Biological Complementary Therapies: A Focus on Botanical Products in Diabetes

doi:10.2337/diaspect.14.4.199

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Biological Complementary Therapies: A Focus on Botanical Products in Diabetes

Laura Shane-McWhorter, PharmD, BCPS, FASCP, CDE, BC-ADM

Abstract

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Abstract
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BOTANICAL PRODUCTS THAT MAY...
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In Brief

Several botanical and biological products claim to lower bloodglucose or decrease complications of diabetes, and some of theseare being used by people with diabetes. Products thought tolower blood glucose include gymnema, fenugreek, bitter melon,ginseng, and nopal. Claims have also been made for aloe, bilberry,and milk thistle, but there is less evidence in support of these.Botanical products thought to decrease diabetes complicationsinclude ${gamma}$ -linolenic acid, ginkgo biloba, and garlic. A vitamin-likesubstance, ${alpha}$ -lipoic acid, has been used to treat neuropathiccomplications.

Introduction

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Abstract
Introduction
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BOTANICAL PRODUCTS THAT MAY...
BIOLOGICAL PRODUCTS THAT MAY...
References
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No one has thoroughly determined how many patients with diabetesuse complementary therapies. A recent survey of diabetes educatorsin the western half of the United States¹ evaluated the mostfrequently recommended and used alternative therapies. Theseincluded physical activity, self-help groups, lifestyle diets,laughter and humor, relaxation therapy, prayer, imagery/visualization,meditation, massage, and music therapy. Although botanical productswere included in the survey, they were not frequently recommendedor used.

Another survey of alternative treatments used by patients withdiabetes² did indicate that herbal treatments are used alongwith other modalities. In some cases, patients used these treatmentsinstead of conventional medications, and severe complications,including increased hospitalizations, ketoacidosis, and acutehyperglycemia, occurred.

Technically, an herbal product is made from the leaves and rootsof a plant, whereas a botanical product includes parts or piecesfrom the whole plant. However, these terms are often used interchangeablyin discussions of complementary therapies.

CONCERNS ABOUT BIOLOGICAL OR BOTANICAL THERAPIES

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As with conventional medicines, the use of complementary therapiesraises concerns about possible side effects³ and drug interactions.⁴Patients using complementary therapies have experienced manyserious side effects; in some cases, they may attribute theseeffects to another medication. Because patients often take medicationsto treat their diabetes, concomitant use of complementary therapiesmay also result in toxicity secondary to exaggerated effectsor sub-therapeutic effects of their conventional medications.

Another concern relates to the variability of products. Botanicalproducts are available in capsules and tablets, as well as inother forms, such as water extracts (also called decoctionsor infusions), tinctures (hydroalcoholic extracts), and glycerites(glycerin-extracted preparations that are alcohol-free). Allvary in potency. In addition, product quality may depend onwhat part of the plant was used, how it was stored, how longit was stored, the processing technique, and how the extractwas prepared.³

Some products are available in a form standardized for pharmacologicalactivity. This should guarantee that there is consistency frombatch to batch and that the active ingredients are stable.⁵However, standardization is not simple because, for many botanicals,the active constituents are unknown. A product may be standardizedfor one or more biologically active compounds, but that compoundmay not be the active ingredient. Pharmacological action maycome from the additive or synergistic effects of several ingredients,none of which separately has the same activity as the wholeplant.⁶ Furthermore, active constituents in extracts or driedbotanicals may vary secondary to geographical or soil differences,differences in exposure to sunlight or rainfall, differencesin the time of harvest, and differences in the methods of drying,storing, and processing. All of these variables may affect pharmacologicalactivity.⁷

Other factors involve potential misidentification, mislabeling,and possible addition of unnatural toxic substances, such asadulteration with heavy metals or steroids and contaminationwith microbes, pesticides, fumigants, and radioactive products.⁷

BOTANICAL PRODUCTS THAT MAY LOWER BLOOD GLUCOSE LEVELS

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Gymnema
A member of the milkweed family, gymnema (Gymnema sylvestra)is a woody plant found in tropical forests of India and Africa.⁸–¹⁰For more than 2,000 years, people have chewed its leaves totreat "madhu meha" ("honey urine").⁹ Used in Ayurvedic medicine,it is thought to destroy a person’s ability to discriminatesweet taste; hence, it is often called "gurmar" or "sugar destroyer."⁸

Chemical constituents of the plant include the gymnemic acids(gymnemosides), saponins, stigmasterol, quercitol, and the aminoacid derivatives betaine, choline, and trimethylamine.⁸ Gymnemahas been used for centuries to treat diabetes.¹⁰

Proposed mechanism of action.
Although the exact mechanism is unknown, there are a varietyof theorized mechanisms. Besides impairing the ability to discriminatesweet taste, gymnema increases the enzyme activity responsiblefor glucose uptake and utilization.¹¹ It may stimulate ß-cellfunction, increase ß-cell number, and/or increaseinsulin release by increasing cell permeability to insulin.⁸,¹²In pancreatectomized animals, it has no hypoglycemic effect,indicating that its effect may require some residual ß-cellfunction.¹³

Side effects and drug interactions.
No side effects have been reported secondary to gymnema use.Hypoglycemia is a potential side effect;¹⁰ drug interactionsmay occur from the additive effects when used concomitantlywith hypoglycemic agents.

Clinical studies.
There are only a few human studies, and these do not reportimportant design details, such as blinding or randomization.

One study¹⁴ was conducted in type 1 diabetic patients on insulin,27 of whom took 200-mg gymnema capsules after breakfast andsupper and 37 of whom took insulin only for a period of 6–30months. After 6–8 months, mean HbA_1c decreased in thegymnema group from a baseline of 12.8 to 9.5% (P < 0.001).After 16–18 months, 22 patients remaining on gymnema hada mean HbA_1c of 9% (P values not given). At the end of 26–30months, six patients remaining on gymnema had a mean HbA_1c of8.2% (P values not given).

Mean fasting blood glucose (FBG) also decreased from a baselineof 232 to 177 mg/dl after 6–8 months 150 mg/dl after 16–18months, and 152 mg/dl after 20–24 months (P values notgiven). The mean insulin dose decreased from a baseline of 60to 45 units/day after 6–8 months and to 30 units/day at26–30 months (P values not given). Patients on placebohad no significant changes from baseline.

Another study¹⁵ was conducted in patients with type 2 diabeteson sulfonylureas; 22 took 400 mg/day of gymnema capsules inaddition to sulfonylurea treatment, and 25 took a placebo andsulfonylureas for a period of 18–20 months. Mean HbA_1cdecreased from a baseline of 11.9 to 8.48% (P < 0.001). MeanFBG decreased from 174 to 124 mg/dl after 18–20 months(P < 0.001). Five patients were able to discontinue sulfonylureas.In this study, lipids also decreased significantly. Patientson placebo had no significant changes in HbA_1c, FBG, or lipids.

Clinical notes.
Because of the possibility of hypoglycemia when gymnema isused with insulin or other diabetes agents, doses for existingdiabetes therapies may have to be adjusted with the additionof gymnema. This product should not be used without medicalsupervision. A typical dose is 400 mg/day standardized to contain24% gymnemic acids.⁸,¹⁰

Fenugreek
Fenugreek (Trigonella foenum-graecum) has been used as a cookingspice and flavoring agent for centuries.⁹ It is a member ofthe Leguminosae family, along with other legumes.⁹,¹⁰ The plantgrows in India, Egypt, and the Middle East.⁹

Fenugreek has also been used as a medicinal agent to treat diabetes,constipation, and hyperlipidemia.¹⁰ It has been used topicallyto treat inflammation, and it has been used postpartum witha substance called jaggery to promote lactation. Because itstaste and odor resemble maple syrup, it has been used to maskthe taste of medicines.⁹

Chemical constituents of the plant include saponins, many ofwhich are glycosides of diosgenin.⁹ The seeds also contain thealkaloids trigonelline, gentianine, and carpaine compounds.Other components of the seeds include several C-glycosides.The seeds contain up to 50% mucilaginous fiber.⁹ Other seedconstituents include 4-hydroxyisoleucine, an amino acid, andfenugreekine.

Proposed mechanism of action.
Fenugreek is thought to delay gastric emptying, slow carbohydrateabsorption, and inhibit glucose transport.¹⁶ It has been shownto increase erythrocyte insulin receptors and improve peripheralglucose utilization, thus showing potential pancreatic as wellas extrapancreatic effects.¹⁷

Various components of the seeds have varying activities. Forexample, the component called fenugreekine, a steroidal sapogeninpeptide ester, may have hypoglycemic properties.¹⁰ Trigonelline,another component, may exert hypoglycemic effects in healthypatients without diabetes,¹⁰ but other studies have shown thatfenugreek has no effect on fasting or postprandial blood glucoselevels in nondiabetic subjects.¹⁸

Side effects and drug interactions.
The main side effects are flatulence and diarrhea, which subsideafter a few days. However, fenugreek also has uterotonic properties.¹⁰Hypersensitivity reactions have also been reported,¹⁰ includingrhinorrhea, wheezing, and fainting after inhalation of the fenugreek-seedpowder. Wheezing and facial angioedema after application ofa topical fenugreek paste for dandruff was reported in a patientwith chronic asthma.¹⁹

Because fenugreek is a member of the Leguminosae family, whichincludes peanuts,⁹ it is theoretically possible for someonewith a peanut allergy to react to fenugreek. However, this reactionhas never been reported.

All of fenugreek’s side effects may occur in infants ofnursing mothers who use this substance.

Because of the coumarin constituents, fenugreek may potentiallyenhance anticoagulant activity of drugs or herbs that have antiplateletactivity.¹⁰ It may inhibit corticosteroid drug activity, interferewith hormone therapy, and potentiate monoamine oxidase (MAO)inhibitor activity. A theoretical interaction is decreased ordelayed absorption of concomitant medications because of thehigh mucilage content. Additionally, there may be additive hypoglycemicactivity when combined with diabetes medications.¹⁰

Clinical studies.
There are few human studies, and most of these are short-term,involve few patients, and do not adequately report study designdetails.

In one study,²⁰ 10 patients with type 1 diabetes on insulinunderwent a 10-day metabolic trial. Patients were blinded, butit was unclear whether the investigators were blinded. Patientswere randomized to either placebo or 50 g fenugreek defattedseed powder twice a day in chapati (unleavened bread). MeanFBG decreased from a baseline of 272 to 196 mg/dl (P < 0.01).Patients also demonstrated a statistically significant declinein serum total cholesterol (P < 0.001), triglycerides, andLDL cholesterol (P < 0.01 vs. placebo for triglycerides andLDL), but no change in HDL cholesterol.

The largest fenugreek study²¹ was a 6-month trial in 60 patientswith inadequately controlled type 2 diabetes. The authors didnot provide information on randomization or blinding. Patientswere administered a 75-g oral glucose tolerance test (OGTT)to determine mean baseline parameters. Fenugreek seed powder,25 g/day, was administered in two equal doses with lunch anddinner for 6 months. Mean FBG decreased from a baseline of 151to 112 mg/dl after 24 weeks. The mean 1-h OGTT baseline was284 mg/dl, compared to 196 mg/dl after 24 weeks. Mean 2-h valuesdecreased from a baseline of 257 to 171 mg/dl after 24 weeks(P < 0.001 vs. baseline for both). Mean HbA_1c decreased froma baseline of 9.6 to 8.4% after 8 weeks (P < 0.001). Although40 patients were on oral diabetes medications, the authors didnot report on whether they were able to decrease their dosesor discontinue their diabetes drugs.

Clinical notes.
Fenugreek has been categorized as "generally recognized assafe" in the United States.¹⁰ Dose recommendations vary dependingon the source. However, all recommended doses are much lowerthan those used in the clinical studies, which ranged from 15g mixed in water to 50 g twice daily. One source recommended1–2 g of the seed or its equivalent three times dailyor 1 cup of the tea, made by steeping 500 mg seed in 150 mlcold water several times a day.¹⁰

Bitter Melon
Bitter melon (Momordica charantia), also known as bitter gourd,bitter apple, bitter cucumber, karolla, and karela, is a vegetablecultivated in tropical areas, including India, Asia, South America,and Africa. It is yellow-orange with a bumpy exterior resemblinga gherkin and is bitter but edible.⁹

Bitter melon has been used to treat diabetes and psoriasis andfor HIV supportive therapy, and it has been studied as a potentialcontraceptive agent.⁹,¹⁰ It has been taken for centuries asa dietary treatment and more recently has been used as an injectableextract for research.²²

Bitter melon contains several chemical constituents, includingthe glycosides mormordin and charantin. Charantin contains mixedsteroids with hypoglycemic activity. Another component is thepeptide polypeptide-P.⁹ Bitter melon also contains the alkaloidmormordicine. Its seeds contain the abortifacients ${alpha}$ -mormorcharinand ß-mormorcharin, as well as the pyrimidine nucleosidevicine.⁹

Proposed mechanism of action.
The fruit and seeds of bitter melon are thought to exert hypoglycemiceffects in normal and diabetic animal models.¹⁰ The specificcomponents thought to contribute to its hypoglycemic activityinclude charantin, polypeptide P, and vicine. Other theoreticalactions include extrapancreatic activity, such as increasedtissue glucose uptake, liver/muscle glycogen synthesis, anddecreased blood glucose synthesis through depression of theenzymes glucose-6-phosphatase, fructose-1, and 6 bisphosphatase,and enhanced glucose oxidation by enzyme G6PDH pathway.⁹

Side effects and drug interactions.
Bitter melon may produce digestive tract discomfort.⁹ Hypoglycemiccoma from a tea containing bitter melon¹⁰ has been reported.Favism (acute hemolytic anemia characterized by headache, fever,abdominal pain, and coma) has also been reported from one ofthe seed constituents of bitter melon, vicine.¹⁰ The red arilsaround bitter melon seeds have produced toxicity; in one child,vomiting, diarrhea, and death occurred.⁹ Bitter melon has abortifacienteffects⁹,¹⁰ and in animals has produced hepatotoxicity.¹⁰

Concomitant use with stimulant laxatives or other agents thatdecrease potassium may increase the risk of potassium depletion.¹⁰If combined with secretagogues, additive hypoglycemia may occur.This was reported when a patient used both bitter melon andchlorpropamide.²³

Clinical studies.
Most studies in humans involve very small numbers, are of veryshort duration, and have been reported with only sketchy informationabout details of study design, including blinding and randomization.Although there are several studies using bitter melon, onlystudies in which glucose values were reported will be discussed.

An early study of 19 patients (11 with type 1 and 8 with type2 diabetes)²² used polypeptide-P zinc chloride, a momordicaextract, prepared in the same manner as bovine insulin. This"plant insulin" was injected subcutaneously in five patientswith type 1 diabetes and six patients with type 2 diabetes.No details of randomization or blinding were provided. FBG wasmeasured at the time of injection, as well as 4, 6, 8, and 12h after injection. The control group, consisting of six patientswith type 1 and two patients with type 2 diabetes, did not receiveany treatment.

In the patients with type 1 diabetes, mean FBG decreased from304 to 169 mg/dl 4 h after injection (P < 0.05), and thiseffect was maintained at 6 and 8 h after injection (FBG 176and 174 mg/dl, respectively, P < 0.05 compared to baseline).At 12 h, FBG had started to increase (208 mg/dl).

In the patients with type 2 diabetes, changes were significantlydifferent between the experimental and control groups at 1 and6 h (P < 0.05). However, there were no significant differencesfrom baseline in the experimental group. In the control groupsof both the type 1 and type 2 diabetes interventions, bloodglucose values were not significantly changed from baseline.

The largest study using bitter melon²⁴ was done in 100 type2 diabetic patients but was conducted for only 2 days usingan aqueous suspension of the vegetable pulp. Day 1 mean FBGwas 152 mg/dl, and after a 75-g OGTT, the mean 2-h postprandialglucose level was 257 mg/dl. On day 2, momordica extract wasgiven, and blood glucose was measured 1 h later. This mean valuewas 131 mg/dl and was significantly different from the FBG of160 mg/dl (P < 0.001). Patients then received a 75-g oralglucose load, and blood glucose was sampled 2 h later. The mean2-h blood glucose was 222 mg/dl. One hour after momordica wasgiven, 86 patients had decreased values and an attenuated bloodglucose response to the 75-g glucose load, in comparison tothe previous day (222 vs. 257 mg/dl, P value not significant).

Clinical notes.
There is insufficient information to recommend a reliable dose.¹⁰Various forms of bitter melon have been used in research, includingpowder, extract, juice, as well as the cooked vegetable. Somesources have stated that 50 ml fresh juice taken daily withfood may be used.¹⁰ Tinctures are becoming available. Medicalsupervision is always necessary when using bitter melon.

Ginseng
A variety of products are called "ginseng." The most commonlyused are three different botanicals: Asian or Korean ginseng(Panax ginseng C.A. Meyer), American ginseng (Panax quinquefoliusL.), or Russian or Siberian ginseng (Eleutherococcus senticosusMaximum). The part used is the root.²⁵

Ginseng has been described as an "adaptogen"—a drug thatmay increase resistance to adverse influences such as infectionand stress.²⁵ Individuals use ginseng in an attempt to enhancephysical performance, psychomotor performance, and cognitivefunction; for immunomodulation; and as treatment for infectionsand diabetes.²⁶ Generally, length of use is up to 3 months,with possible repeated courses.²⁷ In diabetes, only Korean andAmerican ginseng have been studied, so this discussion willbe limited to these two substances.

Ginseng contains a family of steroid-like compounds called ginsenosides.Although there are many subtypes, ginsenosides are tetracyclictriterpenoid saponin glycosides thought to have various hormonaland central nervous system (CNS) effects. Some ginseng compoundsshow contradictory effects; for example, ginsenoside Rg1 hashypertensive and CNS-stimulant effects, whereas ginsenosideRb1 has hypotensive and CNS-depressant effects.⁹,²⁵

Proposed mechanism of action.
In diabetes, the mechanism of beneficial effect is unknown.Animal research has indicated that ginseng may lower blood glucoseby possibly decreasing the rate of carbohydrate absorption intothe portal hepatic circulation²⁸ and possibly increasing glucosetransport and uptake.²⁹ Another potential mechanism is modulationof insulin secretion.³⁰ Some ginseng fractions have increasedserum insulin levels and glucose-stimulated insulin secretionin mice.

Side effects and drug interactions.
The most commonly reported side effects include nervousnessand excitation.⁹ Other effects include headache, hypertension,insomnia,⁹,¹⁰ estrogenic effects including mastalgia,³¹ vaginalbleeding,³² and cerebral arteritis.³³

"Ginseng abuse syndrome" is a controversial adverse effect thatwas reported in 14 of 133 long-term users of high daily doses.³⁴This syndrome consisted of hypertension, nervousness, sleeplessness,skin eruptions, increased libido, and morning diarrhea.

Several drug interactions have been reported. Diuretic resistancecan occur when ginseng is used in conjunction with a diuretic.³⁵Tremors³⁶ and hypomania³⁷ can occur when it is given with phenelzine,an MAO inhibitor. Insomnia, headache, and decreased warfarineffect have also been reported.³⁸ Concomitant use with diabetesagents may cause hypoglycemia. If combined with stimulants,ginseng may potentiate stimulant effects.¹⁰

Clinical studies.
Ginseng has been evaluated in many studies of varying quality.A recent meta-analysis that evaluated its effects on physicalor psychomotor performance, cognitive function, immunomodulation,and other outcomes²⁶ drawing on only randomized, placebo-controlledstudies showed that ginseng has suboptimal efficacy.

Ginseng has only been studied in type 2 diabetes. In a randomized,double-blind study of ginseng in 36 newly diagnosed type 2 diabeticpatients,³⁹ 12 people each were assigned to placebo, 100 mg/day,or 200 mg/day of ginseng tablets for 8 weeks. At the end ofthe study, mean FBG values for the three groups were 149, 139,and 133 mg/dl, respectively. (Results were only statisticallysignificant for the 100-mg/day group, P < 0.05.) Baselinevalues were not reported, and average HbA_1c levels at the endof the study were 6.5, 6.5, and 6.0%, respectively (P < 0.05for 200-mg group).

Another study compared the effects of American ginseng and placeboin patients with and without type 2 diabetes.⁴⁰ Ten patientswithout diabetes and nine patients with type 2 diabetes weregiven a 25-g OGTT, with and without 3 g of ginseng capsules.Patients were given ginseng 40 min before or with the glucosechallenge. Patients were blinded, but the authors did not statewhether the investigators were blinded.

No significant difference in postprandial glucose was reportedwhen ginseng was taken with the glucose challenge in patientswithout diabetes. Taking ginseng 40 min before the OGTT resultedin a significant reduction in postprandial glucose (P <0.05vs. placebo). In patients with diabetes, ginseng given eitherconcomitantly or 40 min before the OGTT significantly loweredpostprandial glucose (P <0.05 vs. placebo).

Clinical notes.
Ginseng products have been found to be adulterated with othersubstances including mandrake root or phenylbutazone,⁹ and inone case even led to positive results on a "doping" test foran athlete.⁴¹

Typical doses are 200–600 mg/ day.¹⁰ These doses are lowerthan in the study using American ginseng capsules but a bithigher than the tablets used in the study of newly diagnosedtype 2 diabetic patients. Besides capsules and tablets, ginsengcomes in a variety of forms ranging from fresh and dried rootsto extracts, solutions, sodas, teas, and cosmetics.⁹ The rootcontains at least 1.5% ginsenosides.²⁷

Some people use ginseng on a continual basis, but others useginseng for a period of 3 weeks to 3 months.¹⁰,²⁷ Evidence forefficacy of ginseng is limited, at best.

Nopal
Nopal (Opuntia streptacantha Le-maire), also known as pricklypear, is a member of the cactus family.⁹ Multiple species areknown as Opuntia, including Opuntia megacantha, Opuntia ficusindica, and Opuntia fuliginosa. Research has focused on Opuntiastreptacantha Lemaire to lower blood glucose.

Nopal stems are used as a food source in Mexico.¹⁰ The leavescontain mucopolysaccharide soluble fibers and phytochemicals.Leaves and stems are also used for other reasons, such as fordiabetes control and treatment of hyperlipidemia.¹⁰

Proposed mechanism of action.
Studies in pancreatectomized animals have shown that the hypoglycemicactivity does not depend on the presence of insulin.⁴² However,the mechanism of action is unknown. The fiber and pectin componentsare thought to have hypoglycemic activity. Because insulin concentrationsdecrease with nopal administration, enhanced insulin sensitivityis another theorized mechanism of action.⁴³

Nopal’s hypoglycemic activity has been reported to reachmaximum effects 3–4 h postprandially and to last up to6 h.¹⁰ The fiber content may affect intestinal uptake of glucose.Animal research indicates that the pectin component may alterhepatic cholesterol metabolism.¹⁰

Side effects and drug interactions.
Reported adverse effects include increased stool volume andfrequency and abdominal fullness.⁴⁴ Dermatitis has also beenreported.¹⁰ In a case report of 8-week coadministration withchlorpropamide, additive effects on blood glucose and insulinlevels were found.⁴³ Additive hypoglycemia with secretagoguesis a theoretical concern, although there have been no reportsof this.

Clinical studies.
Most trials are small and have been published in Spanish, althoughEnglish abstracts are available. Two small trials have beenpublished in English.

One trial involved three groups of patients with type 2 diabetestreated with diet alone or in combination with sulfonylureas.⁴⁵Details of blinding or randomization were not provided. Aftera 12-h fast, 16 patients received 500 g broiled nopal (Group1); 10 people received 400 ml water (Group 2); and 6 peoplereceived 500 g broiled zucchini (Group 3).

In Group 1, mean blood glucose declined from 222 mg/dl fastingto 203, 198, and 183 mg/dl after 60, 120, and 180 min, respectively(P < 0.001 compared to baseline). There was no significantdrop in glucose in Group 2. In Group 3, broiled zucchini causeda drop from a mean baseline of 246 mg/dl fasting to 226, 219,and 206 mg/dl at 60, 120, and 180 min, respectively (P <0.05 vs. baseline for 60 and 120 min; P < 0.01 vs. baselineat 180 min).

Another trial compared 14 patients with type 2 diabetes on sulfonylureas(Group 1) to individuals without diabetes (Group 2).⁴⁶ Detailsof blinding or randomization were not provided. Both groupsreceived 500 g broiled nopal or 400 ml water.

In patients with diabetes, mean decreases in glucose concentrationswere 21, 28, and 41 mg/dl at 60, 120, and 180 min, respectively,after nopal administration (P < 0.005 for 60 and 120 minvs. baseline; P < 0.001 for 180 min vs. baseline). Therewere no significant differences after water administration.Insulin concentrations also declined significantly with nopal.In patients without diabetes, there were no significant differences.

Clinical notes.
Nopal is given with meals in doses of 500 g broiled or freshnopal stems.¹⁰ However, ideal doses and optimal preparationmethods have not been established. There are no known riskswith nopal use, but there have been no well-designed or long-termstudies. Evidence in favor of nopal is limited at this time.

Aloe
Aloe is a desert plant with a cactus-like appearance. It belongsto the family Liliaceae.⁹ There are more than 500 species, butthe most familiar form is aloe vera. It has been used sinceprehistoric times for burns and wound healing.

There are two forms of aloe vera: dried juice from the leafand aloe gel. Latex from pericyclic cells obtained beneath theskin of leaves may be evaporated to form a sticky substanceknown as "drug aloes" or "aloe." This aloe juice contains thecathartic anthraquinone, barbaloin, a glucoside of aloe-emodin,as well as other substances.⁹

Aloe gel is obtained from the inner portion of the leaves. Itdoes not contain anthraquinones but does contain a polysaccharide,glucomannan, that is similar to guar gum.⁹ Aloe gel is usedtopically, but it has also been used orally for diabetes.

Proposed mechanism of action.
Aloe gel taken internally may produce a mild reduction in meanglucose levels, but the mechanism has not been elucidated.

Side effects and drug interactions.
The laxative form of aloe may cause abdominal cramps, pain,and severe diarrhea, with subsequent fluid and electrolyte disturbances.This form may deplete potassium, predisposing people who useit to cardiac abnormalities. It may also potentially interactwith glycosides because of the hypokalemic effects.¹⁰ Additivehypokalemia may also occur when it is coadministered with otherdrugs that deplete potassium, such as diuretics or corticosteroids.¹⁰Additive cathartic effects may occur when combined with otherlaxatives. Topical use has not been reported to produce anyproblems.

Aloe gel taken internally may exacerbate Crohn’s diseaseand ulcerative colitis. It may also produce additive hypoglycemiawhen taken concomitantly with secretagogues.¹⁰

Clinical studies.
A very small, uncontrolled study was conducted in patientswith type 2 diabetes.⁴⁷ Five patients were administered one-halfteaspoonful, twice daily, of dried aloe sap for 4–14 weeks.Details were very sketchy, and information regarding blindingwas not provided. FBG fell from a mean of 273 to 151 mg/dl (P< 0.001). Mean HbA_1c decreased from 10.6 to 8.2% (significancenot reported).

Clinical notes.
Aloe has been used topically and as a cathartic. It has alsobeen used orally to boost the immune system and for treatmentof asthma, ulcers, and diabetes.

Doses are variable and include 50–200 mg/day of aloe leafgel.¹⁰ There is insufficient evidence for the use of aloe indiabetes. Supplementation is not recommended.

Bilberry
Bilberry is a plant closely related to the American blueberry,cranberry, and huckleberry.¹⁰ Two forms of bilberry are used:the dried fruit and the leaf. The dried fruit is used to treatdiarrhea²⁷ and to improve visual acuity and night vision.¹⁰,⁴⁸The leaf is used for diabetes, arthritis, circulatory disorders,⁹,²⁷cataracts,⁴⁹ and varicose veins.¹⁰ In folk medicine, it is usedas a "blood sugar–reducing" drug, and is therefore a commonconstituent in "antidiabetic" teas.⁵⁰

Proposed mechanism of action.
Anthocyanosides are bioflavonoids, chemical constituents inbilberry fruit thought to be responsible for some of its vasculareffects.⁹ Anthocyanosides are thought to decrease vascular permeabilityand redistribute microvascular blood flow.¹⁰ They are similarto some of the agents in grape seed.

The mechanism in diabetes may be related to the high chromiumcontent in bilberry leaf (9 parts per million), but furtherresearch is needed to determine this.⁵⁰

Side effects and drug interactions.
Reported adverse effects have been mostly benign, includingmild digestive distress, skin rashes, and drowsiness.⁵⁰ Thereare no known drug interactions. Because it may affect bloodglucose, additive hypoglycemia may occur with secretagogues.If an alcoholic extract is used, there could be a disulfiramreaction (cramping, diaphoresis, and nausea if alcohol is ingested).¹⁰In animals, prolonged use and very high doses have resultedin toxicity, including initial cachexia and excitation and eventualdeath.²⁷

Clinical studies.
Despite enthusiasm during World War II about using bilberrypreserves for improving night vision in Royal Air Force pilots,⁹bilberry has not had demonstrated efficacy in controlled trials.⁴⁸Although its use has been suggested for lowering of blood glucose,there have been no human trials. In streptozotocin-induced diabeticrats, 4 days of bilberry leaf administration caused plasma glucoselevels to consistently decrease by 26%.⁵¹

Clinical notes.
There is potential benefit but very limited evidence that bilberrymay improve conditions related to blood vessel function, suchas varicose veins, cataracts, and other ocular diseases.

For the fruit, standard doses of the dried ripe berries are20–60 g/day. Decoctions have also been prepared by placing5–10 g mashed berries in cold water, simmering for 10min, then straining. The form used in studies has been standardizedto contain 25% anthocyanosides.¹⁰ A tea is prepared using 1g finely chopped dried leaf in 150 ml boiling water and steepingfor 5–10 min.¹⁰

Milk Thistle
Milk thistle (Silybum marianum) is a member of the aster family(Asteraceae or Compositae), which also includes daisies andthistles.⁵²,⁵³ Milk thistle has been used extensively for varioushepatic disorders, including hepatotoxicity secondary to acuteand chronic viral hepatitis, mushroom poisoning, and alcoholiccirrhosis. It has also been used to attenuate hepatotoxic effectsof certain medications.⁵² Recently, its use has been proposedin diabetes to diminish insulin resistance.⁵⁴

Chemical constituents are found in the fruit, seeds, and leaves.Milk thistle contains silymarin, which is composed of threemain constituents: silybin, silychristine, and silidianin. Silybinis thought to have the most potent biological activity.⁵³

Proposed mechanism of action.
There are several proposed mechanisms that may benefit patientswith hepatic disease or impairment.⁵² One is inhibition of hepatotoxinbinding to hepatocyte membrane receptor sites, resulting inhepatocyte stabilization. Another is reduction of glutathioneoxidation, which may deplete diminished glutathione levels inthe liver and intestines. Milk thistle also has antioxidantactivity to protect against toxic free radicals. Finally, itstimulates protein synthesis, which may lead to enhanced hepatocyteregeneration.

Milk thistle may benefit patients who have insulin resistancesecondary to hepatic damage. One theory is that lipoperoxidationmay affect patients with diabetes, and restoration of normalmalondialdehyde concentrations may improve diabetes.⁵⁴

Side effects and drug interactions.
Reported dose-related (>1,500 mg/ day) adverse effects includeloose stools as a result of increased bile flow and secretion.⁵⁵Patients with allergies to the Asteraceae or Compositae familymay exhibit cross-allergenicity with milk thistle administration.¹⁰No adverse drug interactions have been reported with milk thistle.Beneficial interactions, however, have included reduction ofhepatotoxicity associated with acetaminophen, antipsychotics,halothane, and alcohol.⁵²

Clinical studies.
Several studies have evaluated the impact of milk thistle onhepatic disease. These studies include acute viral hepatitis,mushroom poisoning, drug-induced hepatitis, chronic liver disease,and alcoholic liver disease.⁵³ However, these studies have beenfraught with shortcomings. Many were open-label, involved smallnumbers of patients, used different doses, involved differentseverities of liver disease, lacked control groups, and lackedwell-defined study endpoints.

Milk thistle was evaluated in a 12-month, randomized, open-labeltrial in 60 type 2 diabetic patients with cirrhosis.⁵⁴ All subjectsused insulin. One group of 30 received 600 mg/day of silymarin,and the other group of 30 received a placebo for 12 months.

Mean FBG declined from 190 mg/dl at baseline to 165 mg/dl at12 months (P < 0.01 vs. baseline). HbA_1c declined from 7.9%at baseline to 7.2% at 12 months (P < 0.01 vs. baseline).Mean daily insulin requirement decreased significantly from55 units/day at baseline to 42 units/day at 12 months (P <0.01 vs. baseline). Results were significant in the group ofpatients on silymarin, but not in the control group.

Clinical notes.
Milk thistle may protect against hepatotoxicity by such agentsas acetaminophen, antipsychotics, alcohol, and halothane. Thetypical dose for liver disease is 200 mg three times/day. Milkthistle extract should be standardized to contain 70% silymarin,which then contains 140 mg silymarin. Because phosphatidylcholineenhances oral absorption, preparations containing this ingredientmay be dosed at 100 mg/day.⁵² These doses differ from dosesused in clinical studies, which have ranged from 280 to 800mg/day.

Milk thistle’s potential use for diabetes is very preliminary.

BIOLOGICAL PRODUCTS THAT MAY ADDRESS COMPLICATIONS OF DIABETES

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${gamma}$ Linolenic Acid
${gamma}$ linolenic acid (GLA) is an ${omega}$ -6 fatty acid. Although other sourcesof GLA include black currant and borage oil, the main sourceused in nutritional supplements is evening primrose oil.⁹ GLAhas been used to treat diabetic neuropathy, hyperlipidemia,mastitis, premenstrual syndrome, eczema, rheumatoid arthritis,and multiple sclerosis.⁹

Proposed mechanism of action.
In the body, linoleic acid (LA) is converted to GLA via regulationby the enzyme ${delta}$ -6-desaturase (D6D).⁵⁶ Two metabolites of GLA,dihomogammalinolenic acid (DGLA) and arachidonic acid (AA) areprostaglandin precursors that regulate the balance of plateletaggregation and maintain blood flow in small blood vessels.⁵⁶

In diabetes, conversion of LA to GLA is thought to be impairedsecondary to problems with D6D. Subsequent problems may occur,such as difficulty maintaining nerve membrane structure, nerveblood flow, and nerve conduction.⁵⁷ An exogenous source of GLAbypasses the need for conversion of LA to GLA.

Side effects and drug interactions.
Most adverse effects are mild and include headache and mildgastrointestinal (GI) complaints, such as bloating and loosestools.¹⁰ There are reports of prolonged bleeding time and onecase report of seizures.⁹ Seizures may potentially occur ifGLA is combined with phenothiazines because these drugs maylower the seizure threshold.¹⁰

Clinical studies.
Two main clinical trials have evaluated GLA. One was a 6-monthrandomized, double-blind, placebo-controlled trial evaluatingits effects on peripheral neuropathy in 22 patients with type1 or type 2 diabetes.⁵⁸ Twelve patients received 360 mg/dayGLA, and 10 patients received a placebo. At the end of 6 months,there was improvement in neuropathy symptom scores (P < 0.001)as well as other parameters of neuropathy in the GLA group.There was no significant change in HbA_1c.

Another trial was a year-long, multicenter, randomized, double-blind,placebo-controlled trial involving 111 patients with type 1or type 2 diabetes.⁵⁹ Patients were given 480 mg/day GLA. Theinvestigators reported significant improvement in 13 of 16 parametersof neuropathy. HbA_1c did not improve, but GLA response was betterin those patients whose initial baseline HbA_1c was <10%.

Clinical notes.
GLA derived from EPO may improve problems with nerve membranestructure, impulse conduction, and nerve blood flow. Since HbA_1cdoes not improve, benefit is not secondary to blood glucosecontrol. Doses used to treat neuropathy are 360–480 mg/day.Some experts have stated that it may take several months tosee results with GLA and that, for maximal absorption, it shouldbe taken with food.

Although the initial data seem promising and GLA is relativelybenign, its role in treating neuropathic complications requiresmore investigation.

Ginkgo Biloba
Ginkgo biloba is one of the world’s oldest living treespecies, dating back more than 200 million years.⁹ Extractsfrom dried leaves of younger trees are used in complementarytherapies. Active ingredients include flavonoids (ginkgo-flavoneglycosides) and terpenoids, consisting of ginkgolides and bilobalides.⁶⁰

Ginkgo biloba is one of the most widely used drugs in Germany.It is used for "cerebrovascular insufficiency" and dementia.In diabetes, ginkgo biloba may be of use in ameliorating peripheralcirculatory problems, such as intermittent claudication.⁶¹ Thereis also some evidence that it may benefit sexual dysfunction.⁶²

Proposed mechanism of action.
The flavone glycosides, including quercetin, kaempferol, andisorhamnetin, are thought to have antioxidant activity and inhibitplatelet aggregation. The ginkgolides are thought to improvecirculation and inhibit the platelet-activating factor. Thebilobalides are thought to have neuroprotective properties.⁹,¹⁰,⁶⁰

Side effects and drug interactions.
Patients may experience transient headaches for the first 2–3days of use. GI upset occurs in <1% of patients. Exposureto the fruit pulp may produce cross allergenicity with poisonivy. Eating the seeds may produce loss of consciousness andtonic-clonic seizures.⁹ There have been case reports of subduralhematoma,⁶³ subarachnoid hemorrhage,⁶⁴ and bleeding from themargin of the iris.⁶⁵

The main drug interaction is the potential for additive antiplateletactivity when combined with antiplatelet drugs, such as warfarinor aspirin or with herbs that also have antiplatelet activity,such as ginger, garlic, and feverfew.¹⁰

Clinical studies.
Clinical studies have been done with products containing 24%flavone glycosides and 6% terpene lactones.¹⁰ For intermittentclaudication, different trials have found that ginkgo increasesmaximum walking distance and pain-free walking distance. A recentmeta analysis revealed a significant effect on increased pain-freewalking distance.⁶¹ The weighted mean difference was 34 m.

Ginkgo was found to improve antidepressant-induced sexual dysfunctionin an open-label trial.⁶² Ginkgo has been reported to have abeneficial effect on erectile dysfunction by improving penilearterial blood flow.⁶⁶

Clinical notes.
Doses used range from 120 to 160 mg/day for peripheral vasculardisease.¹⁰ Ginkgo is administered in divided doses, usuallytwo to three times/day. Administration for 6–8 weeks isrequired to determine benefit. The role for ginkgo in diabetescare is still preliminary.

Garlic
Garlic, a member of the lily family,⁹ has been used in cookingfor thousands of years. Garlic contains the sulfur-containingchemical constituent, alliin, which must be converted to allicin(the active form) by the enzyme allinase. When the garlic bulbis chewed or crushed, this reaction occurs.⁹ Ajoene is formedby the acid-catalyzed reaction of two allicin molecules.

Commercial preparations usually contain allin, not allicin.Conversion requires allinase, which is unstable in stomach acids.Dried garlic preparations may be effective only if they areenteric-coated to prevent gastric acid breakdown and permitrelease in the small intestine. Fresh garlic is effective.⁹,¹⁰

Garlic is used to treat hyperlipidemia and hypertension, forcancer prevention, and for other antibacterial activity. Althoughevidence is preliminary, garlic may be useful in diabetes.⁶⁷

Proposed mechanism of action.
Allicin has antibacterial and antioxidant activity. It maypossibly increase blood levels of catylase and glutathione peroxidaseactivity. Ajoene decreases the activity of factors needed forlipid synthesis by reducing the thiol group in coenzyme A andHMG CoA reductase and also by oxidizing NADPH. Ajoene has antiplateletactivity and interferes with thromboxane synthesis and decreasesplatelet aggregation.⁹

Researchers have noted that garlic use may be associated withincreased serum insulin and improved liver glycogen storage.⁶⁷A constituent of garlic, allylpropyl disulfide, may reduce bloodglucose and increase insulin.¹⁰

Side effects and drug interactions.
Side effects include breath odor, mouth and GI burning or irritation,heartburn, flatulence, and rare topical reactions. There arecases of spontaneous spinal epidural hematoma⁶⁸ and excessivebleeding.⁶⁹

Potential drug interactions may occur if a patient is takingantiplatelet agents, such as warfarin or aspirin.¹⁰ Additiveanticoagulant effects may occur when combined with herbal productsthat have antiplatelet activity, such as ginkgo, ginger, andfeverfew.

Clinical studies.
A recently published meta-analysis included trials from previouslypublished meta analyses and newer trials.⁷⁰ The results revealedthat garlic reduced total cholesterol more than did placebo(P < 0.01). The result was more modest than in previous studies.Mean total cholesterol decrease was 15.7 mg/dl.

In mild hypertension, a 1994 meta-analysis indicated that meansystolic blood pressure was 7.7 mmHg lower than with placebo,and diastolic blood pressure was 5 mmHg lower.⁷¹ However, onlythree of the trials were conducted in hypertensive subjects.Seven of the eight trials in the meta-analysis compared garlicto placebo. Three of the trials found a significant reductionin systolic blood pressure, and four trials showed a significantreduction in diastolic blood pressure.

Clinical notes.
Although lipid lowering has been shown with garlic use, theresults are less impressive than with traditional agents. Althoughtotal cholesterol is lowered, there is less evidence for benefitto LDL, triglycerides, or HDL cholesterol. Garlic may not providethe aggressive lipid lowering that is recommended for patientswith diabetes. Likewise, patients with diabetes need more aggressiveantihypertensive effects than garlic may provide.

The dose to treat hyperlipidemia and hypertension is 600–900mg/day in divided doses.¹⁰ For fresh garlic, the dose is oneclove (4 g) taken once/day.¹⁰ Dried garlic powder preparationsstandardized to 1.3% allicin content have been used in studies.These preparations should be enteric-coated to prevent breakdownby stomach acids.¹⁰

${alpha}$ -Lipoic Acid
${alpha}$ -lipoic acid (ALA), also known as thioctic acid, is a disulfidecompound synthesized in the liver.⁷² It functions as a cofactorin enzyme complexes such as pyruvate dehydrogenase, where itassists in the conversion of pyruvic acid to acetyl-coenzymeA in the oxidative metabolism of glucose.⁷²

In vitro and animal research indicates that elevated glucoselevels may increase free radical-mediated oxidation, which inturn is strongly implicated in the pathogenesis of diabetes-relatedneuropathy.⁷³ Because ALA may decrease oxidative stress (inpart caused by increased blood glucose levels), it may helpminimize diabetes complications. ALA has been used in Germanyfor decades to treat peripheral neuropathy.

Proposed mechanism of action.
ALA is readily converted to its reduced form, dihydrolipoicacid (DHLA).¹⁸ ALA and DHLA are both potent antioxidants andhave three distinct actions: 1) free radical scavenging activity;2) regeneration of endogenous antioxidants such as vitamin C,vitamin E, and glutathione; and 3) metal chelating activity.⁷³

Side effects and drug interactions.
Serious side effects have not been reported. ALA may produceGI side effects and possible allergic skin conditions.⁷⁴ ALAmay potentially result in additive hypoglycemia when combinedwith hypoglycemic agents.⁷⁵

Clinical studies.
ALA was studied in the ALADIN (Alpha Lipoic Acid in DiabeticNeuropathy) trials. The first trial⁷⁴ was a randomized, double-blind,placebo-controlled trial in 260 type 2 diabetic patients withsymptomatic peripheral neuropathy. For 3 weeks, patients wereadministered placebo or intravenous (IV) ALA (100, 600, or 1,200mg) daily. Total symptom scores of neuropathy decreased significantlyfor all three ALA doses versus placebo (P < 0.05). Burning,paresthesia, and numbness decreased significantly in patientson 600 and 1,200 mg/day versus placebo (P < 0.05). Pain scoresdecreased significantly only in the 600 mg/day versus placebogroup (P < 0.05). However, both the 600- and 1,200-mg dosesdecreased Hamburg Pain Adjective List scores (P < 0.01 vs.placebo). The Neuropathy Disability Score decreased but wassignificant only for the 1,200-mg group versus the placebo group(P = 0.030).

The second ALADIN trial (ALADIN II) was a randomized, double-blind,placebo-controlled 2-year trial in 65 patients with type 1 ortype 2 diabetes and polyneuropathy symptoms.⁷⁶ Following administrationof placebo, 600 mg, or 1,200 mg/day IV for 5 days, patientswere then randomized to oral placebo, 600 mg, or 1,200 mg/dayfor 2 years. Mean sural nerve conduction velocity changes weresignificant only for 600 and 1,200 mg versus placebo (P <0.05). Sural sensory nerve action potential scores decreasedsignificantly only for 600 mg versus placebo (P < 0.05).Tibial motor nerve conduction velocity changes were significantonly for 1,200 mg versus placebo (P < 0.05).

ALADIN III⁷⁷ was a randomized, double-blind, placebo-controlledtrial in 503 patients with type 2 diabetes. One group was given600 mg IV/day of ALA for 3 weeks, and then subjects were randomizedto oral ALA, 600 mg three times daily, or placebo for 6 months.The other group was given daily IV placebo for 3 weeks followedby oral placebo for 6 months. Mean baseline neuropathic impairmentscores decreased after 19 days in the two ALA groups versusplacebo (P = 0.02). After 7 months, however, differences werenot significant between the groups. The authors suggested thatlack of effect in this trial, as opposed to the earlier trials,might have been due to intercenter variability in symptom scoring.

Clinical notes.
There is no information on the prevention of neuropathy withALA. The clinical significance of the reported improvement indifferent parameters of neuropathy in the ALADIN studies⁷⁴,⁷⁶,⁷⁷may be enhanced quality of life for patients who experienceneuropathy.

Long-term trials are necessary to determine whether ALA slowsprogression of neuropathy or merely improves neuropathy symptoms.The Neurolog-ical Assessment of Thioctic Acid in NeuropathyStudy (NATHAN) is an ongoing multicenter trial in Europe andNorth America to evaluate the ability of oral ALA to slow progressionof neuropathy in diabetes.⁷⁸

Typical oral doses of ALA are 600–800 mg/day.¹⁰ Althoughintravenously administered ALA has been shown to be effectivewhen used in short-term clinical trials,⁷⁴ it is not a practicalform for supplementation.

The American Diabetes Association does not sanction use of ALA.

Conclusions
Although biological complementary therapies have been studiedin human clinical trials, there are many problems with studydesign, study endpoints, numbers of patients, and study duration.There is insufficient evidence to recommend generalized usefor patients with diabetes. Furthermore, these products havemany side effects and may potentially interact with traditionaldiabetes medications.

Footnotes

Laura Shane-McWhorter, PharmD, BCPS, FASCP, CDE, BC-ADM, isan associate clinical professor in the Department of PharmacyPractice at the University of Utah in Salt Lake City.

References

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Abstract
Introduction
CONCERNS ABOUT BIOLOGICAL OR...
BOTANICAL PRODUCTS THAT MAY...
BIOLOGICAL PRODUCTS THAT MAY...
References
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Diabetes Educ

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⁷⁷ Ziegler D, Hanefeld M, Ruhnau K-J, Hasche H, Lobisch M, Schutte K, Kerum G, Malessa R, The ALADIN III Study Group: Treatment of symptomatic diabetic polyneuropathy with the antioxidant ${alpha}$ -lipoic acid: a 7-month multicenter randomized controlled trial (ALADIN III Study). Diabetes Care 22:1296–1301, 1999[Abstract]

⁷⁸ Ziegler D, Reljanovic M, Mehnert H, Greis FA: Alpha-lipoic acid in the treatment of diabetic polyneuropathy in Germany: current evidence from clinical trials. Exp Clin Endocrinol Diabetes 107:421–430, 1999[Medline]

	Suggested Readings/Websites

Top Abstract Introduction CONCERNS ABOUT BIOLOGICAL OR... BOTANICAL PRODUCTS THAT MAY... BIOLOGICAL PRODUCTS THAT MAY... References Suggested Readings/Websites

Tyler VE: Herbs of Choice: The Therapeutic Use of Phytomedicinals.Binghamton, N.Y., Pharmacaeutical Products Press, 1994

Gruenwald S, Brenoller T, Jaenicke L (Eds.): PDR for HerbalMedicine. Montvale, N.J., Medical Economics, 1999

Leung AY, Foster S: Encyclopedia of Common Natural IngredientsUsed in Foods, Drugs, and Cosmetics. 2nd ed. New York, Wiley,1995

Newall CA, Anderson LA, Phillipson JD: Herbal Medicines: AGuide for Health-Care Professionals. London, PharmaceuticalPress, 1996

Bisset NG (Ed.): A Handbook for Practice on a Scientific Basis.Boca Raton, Fla., Medpharm Scientific Publications CRC, 1996