random Clinical Trials

The Consolidated Standards of Reporting Trials (CONSORT) group came up with standards for random clinical trials (RTC) of herbs in 1996, revised in 2002. This statement comprises a 22-item checklist and flow diagram to guide authors, peer reviewers, editors, and readers on the essential information required in reports of two-group parallel RCTs of natural products. The CONSORT statement is endorsed by leading medical journals, editorial groups, professional societies, and funding bodies.[26]

  • The title and/or abstract should include the Latin binomial for the plant species from which the herbal medicine(s) originated, the part(s) of the plant used in the preparation, and the type of preparation (e.g., dried crude herb, ethanolic extract). The background ...should include a statement explaining the rationale for investigation of the specific herbal medicinal product and whether the indication for which it is being tested is new or is based on traditional use. Participant eligibility criteria ...in a trial testing a traditional indication (e.g., in traditional Chinese herbal medicine, a trial may test the effects of an herbal medicine intervention for liver chi (Qi) deficiency) should describe the theories and concepts underlying this indication.
  • The description of the intervention ...must include the herbal medicinal product name, manufacturer, plant part used, type of preparation, source and authentication of the herbal material, pharmaceutical quality (e.g., herbal drug-to-extract ratio, type and concentration of the extraction solvent, quantity of known active constituents per unit dose), and dosage regimen and qualitative testing (purity). Also, reporting of the rationale for the control/placebo used in the trial is recommended. For studies involving herbal medicine practitioners as part of the intervention, details of practitioners (e.g., training, registration status) should be reported. Not all recommendations are relevant for all types of herbal medicine interventions. Therefore, we begin this section with the words "where applicable." For example, a report of an RCT of an herbal medicinal product comprising crude herbal material (e.g., leaves, stems, root) prepared as a tea or decoction does not require reporting of the "type and concentration of solvent used and the plant to plant extract ratio"... In addition, herbal interventions made by the investigators specifically for the study will not have a finished product or extract name or manufacturer ...For such products, all methods used in preparing and formulating the product must be reported. Similarly, allegiance is only relevant for studies in which the practitioner is a part of the intervention. In other studies, the practitioner may serve a more neutral role and thus their characteristics need not be reported. With these exceptions, all information outlined in these recommendations are suggested to be reported for all herbal medicine interventions.
  • Also, outcome measures ...should reflect the intervention and indications tested while considering their underlying theories and concepts. For the results section, it is recommended that in addition to other baseline data..., RCTs of herbal medicine interventions report any concomitant medication, herbal medicinal product, or other CAM use. It is recommended that when interpreting the results ... there be consideration of the specific herbal product and dosage regimen tested. This includes an overview of evidence on this particular herbal medicinal product. When considering generalizability ...), it is suggested that authors report how the product used in the trial generalizes to products used in self-care and/or in clinical practice. Finally, when interpreting the results in the context of the evidence it is recommended that a general discussion in relation to trials of other available products should be reported.[27]

[edit] Indexing Issues and Megastudies

With the rise of megastudies and the advent of computerized researching, the structure of search engines such as MEDLINE tend to increase medical misinformation. For instance, a substantial number of studies are classified under misspellings. A search of MEDLINE for papers published on ginkgo misses 160 or 8% of potentially important reports because they are entered under the misspelled name "gingko" (sic).[28] Misspellings are not only significant for loss of indexing but because they frequently are correlated with the failure to properly identify the species.

Herbalist Jonathan Treasure, NIMH, traces the growth of misinformation on an alleged adverse herb-drug interaction between the monoamine oxidase inhibitor phenelzine and Asian ginseng (Panax ginseng C.A. Meyer). This originally was mentioned in a 1985 editorial by the then editors of the Journal of Clinical Psychopharmacology, Shader and Greenblatt where they devoted a couple of lines to the case of 64 year-old woman who took an undisclosed dose for an undisclosed time of a combination dietary supplement product called “Natrol High” while concurrently taking phenelzine 60 mg qd. She experienced symptoms of “insomnia, headache, and tremulousness”. Treasure contacted Natrol by email and discovered within ten minutes that there was no Panax ginseng in the formula, but instead eleutherococcus which was then called by the popular name "Siberian ginseng" and it was given in a subclinical dosage mixed with a variety of other herbs. The purported interaction effects are well-known side effects of phenelzine alone, which had been given in a high dosage and are not at all suggestive of eleutherococcus. However this misinformed article with a misidentified herb has been picked up in literature searches, megastudies and is now is documented by conventional medical authorities such as Stockley’s , and is repeated in several botanical monographs e.g. World Health Organization (WHO 1999).[29][30][31]

This occurs because of what Treasure calls the "cascading effect" of Medline where "primary observations shown to be significant by tertiary analyses are deemed to be validated ‘real’ effects. [He demonstrates] that the system actually works in reverse, with successive generations of secondary reviews amplifying the errors of previous derivative articles that were in turn based on erroneous primary data or speculation." The aura of scientific validity cast by Medline over compiled articles that have not been vetted for accuracy tends to exacerbate this effect.[32]

[edit] Loss of Species

One major source of species loss is the rate of habitat destruction. Less than 50% of the area covered by prehistoric tropical rainforests remains, yet tropical rainforests are still being cut and burned at a rate of approximately l42,000 square kilometres each year, equal in area to the countries of Switzerland and the Netherlands combined. (Wilson l992). It is this destruction which is primarily responsible for the mass extinction of the world's species. There are an estimated l0 million to l00 million different species on Earth. Based upon a conservative estimate of 20 million total world species, then l0 million species would be found in tropical rainforests, and at current rates of tropical deforestation, this would mean 27,000 species would be lost in tropical rainforests alone each year, or more than seventy-four per day, three each hour [33] [34]

Plant, animal and microbial species are themselves the sources for some of today's most important medicines and make up a significant proportion of the total pharmacopoeia. [35] Farnsworth for example, has found that 25% of all prescriptions dispensed from community pharmacies in the United States from l959 to l980 contained active ingredients extracted from higher plants. A much higher percentage is found in the developing world. As many as 80% of all people living in developing countries, or roughly two thirds of the world's population, rely almost exclusively on traditional medicines using natural substances, mostly derived from plants.

The knowledge held by traditional healers, often passed down orally over centuries, has led to the discovery of many medicines that are widely used today - quinine, physostigmine, d-tubocurarine, pilocarpine and ephedrine, to name a few [36] But that knowledge is fast disappearing, particularly in the Amazon, as native healers die out and are replaced by more modern medical practitioners. Botanists and pharmacologists are racing to learn these ancient practices, which, like the forest plants they employ, are also endangered [37][38] [39]

Scientists have analysed the chemistry of less than 1% of known rainforest plants for biologically active substances [40] - as well as a similar proportion of temperate plants [41] and even smaller percentages of known animals, fungi and microbes. But there may be tens of millions of species as yet undiscovered in the forests, in soils, and in lakes and oceans which with massive extinctions currently in progress, we may be destroying new cures for many old and newly emerging illnesses.[42]

A more controversial explanation for some species loss is habitat lost to invasive species introduction. While Farnsworth and others suggest that this is a major danger, others like David Theodoropoulos argue that species have always moved and data shows, for instance that purple loosestrife, identified as invasive, may result in higher levels of native pollinators than displaced drossera and that development of land has had a greater effect on the native species [43] Probably the truth lies in the middle: it is difficult to deny the effect of Kudzu (Pueria spp.) overtaking native species in the Southern American states, yet other species may have less effect than the growth of shopping centers on previously wild land. Herbalist David Winston has suggested that a high proportion of nonnative species seen as invasive (kudzu, Japanese knotweed, mimosa, lonicera, St. Johnswort and purple loosestrife) be harvested for the domestic herbal medicine market.[44]

However species extinction is not only due to habitat loss. Overharvesting of medicinal species of plants and animals also contributes to species loss. This is particularly notable in the matter of Traditional Chinese Medicine where crude drugs of plant and animal origin are used with increasing demand. People with a stake in TCM often seek chemical and biological alternatives to endangered species because they realize that plants and animals lost from the wild are also lost to medicine forever but different cultural attitudes bedevil conservation efforts. Still conservation is not a new idea: Chinese advice against overexploitation of natural medicinal species dates from at least Mencius, a philosopher living in the 4th century BC.

Cooperation between western conservationists and practitioners have been beset by cultural difficulties. Western conservationists often speak with combative urgency, while less confrontational Chinese who hear their medicine denigrated as unscientific often view conservationists as rude and arrogant. One repeated fallacy is that rhinoceros horn is used as an aphrodisiac in TCM. It is, in fact, prescribed for life-threatening fevers and convulsions and has been clinically shown to have fever-reducing properties. [45] Still in 1995 when representatives of the oriental medicine communities in Asia met with conservationists at a symposium in Hong Kong, organized by TRAFFIC. The two groups established a clear willingness to cooperate through dialogue and mutual understanding. This has led to several meetings, including the 1997 First International Symposium on Endangered Species Used in Traditional East Asian Medicine where China was among 136 nations to sign a formal resolution recognizing that the uncontrolled use of wild species in traditional medicine threatens their survival and the continuation of these medical practices. The resolution, drawn up by the UN Convention on International Trade in Endangered Species (CITES), aims to initiate new partnerships in conservation. [46]

[edit] Sustainable Sources of Plant and Animal Drugs

As species face loss of habitat or overharvesting, there have been new issues to deal with in sourcing crude drugs. These include changes to the herb from farming practices, substitution of species or other plants altogether, adulteration and cross-pollination issues. For instance, ginseng which is field farmed may have significant problems with fungus, making contamination with fungicides an issue. This may be remedied with woods grown programs, but they are insufficient to produce enough ginseng to meet demand. The wildcrafted echinacea, black cohosh and American ginseng often rely upon old growth root, often in excess of 50 years of age and it is not clear that younger stock will have the same pharmaceutical effect. [47]Black cohosh may be adulterated with the related Chinese actea species, which is not the same. Ginseng may be replaced by ginseniodes from Jiaogulan which will have a different effect than the full panax root.[48]

The problem may be exacerbated by the growth of pills and capsules as the preferred method of ingesting medication as they are cheaper and more available than traditional, individually tailored prescriptions of raw medicinals but the contents are harder to track. Seahorses are a case in point: Seahorses once had to be of a certain size and quality before they were accepted by practitioners and consumers. But declining availability of the preferred large, pale and smooth seahorses has been offset by the shift towards prepackaged medicines, which make it possible for TCM merchants to sell previously unused juvenile, spiny and dark-coloured animals. Today almost a third of the seahorses sold in China are prepackaged. [49]

The farming of medicinal species has difficulties as well as Rob Parry Jones and Amanda Vincent write:

  • One solution is to farm medicinal animals and plants. Chinese officials have promoted this as a way of guaranteeing supplies as well as protecting endangered species. And there have been some successes—notably with plant species, such as American ginseng—which is used as a general tonic and for chronic coughs. Red deer, too, have for centuries been farmed for their antlers, which are used to treat impotence and general fatigue. But growing your own is not a universal panacea. Some plants grow so slowly that cultivation in not economically viable. Animals such as musk deer may be difficult to farm, and so generate little profit. Seahorses are difficult to feed and plagued by disease in captivity. Other species cannot be cultivated at all. Even when it works, farming usually fails to match the scale of demand. Overall, cultivated TCM plants in China supply less than 20 per cent of the required 1.6 million tonnes per annum. Similarly, China's demand for animal products such as musk and pangolin scales far exceeds supply from captive-bred sources.
  • Farming alone can never resolve conservation concerns, as government authorities and those who use Chinese medicine realise. For a start, consumers often prefer ingredients taken from the wild, believing them to be more potent. This is reflected in the price, with wild oriental ginseng fetching up to 32 times as much as cultivated plants. Then there are welfare concerns. Bear farming in China is particularly controversial. Around 7600 captive bears have their bile "milked" through tubes inserted into their gall bladders. According to Chinese officials, 10 000 wild bears would need to be killed each year to produce as much bile. But many Westerners argue that bear farming is cruel.
  • One alternative to farming involves replacing medical ingredients from threatened species with manufactured chemical compounds. In general, this sort of substitution is difficult to achieve because the active ingredient is often not known. In addition, most TCM uses compounds which may act synergistically—several ingredients may interact to give the required effect. Also, people prefer and trust the wild source. Tauro ursodeoxycholic acid, the active ingredient of bear bile, can be synthesised and is used by some Western doctors to treat gallstones, but many TCM consumers reject it as being inferior to the natural substance from wild animals.[50]

[edit] Need for Pharmacognosy Education

The need for pharmacognosy education is acute as we enter into a post antibiotic age and as traditional ethnobotanical medicines are revived. The growth of TCM and Ayurvedic medicine as well as the increase in western herbalists means that the identification, quality selection and appropriate processing of crude drugs is especially needed. And those disciplines with the pao zhi or rasayana processing offer traditional western pharmacognosy new techniques to alter crude drugs. Simultaneously pharmaceutical companies and supplement companies are looking at crude drugs as sources for effective drugs and nutraceuticals. One factor in the low quality of research on crude drugs is the low number of people who know how to select, process or dose them appropriately due to the closing of US pharmacognosy classes at the university level. Given that such classes are available in Europe, India, China, Korea and Japan, it is likely that information on new drugs will come from other countries than the United States.