Cynara (Cynarae folium)

Table of contents

Table of contents ................................................................................................................... 2

1. Introduction....................................................................................................................... 4

1.1. Description of the herbal substance(s), herbal preparation(s) or combinations thereof . 4

1.2. Information about products on the market in the Member States .............................. 6

1.3. Search and assessment methodology.................................................................. 1 5

2. Historical data on medicinal use ...................................................................................... 15

2.1. Information on period of medicinal use in the Community ...................................... 1 5

2.2. Information on traditional/current indications and specified substances/preparations .1 6

2.2.1.1. Type of tradition, where relevant .................................................................. 1 6

Evidence regarding the indication/traditional use........................................................ 1 6

2.2.1.2.................................................................................................................. 1 6

2.3. Specified strength/posology/route of administration/duration of use for relevant

preparations and indications..................................................................................... 1 7

3. Non-Clinical Data ............................................................................................................. 18

3.1. Overview of available pharmacological data regarding the herbal substance(s), herbal

preparation(s) and relevant constituents thereof ......................................................... 1 8

3.1.1. Conclusions on traditional use ......................................................................... 2 3

3.2. Overview of available pharmacokinetic data regarding the herbal substance(s), herbal

preparation(s) and relevant constituents thereof ......................................................... 2 4

3.2.1. Assessor’s overall conclusions on pharmacokinetics ............................................ 2 6

3.3. Overview of available toxicological data regarding the herbal substance(s)/herbal

preparation(s) and constituents thereof ..................................................................... 2 6

3.3.1. Assessor’s overall conclusions on toxicology ...................................................... 2 8

3.4. Overall conclusions on non-clinical data............................................................... 2 9

4. Clinical Data ..................................................................................................................... 29

4.1. Clinical Pharmacology ....................................................................................... 2 9

4.1.1. Overview of pharmacodynamic data regarding the herbal substance(s)/preparation(s)

including data on relevant constituents ...................................................................... 2 9

4.1.1.1. Assessor’s overall conclusions on pharmacodynamics....................................... 2 9

4.1.2. Overview of pharmacokinetic data regarding the herbal substance(s)/preparation(s)

including data on relevant constituents ...................................................................... 2 9

4.2. Clinical Efficacy ................................................................................................ 2 9

4.2.1. Dose response studies.................................................................................... 2 9

4.2.2. Clinical studies (case studies and clinical trials).................................................. 2 9

4.2.3. Clinical studies in special populations (e.g. elderly and children)........................... 4 0

4.3. Overall conclusions on clinical pharmacology and efficacy ...................................... 4 0

5. Clinical Safety/Pharmacovigilance................................................................................... 40

5.1. Overview of toxicological/safety data from clinical trials in humans.......................... 4 0

5.2. Patient exposure .............................................................................................. 4 0

5.3. Adverse events and serious adverse events and deaths ......................................... 4 0

5.4. Laboratory findings .......................................................................................... 4 2

5.5. Safety in special populations and situations ......................................................... 4 2

5.6. Intrinsic (including elderly and children) /extrinsic factors ...................................... 4 2

5.7. Drug interactions ............................................................................................. 4 2

5.8. Use in pregnancy and lactation........................................................................... 4 2

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5.9. Overdose ........................................................................................................ 4 2

5.10. Drug abuse.................................................................................................... 4 3

5.11. Withdrawal and rebound.................................................................................. 4 3

5.12. Effects on ability to drive or operate machinery or impairment of mental ability....... 4 3

5.13. Overall conclusions on clinical safety ................................................................. 4 3

6. Overall conclusions .......................................................................................................... 43

Annex .................................................................................................................................. 44

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1. Introduction

Latin Name : Cynara scolymus L., Asteraceae family ( Compositae )

In a recent botanical taxonomic revision of the genus Cynara [ESCOP 2009] it has been accepted that

the leafy cardoon ( Cynara cardunculus L.) and the globe artichoke ( Cynara scolymus L.) are two

cultivars of a new subspecies Cynara cardunculus L. subsp. flavescens Wiklund [ESCOP 2009].

Nevertheless, the botanical name, Cynara scolymus has been kept for the monograph, in accordance

with the European Pharmacopoeia ( Cynara scolymus) not distinguishing morphologically the two types

of the plant cultivars (globe artichoke and leafy cardoon).

Pharmacopoeial Name : Cynarae folium

Other Names : The name has originated from ardi shauki ( أرضي شوكي ), which is Arabic for ground-

thorn, through the Italian : articiocco, English : globe artichoke, French : artichaut, German :

Artischocke, Hungarian : articsóka level, Latvian name : artišoka lapas, Greek : Κινάρα, Swedish :

kronärtskocka, Dutch : artisjok, Portuguese : alcachofra, Croatian : artičoka, Turkish : enginar,

Russian : артишок, Spanish : alcachofa, alcachofera.

1.1. Description of the herbal substance(s), herbal preparation(s) or

combinations thereof

 Herbal substance(s)

Pharmacopoeial grade artichoke leaf consists of the dried basal leaves of Cynara scolymus L.

containing a minimum 0.8 % of chlorogenic acid (C 16 H 18 O 9 ; M r 354.3) (dried drug). Botanical

identification is carried out by thin-layer chromatography (TLC), macroscopic and microscopic

evaluations, and organoleptic tests. The dried leaf must contain not less than 25% water-soluble

extractive [BHP 1996; Pharm. Franc. 1987; Blumenthal et al. 2000; Bruneton 1999].

Globe Artichoke ( Cynara scolymus L.) is a perennial thistle originating in southern Europe around the

Mediterranean (northern Africa and the Canary Islands) [Leung & Foster, 1996]. It grows to 1.5-2 m

tall, with arching, deeply lobed, silvery glaucous-green leaves 50–80 cm long. The flowers develop in a

large head from an edible bud about 8–15 cm diameter with numerous triangular scales; the individual

florets are purple. The edible portion of the buds consists primarily of the fleshy lower portions of the

involucral bracts and the base, known as the "heart"; the mass of inedible immature florets in the

center of the bud are called the "choke."

Its cultivation in Europe dates back to ancient Greece and Rome [Grieve 1971]. It is cultivated in North

Africa as well as in other subtropical regions [Iwu 1993]. The material of commerce comes as whole or

cut dried leaves obtained mainly from southern Europe and northern Africa [BHP 1996].

Artichoke leaf contains up to 2% phenolic acids, mainly 3-caffeoylquinic acid (chlorogenic acid), plus

1.3-di-O-caffeoylquinic acid (cynarin), and caffeic acid; 0.4% bitter sesquiterpene lactones of which

47-83% is cynaropicrin; 0.11.0% flavonoids including the glycosides luteolin-7-β-rutinoside

(scolymoside), luteolin-7-β-D-glucoside and luteolin-4-β-D-glucoside; phytosterols (taraxasterol);

sugars; inulin; enzymes; and a volatile oil consisting mainly of the sesquiterpenes β-selinene and

caryophyllene [Hänsel et al. 1992, 1994; Leung & Foster 1996; Meyer-Buchtela 1999; Newall et al.

1996].

Analytically, artichoke's main plant chemicals are caffeic acid, caffeoylquinic acids, chlorogenic acid,

cyanidol glucosides, cynaragenin, cynarapicrin, cynaratriol, cynarin, cynarolide, decanal, eugenol,

ferulic acid, flavonoids, folacin, glyceric acid, glycolic acid, heteroside-B, inulin, isoamerboin, lauric

acid, linoleic acid, linolenic acid, luteolin glucosides, myristic acid, neochlorogenic acid, oleic acid,

palmitic acid, phenylacetaldehyde, pseudotaraxasterol, scolymoside, silymarin, sitosterol, stearic acid,

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stigmasterol, and taraxasterol [Dorne 1995; Maros et al. 1966, 1968; Montini et al. 1975;

Samochowiec et al. 1971].

Cynarin

Chlorogenic acid

Scolymoside

Cynaroside

Cynaropicrin ( 1 ) and grosheimin ( 2 )

Caffeic acid

The artichoke is popular for its pleasant bitter taste, which is attributed mostly to a plant chemical

called cynarin found in the green parts of the plant. Cynarin is considered one of artichoke's main

biologically active chemicals. It occurs in the highest concentration in the leaves of the plant, which is

why leaf extracts are most commonly employed in herbal medicine. Other documented "active"

chemicals include flavonoids, sesquiterpene lactones, polyphenols and caffeoylquinic acids.

 Herbal preparation(s)

Concerning the information provided by the Member States the intended use of the following

preparations is:

TU

- Comminuted or powdered leaves for herbal tea (Belgium, Germany, Spain and Poland)

- Powdered leaves (France)

- Dry extract (DER 3.8-7.5:1), extraction solvent water (Poland, Germany)

- Dry extract fresh leaves (DER 25-35:1), extraction solvent water (Poland)

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- Soft extract fresh leaves (DER 15-30:1), extraction solvent water (France)

 Combinations of herbal substance(s) and/or herbal preparation(s) including a description of

vitamin(s) and/or mineral(s) as ingredients of traditional combination herbal medicinal products

assessed, where applicable.

For combination products there is the following information in European market:

- Spain: Combinations products: Artichoke extract with laxative products or with Boldo extract

- Sweden: There is one combination product, a so called natural remedy, containing Cynara scolymus

together with Gentiana lutea and Curcuma longa

- Germany: Seven authorized combination products with Matricariae flos, Taraxaci herba cum

radix, Menthae piperitae folium, Millefolii herba, Foeniculi amari fructus, Helichrysi flos

Therefore the combinations of artichoke are not proposed for the monograph/list.

 Vitamins

Not applicable.

 Minerals

Not applicable.

1.2. Information about products on the market in the Member States

Regulatory status overview

Member State Regulatory Status

Comments

Austria

MA

TRAD

Other TRAD

Other Specify:

Belgium

MA

TRAD

Other TRAD

Other Specify:

Bulgaria

MA

TRAD

Other TRAD

Other Specify:

Cyprus

MA

TRAD

Other TRAD

Other Specify: Not known

Czech Republic

MA

TRAD

Other TRAD

Other Specify: Only combinations

Denmark

MA

TRAD

Other TRAD

Other Specify: Not known

Estonia

MA

TRAD

Other TRAD

Other Specify: Not known

Finland

MA

TRAD

Other TRAD

Other Specify: No marketed product

France

MA

TRAD

Other TRAD

Other Specify:

Germany

MA

TRAD

Other TRAD

Other Specify: Also in combinations

Greece

MA

TRAD

Other TRAD

Other Specify: No marketed product

Hungary

MA

TRAD

Other TRAD

Other Specify:

Iceland

MA

TRAD

Other TRAD

Other Specify: No marketed product

Ireland

MA

TRAD

Other TRAD

Other Specify: Not known

Italy

MA

TRAD

Other TRAD

Other Specify: Not known

Latvia

MA

TRAD

Other TRAD

Other Specify: No marketed product

Liechtenstein

MA

TRAD

Other TRAD

Other Specify: Not known

Lithuania

MA

TRAD

Other TRAD

Other Specify: No marketed product

Luxemburg

MA

TRAD

Other TRAD

Other Specify: Not known

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Member State Regulatory Status

Comments

Malta

MA

TRAD

Other TRAD

Other Specify: Not known

The Netherlands

MA

TRAD

Other TRAD

Other Specify: Not known

Norway

MA

TRAD

Other TRAD

Other Specify: Not known

Poland

MA

TRAD

Other TRAD

Other Specify:

Portugal

MA

TRAD

Other TRAD

Other Specify: No marketed product

Romania

MA

TRAD

Other TRAD

Other Specify: Not known

Slovak Republic

MA

TRAD

Other TRAD

Other Specify:

Slovenia

MA

TRAD

Other TRAD

Other Specify: Not known

Spain

MA

TRAD

Other TRAD

Other Specify: Also combinations

Sweden

MA

TRAD

Other TRAD

Other Specify: Only in combination

United Kingdom

MA

TRAD

Other TRAD

Other Specify: Not known

MA: Marketing Authorisation

TRAD: Traditional Use Registration

Other TRAD: Other national Traditional systems of registration

Other: If known, it should be specified or otherwise add ’Not Known’

This regulatory overview is not legally binding and does not necessarily reflect the legal status of the

products in the MSs concerned.

Member

State

Regulatory Status

Member state products, indications

Austria

TU

Preparations:

1) dry extract, DER 4-6:1, solvent water 350 mg

2) dry extract (no further details) 300 mg

3) dry extract, DER 4-6:1, solvent water 320 mg

4) dry extract, DER 4-6:1, solvent water 600 mg

5) dry extract, solvent water (no further details) 400 mg

Since:

1) 2000; 2) 1999; 3) 1998; 4) 2000; 5) 1999

Pharmaceutical form:

1), 2), 4), 5) coated tablet

3) capsules

Posology for oral use in adults:

1) 3 x daily 30-1-2 coated tablets

2), 4), 5) 3 x daily 30-1 coated tablet

3) 3 x daily 30-1 -2 capsules

Indications :

1), 2), 4), 5) Digestive complaints

3) Dyspepsia

Risks:

No adverse effects known.

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Member

State

Regulatory Status

There are also products in the market as a combination with Menthae pip. folium,

Taraxaci radix, Curcumae rhizoma and Silybi marianae fructus. Or Silybi marianae

fructus, Taraxaci radix

WEU

Preparations:

1) dry extract, DER 25-35:1, solvent water 300 mg

2) dry extract, DER 25-35:1, solvent water 450 mg

3) dry expressed juice from 12000 mg fresh leaves 400 mg

4) dry extract, DER 4-6:1, standardized to >1.25% caffeoylquinic acids

5) soft extract, DER 4-6:1, standardized to >0.5% caffeoylquinic acids 5 ml contain

200 mg

6) dry extract, DER 3.8-5.5:1, solvent water 400 mg

7) dry expressed juice from 12000 mg fresh leaves 400 mg

Since:

1), 2), 6), 7) 2002; 3) 2004; 4), 5) 1992

Pharmaceutical form:

1), 2), 3), 4), 7) coated tablet

5) solution for oral intake

6) capsules

Posology for oral use in adults:

1) oral, 3 x daily 300 mg

2) oral, 3 x daily 450 mg

3) oral, 1 x daily 1-2 coated tablets

4) oral, 3 x daily 1-2 coated tablets

5) oral, 3 x daily 5-10 ml

6) oral, 3 x daily 1 capsule

7) oral, 3 x daily 1-2 coated tablets

Indications:

1), 2), 6) Digestive complaints, regulation and improvement of lipid metabolism

3) Improvement of digestion

4), 5), 7) dyspeptic disorders, post-treatment after hepatitis, chronic hepatopathies,

subacute or chronic diseases of the biliary tract, after-care of cholecystectomy

Risks :

4), 5), 7) None known

1), 2) Rarely mild laxative effects

6) hypersensitivity reactions

Belgium

WEU

Preparations:

1) powdered leaves

2), 3) dry “purified” extract, equiv 1.875% chlorogenic acid (no further details)

4) dry extract (no further details)

Since:

1) 2006; 2), 3) 2000; 4) 1999

Pharmaceutical form :

1) capsules, hard; 200 mg powder per capsule

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Member

State

Regulatory Status

2) coated tabs; 200 mg extract/tab

3) oral solution; 240 ml extract/ml

4) coated tabs; 200 mg extract/tab

Posology for oral use in adults and adolescents:

1) 2 times 3 to 4 caps daily

2) 2 times 3 tablets daily

3) 2-4 times 2.5 ml daily

4) 2-4 times 3 tabs daily

Indications:

1) enhances biliar excretion, after exclusion of serious pathologies

2) cholagogue, after exclusion of serious pathologies. Minor increase in renal water

excretion.

Marketing Authorisations for the teas date from 1962

50-200 mg Cynara herb per g tea

Combinations products :

Artichoke leaf extract with Boldo folium, herba hepaticae, Centaurii herba, Cardui

benedicti herba, Fraxini folium

Bulgaria

WEU

Preparations :

1) dry extract, DER 4-6:1, tablets

2) soft extract (DER 4-6:1), liquid

Since:

1) 2001; 2) 2006

Pharmaceutical form:

1) coated tablet

5) solution for oral intake

Posology for oral use in adults (children over 12 years):

1) adults 1-2 tablets 3 times daily

2) adults 1-2 tea spoon 3 times daily

Indications:

1), 2) dyspeptic symptoms and meteorism following fatty meals and meals which are

difficult to digest, follow-up treatment by liver and biliary disfunction

Risks :

1), 2) hypersibility, diarrhoea, flatulence, nausea

Cyprus

Not known.

Czech

Republic

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

Denmark

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

Estonia

Not known.

Finland

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

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Member

State

Regulatory Status

France

TU

Preparations:

1), 2) powdered dried leaves

3) aqueous extract

4) dry aqueous extract

5) dry aqueous extract , DER 2-3.5:1

6), 7) dry aqueous extract; DER 2.5-3.5:1 dried leaf or DER 15-30:1 fresh leaf

8) soft aqueous extract

Since:

1) 1988; 2) 1994; 3) 1988; 4) 1990; 5) 1986; 6-7) 1976; 8) 1966

Pharmaceutical form:

1), 4), 5) Hard capsules

6) coated tablet

2), 3), 7), 8) solution for oral intake

Posology for oral use in adults:

1) hard capsule 3 times daily 200 mg of powdered drug/capsule

2) 1 ampoule (5 ml) 2 times daily (0.5 g of powdered drug/ ampoule)

3) 3 to 6 ampoules (15 ml) daily (0.3 g of extract/ampoule)

4) 1 to 2 hard capsules 2 times daily (192.5 mg of extract/capsule)

5) 1 hard capsule 2 times daily (200 mg of extract/capsule)

6) 1 to 2 coated tablets 3 times daily (200 mg of extract/tablet)

7) 1 coffee spoon 3 times daily (20 g of extract/100 ml)

8) 1 ampoule (10 ml) 3 times daily (2 g of extract/ampoule)

Indications:

1-5) Traditionally used to promote urinary and digestive elimination functions.

Traditionally used as a choleretic and cholagogue

6-8) Traditionally used to promote urinary and digestive elimination functions

Risks:

None reported

Germany

TU

Preparations:

dry extract (DER 5.8-7.5:1), extraction solvent water

Since:

1978

Pharmaceutical form:

coated tablet

Posology for oral use in adults:

1 coated tablet contains 300 mg dry extract

1-2 times daily 1 coated tablet

Indications :

traditional used to promote the digestion

Risks:

ADVERSE REACTIONS : slight diarrhoea with abdominal spasm, epigastric complaints like

nausea and heartburn, reactions of hypersensitivity like exanthema.

Interactions: concomitant use may decrease the efficacy of anticoagulants (coumarin

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Member

State

Regulatory Status

derivates like Phenprocoumon, Warfarin). Tight monitoring is necessary.

Seven (7) authorized combination products with Matricariae flos, Taraxaci herba

cum radix, Menthae piperitae folium, Millefolii herba, Foeniculi amari fructus,

Helichrysi flos

Moreover the following authorized products for TU :

Cynariae flos : 3 expressed juices from fresh artichoke flower buds (1:0.6-0.9) on

the market since 1978, expr. juice, for TU

Cynariae herba: 1 fluid extract from artichoke herb (1:2.4-5.2), extraction solvent:

ethanol on the market since 1978, liquid, for TU

WEU

Preparations:

1), 3-11), 14-16), 18-19), 21-23), 27-34), 36), 38), 43) dry extract (DER 4-6:1),

extraction solvent water

2, 26) dried expressed juice from fresh artichoke leaves (DER 25-35:1), extraction

solvent water

12, 39-40) dry extract from fresh artichoke leaves (DER 25-35:1), extraction solvent

water

13, 41, 42) dry extract (DER 5.8-7.5:1), extraction solvent water

17) fluid extract (DER 1:0.9-1.1), extraction solvent ethanol 35% (v/v)

20) dry extract (DER 3.8-5.5:1), extraction solvent water

25, 35) dry extract from fresh artichoke leaves (DER 15-30:1), extraction solvent

water

37) soft extract (DER 2.5-3.5:1), extraction solvent ethanol 20% (v/v)

Since:

1, 14, 16) 2000; 2) 2005; 3, 6, 9, 15, 18, 21-24) 1998; 4, 7, 10, 12, 13, 17, 19, 20,

35-42) 1978; 5, 11) 1999; 8, 28-31, 43) 2003; 25, 27, 32) 2002; 26) 2006; 33, 34)

2004

Pharmaceutical form:

1, 3, 5, 6, 9-11, 14-16, 18, 20-24, 38) hard capsule

2, 4, 8, 12, 13, 26-36, 39-43) coated tablet

7, 25) film tablet

17, 19, 37) oral liquid

Posology for oral use:

Adults and adolescents over 12 years

1, 3, 6, 9, 14-16, 18, 21-24) 1 hard capsule contains 400 mg dry extract ; 1x3 times

daily

2, 26) 1 coated tablet contains 400 mg dried expressed juice ; 2 times daily 1 coated

tablet

4) 1 coated tablet contains 232 mg dry extract ; 5 coated tablets per day in the

following order: 2 coated tablets in the morning, 2 coated tablets at noon and 1

coated tablet in the evening

5) 1 hard capsule contains 400 mg dry extract ; 2-3 times daily 1 hard capsule

7) 1 film tablet contains 200 mg dry extract ; 3 times daily 2 film tablets

8, 27-34, 43) 1 coated tablet contains 600 mg dry extract; 2 times daily 1 coated

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Member

State

Regulatory Status

tablet

10) 1 hard capsule contains 200 mg dry extract ; 3 times daily 2 hard capsules

11) 1 hard capsule contains 400 mg dry extract ; 3 times daily 1 hard capsule

12) 1 coated tablet contains 450 mg dried expressed juice ; 1-2 coated tablets

13, 41, 42) 1 coated tablet contains 300 mg dry extract

17) 1 ml liquid contains 1 ml fluid extract ; 4 times daily 45 drops fluid extract

19) 10 ml liquid contains 400 mg dry extract ; 3 times daily 2 teaspoons (=10 ml) of

liquid

20) 1 hard capsule contains 200 mg dry extract ; 3 times daily 1 hard capsule, if

necessary 4 times daily

25) 1 film tablet contains 320 mg dry extract ; 4 times daily 1 film tablet

35) 1 coated tablet contains 160 mg dry extract; 4 times daily 2 coated tablets

36) 1 coated tablet contains 220 mg dry extract; 3 times daily 2 coated tablets

37) 100 g (=94.8 ml) liquid contains 33.333 mg soft extract ; 3 times daily 40 drops

38) 1 hard capsule contains 320 mg dry extract ; 2 times daily 2 hard capsules

39) 1 coated tablet contains 300 mg dry extract; Adults: 3-4 times daily 2 coated

tablets

40) 1 coated tablet contains 150 mg dry extract; Adults: 3-4 times daily 2-4 coated

tablets

Indications :

1, 3, 6, 7, 9, 11-16, 18-25, 39-42) dyspeptic complaints, particularly based on

functional affections of the biliary tract

2, 4, 5, 8, 17, 26-38, 43) dyspeptic complaints, particularly based on functional

affections of the biliary tract

10) dyspeptic complaints based on insufficient bile secretion like sense of fullness,

flatulence, minor gastrointestinal spasms

Risks:

1–43) ADVERSE REACTIONS : slight diarrhoea with abdominal spasm, epigastric

complaints like nausea and heartburn, reactions of hypersensitivity like exanthema.

Interactions : concomitant use may decrease the efficacy of anticoagulants

(coumarinderivates like Phenprocoumon, Warfarin). Tight monitoring is necessary.

Greece

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

Hungary

TU

Preparations:

400 mg Cynarae scol. folium extr. sicc (3-6:1, extraction solvent water)

Since:

2001

Pharmaceutical form:

Dragée, coated tablet

Posology for oral use in adults 3x1 dragée:

The use is not recommended in children under 12 years of age because of the lack of

available experience.

Duration treatment: Until the existence of the complaints but not more 2-3 months. If

the complaints reoccur the cure can be restarted but at least one month’s break

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Member

State

Regulatory Status

should be kept.

Indications:

For digestive complaints, feeling of fullness, nausea, flatulence, gallbladder disease,

to promote bile secretion (as cholagogue) , to promote fat digestion

Risks:

Contraindication : Obstruction of bile duct, cholangitis, hepatitis, hypersensitivity to

artichoke or other species of the Compositae.

Warnings : Patients with cholelithiasis should take artichoke leaf only after consulting a

health care professional.

Interactions : There are no data on concomitant use of Artichoke leaf with other

preparations.

Pregnancy, lactation : Safety during pregnancy and lactation has not been established.

In the absence of sufficient data, the use during pregnancy and lactation is not

recommended.

Adverse effects : mild digestive system disturbances may occur in rare cases; allergic

reactions might occur in sensitized patients.

Iceland

Not known.

Ireland

Not known.

Italy

Not known.

Latvia

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

Lithuania

Not known.

Luxembourg Not known.

Malta

Not known.

Netherlands

Not known.

Norway

Not known.

Poland

TU

Preparations:

1) Cynarae herbae extractum sicuum (3-6:1), extraction solvent water

2) Cynarae herbae tinctura (1:5), extraction solvent ethanol 70% (v/v)

3) Cynarae folii extractum siccum (25-35:1), extraction solvent water

4) Cynarae herbae extractum siccum (4:1), extraction solvent ethanol 50% (v/v)

5) Cynarae herba –herbal tea

Since:

1, 3) 1967; 2, 4) 1997; 5) since many years

Pharmaceutical form:

1) capsule, hard

2) oral liquid

3) capsule, hard

4) tablets

5) herbal tea

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Member

State

Regulatory Status

Posology

1) oral use, 3-4 capsules daily

2) oral use, 10 ml 3 times daily

3) oral use, 1 capsule daily

4) oral use, 2 tablets once a day (digestive disorders) or 2 tablets 3 times daily

(hyperlipidaemia)

5) oral use: 3 g (of the dried Cynarae herba in one glass of bolding water–as infusion)

1-3 times daily or in hyperlipidaemia 1.5 g (of the dried Cynarae herba in one glass of

bolding water – as infusion) 4 times daily

Indications :

1, 3) digestive complaints (e.g. stomach ache, feeling of fullness, flatulence)

2) digestive complaints and hepatobiliary disturbances

4) digestive complaints and hepatobiliary disturbances. Adjuvant to a low fat diet in

the treatment of mild to moderate hyperlipidaemia,

5) digestive complaints (feeling of fullness, nausea, flatulence). Adjuvant to a low fat

diet in the treatment of mild to moderate hyperlipidaemia.

Risks:

Mild gastro-intestinal disturbances reactions may occur in rare cases; allergic

reactions might occur in sensitized patients.

WEU

Preparations : Cynarae folii extractum aq siccum (4-6:1), extraction solvent: water

Since:

1997

Pharmaceutical form :

capsule, hard

Posology:

for oral use, 1-2 capsules once a day (digestive disorders) or 3-5 capsules daily (mild

hyperlipidemia)

Indications:

digestive complaints (feeling of fullness, nausea, flatulence, heartburn)- Adjuvant to a

low fat diet in the treatment of mild to moderate hyperlipidaemia

Risks :

Mild gastro-intestinal disturbances reactions may occur in rare cases; allergic

reactions might occur in sensitized patients

Portugal

No authorized herbal medicinal products containing Cynarae folium as a single drug

preparation are on the market.

Romania

Not known.

Slovakia

WEU

Preparations:

extractum fluidum

Since:

1996

Pharmaceutical form :

oral solution

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Member

State

Regulatory Status

Posology for oral use:

(tea spoon for 3 times a day)

Indications:

Indicated in light forms of hyperlipidemia as additional treatment. Indicated for adults,

adolescents and children

Risks:

None reported

Slovenia

Not known.

Spain

TU

Preparations:

1) Dried leaves for oral use as herbal tea or

2) Powdered leaves in pharmaceutical forms for oral use

At least since 1973

Pharmaceutical form:

1) Herbal tea

2) Tablets/Capsules

Posology for oral use in adults:

1) up to 3 g a day (1 to 3 caps of tea a day)

2) 600-1500 mg a day (Caps of 150; 175; 300; 500 mg)

Indications:

Dyspepsia

Risks :

None reported

Combinations products:

Combination of Artichoke with laxative products and with Boldo extract

Sweden

There is one combination product, a so called natural remedy, containing Cynara

scolymus together with Gentiana lutea and Curcuma longa .

United

Kingdom

Not known

1.3. Search and assessment methodology

2. Historical data on medicinal use

2.1. Information on period of medicinal use in the Community

The artichoke was used as a food and medicine by the ancient Egyptians, Greeks, and Romans.

Artichoke leaf has been used as a choleretic and diuretic in traditional European medicine since Roman

times [Bianchini & Corbetta 1977]. Artichoke ( Cynara scolymus L., ( Asteraceae ) is widely cultivated in

Mediterranean countries, particularly in Italy, the sprout being consumed as a vegetable. Globe

artichokes were first cultivated at Naples around the middle of the 15 th century, and are said to have

been introduced to France by Catherine de “Medici”. The Dutch introduced artichokes to England,

where they were growing in Henry VIII's garden at Newhall in 1530. They were introduced to the

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United States in the 19 th century, to Louisiana by French immigrants and to California by Spanish

immigrants.

2.2. Information on traditional/current indications and specified

substances/preparations

2.2.1.1. Type of tradition, where relevant

European tradition

2.2.1.2. Evidence regarding the indication/traditional use

The alcoholic extract of the leaves, currently used for the production of bitter liqueurs (about 10 g of

dried leaves per litre), has been documented as a traditional folk remedy for dyspeptic disorders.

Especially artichoke is the primary flavor of the Italian liquor.

The Commission E reported choleretic activity [Blumenthal et al. 2000; ESCOP 2009].

The British Herbal Pharmacopoeia reported hepatic action [BHP 1996].

The Merck Index reported the therapeutic category of cynarin, an active principle of artichoke, as

choleretic [Budavari 1996].

The African Pharmacopoeia indicates its use for the treatment of liver dysfunction as well for its

diuretic and anti-atherosclerotic actions [Iwu 1993].

Traditional medicinal uses of artichoke pertain to liver function as its leaves are considered choleretic

(bile increasing), hepatoprotective, cholesterol-reducing, and diuretic [Kirchhoff et al. 1994]. Artichoke

has been used in traditional medicine for centuries all over Europe as a specific liver and gallbladder

remedy and several herbal drugs based on the plant are used as well for high cholesterol and digestive

and liver disorders. Other uses around the world include treatment for dyspepsia and chronic

albuminuria. Artichoke is also often used to mobilize fatty stores in the liver and detoxify it, and as a

natural aid to lower cholesterol. In Brazilian herbal medicine systems, leaf preparations are used for

liver and gallbladder problems, diabetes, high cholesterol, hypertension, anemia, diarrhea (and

elimination in general), fevers, ulcers, and gout. Artichoke leaf has shown cholesterol-lowering and

lipid-lowering activity in rats and humans [Lietti 1977]. Human studies have validated carminative,

spasmolytic, antiemetic and choleretic actions [Kraft 1997].

In vivo , artichoke leaf has demonstrated hepatoprotective and hepatostimulating properties [Adzet et

al. 1987; Maros et al. 1966].

In Germany, artichoke leaf is used widely as a choleretic [BAnz 1998; Meyer-Buchtela 1999] for its

lipid-lowering, hepato-stimulating, and appetite-stimulating actions since at least thirty years [Hänsel

et al. 1992, 1994; Meyer-Buchtela 1999]. Moreover, in German pediatric medicine, herbs with a

relatively low bitter value such as artichoke leaf are considered suitable for the treatment of appetite

disorders [Schilcher 1997].

Preparations of artichoke have been used for bloating, nausea, and impairment of digestion [Bruneton

1999]. It is specifically indicated for "dyspeptic syndrome" though its proven lipid-lowering actions

suggest that it may also be useful as a prophylactic against atherosclerosis [Kraft 1997]. Artichoke leaf

has shown cholesterol-lowering and lipid-lowering activity in rats and humans [Lietti 1977]. Human

studies have validated carminative, spasmolytic, antiemetic, and choleretic actions [Kraft 1997].

In France, several pharmaceutical forms of Artichoke leaf extracts are also in use since the last thirty

years [Pharm. Franc. 1987; Martindale 1993; WHO Monographs 2009; ESCOP monographs supp.

2009].

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WORLDWIDE ETHNOMEDICAL USES

Europe

for bile insufficiency, cancer, detoxification, dyspepsia, gallbladder

disorders, high cholesterol, hyperglycemia, jaundice, liver

disorders, nausea

Brazil

for acne, anaemia, arthritis, arteriosclerosis, asthma, bile

insufficiency, blood cleansing, bronchitis, diabetes, diarrhea,

dyspepsia, digestive disorders, dandruff, fever, flatulence,

gallbladder disorders, gallstones, gout, heart function,

haemorrhage, haemorrhoids, high cholesterol, hypertension,

hyperglycaemia, inflammation, kidney insufficiency, liver disorders,

nephritis, obesity, prostatitis, rheumatism, seborriasis, ulcers,

urethritis, urinary disorders, and as an astringent and

vasoconstrictor

Dominican

Republic

for bile insufficiency, digestive problems, gallbladder disorders

Haiti

for oedema, hypertension, kidney disorders, liver problems, urinary

insufficiency

Mexico

for cystitis, gallstones, hypertension, liver disorders

The following herbal substances and herbal preparations are for more than 30 years on the European

market and are proposed for the monograph on traditional use .

a) Comminuted or powdered leaves for herbal tea (Belgium, Germany, Spain, Poland)

b) Powdered leaves (France)

c) Dry extract (DER 3.8-7.5:1), extraction solvent water (Poland, Germany)

d) Dry extract fresh leaves (DER 25-35:1), extraction solvent water (Poland)

e) Soft extract fresh leaves (DER 15-30:1), extraction solvent water (France)

2.3. Specified strength/posology/route of administration/duration of use

for relevant preparations and indications

Posology and indications of the traditional herbal substance and preparations of artichoke

Indications : traditionally used

a) Traditional herbal medicinal product to promote digestion (against dyspepsia, digestive complaints)

(Germany)

b) Traditional herbal medicinal product against digestive complaints (e.g. stomach ache, feeling of

fullness, flatulence) and/or adjuvant to a low fat diet in the treatment of mild to moderate

hyperlipidaemia (Poland)

c) Traditional herbal medicinal product against biliar disturbances, biliar colic

d) Adjuvant to allow fat diet in the treatment of mild to moderate hyperlipidaemia (for reducing

cholesterol (ES)

e) Traditionally used to promote urinary and digestive elimination functions. Traditionally used as a

choleretic and cholagogue (France)

The therapeutic indication which has been accepted by the MLWP is:

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Traditional herbal medicinal product for the symptomatic relief of digestive disorders such as dyspepsia

with a sensation of fullness, bloating and flatulence.

The product is a traditional herbal medicinal product for use in the specified indication exclusively

based upon long-standing use.

Posology :

Generally it has been proposed an average oral daily dose: for hypercholesterolaemia and dyspepsia,

1–2 g of a dried aqueous extract [Englisch et al. 2000; 27. Petrowicz et al. 1997; Holtmann 2003].

While for adults daily dose: 5–10 g of crude drug; or equivalent galenical preparations for oral use

[Blumenthal et al. 2000; Hagers Handbuch der Drogen 2003, WHO monographs, Vol. 4 2009]

a) Comminuted or powdered dried leaves for herbal tea

Daily dose of 6 g (3 g x 1-2 times per day corresponding to 600 mg dry aqueous extract, or 1.5 g x 4

times per day)

b) Powdered dried leaves

Daily dose of 600-1500 mg (in doses of 150, 175, 300, 500 mg)

c) Dry extract (DER 3.8-7.5:1) extraction solvent water

Daily dose 600-900 mg (in doses of 200, 300, or 600 mg)

d) Soft extract of fresh leaves (DER 15-30:1), extraction solvent water

Daily dose of 600-1200 mg (in doses of 200 mg) or in liquid form daily 9 ml (20 g of extract/100 ml)

e) Dry extract fresh leaves (DER 25-35:1), extraction solvent water

Daily dose 900 mg

Single dose up to 450 mg daily

In Germany exist also the following authorized products for TU:

Cynariae flos

3 expressed juices from fresh artichoke flower buds (1:0.6-0.9) on the market since 1978, expressed

juice, for TU

Cynariae herba

1 fluid extract from artichoke herb (1:2.4-5.2), extraction solvent ethanol on the market since 1978,

liquid, for TU

3. Non-Clinical Data

3.1. Overview of available pharmacological data regarding the herbal

substance(s), herbal preparation(s) and relevant constituents thereof

Constituents

Acids Phenolic, up to 2%. Caffeic acid, mono- and dicaffeoylquinic acid derivatives, e.g. cynarin (1.3-

di-O-caffeoylquinic acids) and chlorogenic acid (mono derivatives).

Flavonoids 0.1-2%. Flavone glycosides e.g. luteolin-7-β-D-rutinoside (scolymoside), luteolin-7- β-D-

glucoside and luteolin-4-β-D-glucoside.

Volatile oils Sesquiterpenes, β-selinene and caryophyllene (major); also eugenol, phenylacetaldehyde,

decanal, oct-1-en-3-one, hex-1-en-3-one, and non-trans-2-enal.

Other constituents Phytosterols (taraxasterol and β-taraxasterol), tannins, glycolic and glyceric acids,

sugars, inulin, enzymes including peroxidase, cynaropicrin and other sesquiterpene lactones

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(grosheimin, cynarotriol etc). The root and fully developed fruits and flowers are devoid of

cynaropicrin; highest content reported in young leaves.

Primary pharmacodynamics

Antioxidative, hepatoprotective and choleretic effects of artichoke leaf extracts as well as lipid-lowering

and anti-atherogenicactivity with increased elimination of cholesterol and inhibition of hepatocellular de

novo cholesterol biosynthesis have been demonstrated in various in vitro and in vivo test systems.

Antisyspeptic effects are mainly attributed to increased choleresis [Kraft 1997; ESCOP 2003].

Choleretic effect

The following information was retrieved from ESCOP (2003), while similar results are reviewed by

Hager (1992) Hager ROM 2004 [Hänsel 1992; Blaschek 2002].

 In vitro experiments

Antioxidant and cytoprotective effects

Antioxidant and cytoprotective effects of an artichoke leaf aqueous dry extract (4.5:1) were

demonstrated in primary cultures of rat hepatocytes exposed to t-butyl hydroperoxide (t-BHP). When

added simultaneously or prior to t-BHP, the extract inhibited lipid peroxidation in a concentration-

dependent manner down to 0.001 mg/ml [Gebhardt 1997i; 1997ii]. Several characteristic polyphenolic

constituents of artichoke leaf were effective in reducing t-BHP- induced melondialdehyde production

EC 50 values were 7, 8.1, 12.5, 15.2 and 28 μg/ml for luteolin caffeic acid, chlorogenic acid, cynarin and

luteolin-7-glucoside respectively. The extract also prevented loss of intracellular glutathione by t-BHP

[Gebhardt 1995i, 1996, 1997i, 1997ii; Gebhardt et al. 1998]. The effect of an artichoke leaf aqueous

dry extract (4.5:1) on free radical production was also studied in human polymorphonuclear cells was

tasted by flow cytometry using phorbol 12-myristate-13-acetate as the stimulant. The extract strongly

inhibited the generation of reactive oxygen species with an EC 50 of 0.23 μg/ml [Perez-Garcia et al.

2000].

Cynarin and caffeic acid showed significant cytoprotective activity (p<0.01 at 1 mg/ml) against carbon

tetrachloride in isolated rat hepatocytes, reducing leakage of the liver anzymes glutamine oxaloacetic

transaminase and glutamic pyrovic transaminase [Adzet et al. 1987]. Artichoke leaf aqueous dry

extract at t-20 μg/ml retaded Cu 2+ -mediated oxidation of human low density lipoproteine (LDL) in a

dose –depended manner: the effect was attributed in part to luteolin 7-glucoside (as well as

caffeoylquinic acids) [Brown &Rice-Evans 1990].

An aqueous dried extract (9:2) of the leaves was studied in human leukocytes to assess activity

against oxidative stress. The extract (median effective concentration 0.23 μg/ml) produced a

concentrationdependent inhibition of oxidative stress when cells were stimulated with agents that

generate reactive oxygen species: hydrogen peroxide, phorbol- 12-myristate-13-acetate and N -formyl-

methionyl-leucyl-phenylalanine. Cynarin, caffeic acid, chlorogenic acid and luteolin, constituents of

artichoke leaf extracts, also showed a concentration-dependent inhibitory activity in the above models,

contributing to the antioxidant activity of the extract in human neutrophils [Pérez- García 2000].

A study measured the effects of aqueous and ethanol extracts of the leaves on intracellular oxidative

stress stimulated by inflammatory mediators, tumour necrosis factor alpha and oxidized low-density

lipoprotein (ox-LDL) in endothelial cells and monocytes. Both extracts inhibited basal and stimulated

reactive oxygen species production in endothelial cells and monocytes, in a dose-dependent manner.

In endothelial cells, the ethanol extract (50.0 μg/ml) significantly reduced ox-LDL-induced intracellular

reactive oxygen species production by 60% ( p <0.001) and the aqueous extract (50 μg/ml) reduced

ox-LDL-induced intracellular reactive oxygen species production by 43% ( p <0.01). The ethanol extract

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(50 μg/ml) reduced ox- LDL-induced intracellular reactive oxygen species production in monocytes by

76% ( p <0.01). Effective concentrations of 25–100 μg/ml were well below the cytotoxic levels of the

extracts which started at 1.0 mg/ml as assessed by lactate dehydrogenase leakage and trypan blue

exclusion [Zapolska-Downar et al. 2002].

The flavonoids from artichoke ( Cynara scolymus L.) have been studied in human endothelial cells for

their up-regulate endothelial-type nitric-oxide synthase gene expression by [Li et al. 2004] while the

phenolic compounds of the plant have been further studied for such antioxidative activities [Wang et

al. 2003] and several other products from artichoke extracts showed similar activities [Llorach et al.

2002]. A study by Cervellati et al. (2002), focused on the antioxidant effects of artichoke extract in

cultured blood vessel cells and reported that the extract demonstrated "marked protective properties

against oxidative stress induced by inflammatory mediators". Artichoke's antioxidant properties were

also confirmed in others studies that focused on human cells under various induced oxidative stresses

[Jimenez-Escrig et al. 2003; Sarawek et al. 2008]. The water leaf extract of the plant has assayed and

referred to possess strong antioxidative, anti-inflammatory and antiproliferative properties [Trouillas et

al. 2003]. Antioxidative activities have been reported from Cynara extracts also from [Li et al. 2004;

Stoev SD et al. 2004; Jimenez-Escrig et al. 2003; Wang et al. 2003; Llorach et al. 2002; and Cervellati

et al. 2002].

Antiatherosclerotic and antihypercholesterolaemic activities

Artichoke leaf aqueous dry extract (4.5:1) inhibited the biosynthesis of cholesterol from 14 C-acetate in

primary cultured rat hepatocytes in a concentrations of 0.007-0.1 mg/ml produced moderate I

inhibition of about 20% at 1 mg/ml the inhibition was about 80% [Gebhardt 1995ii, 1998]. At 50-100

μg/ml, caffeic acid and cynarin produced negligible inhibition chlorogenic acid 10-15% and cynaroside

(luteolin 7-glucoside) 19-22% but luteolin 51-63% [Gebhardt 1998]. When cynaroside was incubated

with β-glucosidase, maximum inhibition of 50-60% was observed with an EC 50 of approx. 30 Μμ. In

human hepatic (HepG2) cells the maximum response of luteolin was more than 80% and the EC 50

value was slightly higher. It was concluded that luteolin (a minor constituent) and indirectly its

glucoside, cynaroside, seem to be mainly responsible for the inhibition of hepatic biosynthesis of

cholesterol by artichoke leaf extracts [Gebhardt 1997, 1998]. Subsequently it was demonstrated that

artichoke extracts inhibit cholesterol biosynthesis from. 14 C-acetate in primary cultured rat

hepatocytes, inhibition in human hepatic (HepG2) cells in weak unless they have been pre-treated with

β-glucosidase. This was explained by the fact the rat hepatocytes contain more endogenous β-

glucosidase, enabling release of luteolin from its glucoside, cynaroside. Since β-glucosidase is present

in the intestinal tract and in the liver, release of luteolin fron cynaroside may occur in the human body

[Gebhardt & Hanika 1999; Gebhardt 2001, 2002i, 2002ii; Brown & Rice Evans JE. et al. 1990; Fritsche

et al. 2002].

Cynara scolymus is thought among the herbs dealing with serum cholesterol reduction [Thomson Coon

et al. 2002, 2003], while it has been recently referred in the literature the activity of artichoke juice

which improves endothelial function in hyperlipidaemia [Lupattelli et al. 2004].

Hepatobiliary effects

In vitro an artichoke leaf aqueous dry extract enhanced the secretion of biliary substances in bile

canaliculi reformed in primary cultures of hepatocytes. A cholestatic effect induced in the cultures by

lithocholate was inhibited by the extract [Gebhardt 1996]. The effect of pressed juice (sap) from fresh

artichoke activity was investigated in isolated perfuse rat liver. Pressed juice, undiluted and diluted 1:3

and 1:5, produced dose-dependent increase in bile flow of up to 150%, 125% and 112% respectively

detectable 20 minutes after addition and reaching maximum value 10 minutes later. Bile acid

production remained almost unchanged [Matuschowski et al. 1997]. By testing fractions of present

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juice, it was shown that phenolic constituents were mainly responsible for the choleric action the

strongest effects on both choleresis and bile acid production being exerted by mono-and

dicaffeoylquinic acids. In further experiments with isolated perfuse rat liver a different pressed juice

(from fresh artichoke flower buds) produced a comparable increase in bile flow and increased bile acid

excretion by up to 128%. In contrast dried pressed juice (16:1 from flower buds) and dry aqueous

extract (4:1) from artichoke leaf increase bile flow without significantly increasing bile acid secretion

and no correlation with the content of caffeoylquinic acids was evident.

Antihepatotoxic activity

The effects of an aqueous extract of the leaves on taurolithocholate-induced cholestatic bile canalicular

membrane distortions were studied in primary cultured rat hepatocytes using electron microscopy.

Artichoke extracts at concentrations between 0.08 and 0.5 mg/ml were able to prevent the formation

of canalicular membrane transformations in a dosedependent manner when added simultaneously with

the bile acid. However prevention also occurred when the hepatocytes were preincubated with the

extracts, indicating that absorption of the bile acid to components of the extracts was not involved

[Gebhardt 2002]. The hepatoprotective activity of cynarin against carbon tetrachloride (CCl4)-induced

toxicity in isolated rat hepatocytes was compared with other phenolic compounds. Only cynarin and, to

a lesser extent, caffeic acid showed a cytoprotective effect [Adzet 1987]. Treatment of rats with three

consecutive doses of 500.0 mg/kg bw of an extract of the crude drug, administered by gavage 48, 24

and 1 h before CCl4 intoxication, produced a significant decrease in glutamic-oxaloacetic transaminase,

glutamic-pyruvic transaminase (also known as alanine aminotransferase or ALT), direct bilirubin and

glutathione levels, thus indicating a reduction in the potential for hepatotoxicity [Adzet et al. 1987].

Primary cultures of rat hepatocytes exposed to tert -butyl hydroperoxide were used for characterizing

the antioxidative and hepatoprotective potential of an aqueous extract of the crude drug and some

selected constituents. Addition of tert -butyl hydroperoxide to the culture media resulted in enhanced

lipid peroxidation as measured by the production of malondialdehyde and enhanced cytotoxicity

detected by leakage of lactate dehydrogenase. The extract added prior to or simultaneously with tert -

butyl hydroperoxide reduced both phenomena with a median effective concentration (EC50) of 95.0

and 12.0 μg leaf powder/ml respectively. Furthermore, the aqueous extract prevented the loss of

intracellular glutathione caused by tert -butyl hydroperoxide. Several polyphenolic and flavonoid

constituents of the extract were found to reduce malondialdehyde production. The median effective

concentration values were 8.1, 12.5, 15.2 and 28 μg/ml for caffeic acid, chlorogenic acid, cynarin and

cynaroside, respectively [Gebhardt and Fausel 1997]. Primary rat hepatocyte cultures exposed to tert -

butyl hydroperoxide or cumene hydroperoxide were used to assess the antioxidative and protective

potential of aqueous extracts of the leaves. Both hydroperoxides stimulated the production of

malondialdehyde, particularly when the cells were pretreated with diethylmaleate in order to diminish

the level of cellular glutathione. Addition of the extract did not affect basal malondialdehyde

production, but prevented the hydroperoxide-induced increase of malondialdehyde formation in a

concentration-dependent manner when presented simultaneously with or prior to the peroxides. The

effective concentrations were as low as 0.001 mg/ml [Gebhardt 1997]. The liver Protective Actions of

artichoke have been also tested and reported by [Maros T et al. 1966; Aktay G et al. 2000; Speroni E

et al. 2003].

Gastrointestinal effects

The antispasmodic activity of several fractions from artichoke and cynaropicrin as well with other

Brazilian traditionally used medicinal plants, on guinea-pig ileum has been demonstrated by

[Emendorfer et al. 2005i, 2005ii].

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Antimicrobial effects

The antibacterial and antifungal activities of artichoke extracts as well as of their phenolic compounds

have been assayed [Zhu XF et al. 2004, 2005; Yang B et al. 2005; Stoev SD et al. 2004].

 In vivo experiments

Hepatobiliary and hepatoprotective affects

Chlorogenic acid administered orally to rats at 5-40 mg/kg body weight significantly stimulated

choleresis (70%) and peristaltic activity (40%) in a concentration depended manner. A dose-depended

increase in bile flow of up to 95% and an increase in biliary-excreted cholesterol were observed

following a single intravenous administration of cynarin (7-166 mg/kg body weight) in the bile fistula

rat model. Choleresis was still observed 4 hours after administration of 100 or 166 mg/kg body weight

[Preziosi 1956, 1958, 1959, 1960].

A deproteinized aqueous extract of artichoke leaf, administrated orally to partially hepatectomized rats

at 0.5 ml/animal daily for 21 days, significantly increased liver tissues regeneration as measured by

residual liver weight, mitotic index and percentage of dinucleated liver cells [Maros et al. 1966]. In

further experiments using the same methodology, the deproteinized extract accelerated the increase in

liver weight, induced pronounced hypereamia and increased the percentage of binuclear hepatocytes

and the content of ribonucleic acid in liver cells [Maros et al. 1968].

Intraperitoneal administration of a purified acid-rich, butanolic extract of artichoke leaf at 10 mg/kg

protects mice against toxicity induced by ethanol: the LD 50 for treated mice was 6.8 g ethanol/kg

compared to 5.6 g ethanol/kg for the control group. The effect of the artichoke extract could be

reproduced by administration of a mixture of citric, malic, succinic and hydroxymethylecrylic acids (2.5

mg/kg: LD 50 of 7.1 g ethanol/kg) [Mortier et al. 1976].

Two hydroethanolic extracts of fresh artichoke [Bombardelli et al. 1977] were administered i.p to

groups of rats: a total extract (19% caffeoylquinic acids, 200 mg/kg body weight) and a purified

extract enriched in phenolic compounds (46% caffeoylquinicacids, 25 mg/kg body weight). Though bile

duct cannulation it was shown that both extracts stimulated choleresis significantly increasing the bile

dry residue and the total cholate secretion (p<0.05) [Lietti 1977]. The same extracts administered

orally (400 mg/kg body weight of total extract or 200mg/kg of purified extract) increased

gastrointestinal propulsion in rats by 11% and 14% respectively (p<0.05).

An aqueous extract of artichoke leaf (2.2% caffeoylquinic acids, 0.9% luteolin 7-glucoside)

administered orally to rats at 500 mg/kg body weight 48 hours, 24 hours and 1 hours before inducing

liver intoxication with carbon tetrachloride , improved liver function as measured by decreased levels of

bilirubin glutathione and liver enzymes [Adzet et al. 1987].

In bile duct cannulated rats an undefined artichoke leaf fluid extract (0.45 mg/kg body weight)

administered i.p. produced increases of 32% in bile flow and 495 in bile acid concentration respectively

[Saenz Rodriguez et al. 2002].

Two aqueous alcoholic extracts of the fresh leaves (total extract containing 19% caffeoylquinic acids,

at a dose of 200.0 mg/kg bw and a semipurified extract containing 46% caffeoylquinic acids, at a dose

of 25.0 mg/kg bw) were assessed in rats. Intraperitoneal administration stimulated choleresis, and

significantly increased bile dry residue and total cholate secretion ( p <0.05). Intragastric administration

of the same extracts (400.0 mg/kg bw, total extract and 200.0 mg/kg bw of the semipurified extract)

also increased gastrointestinal motility by 11% and 14%, respectively ( p <0.05) [Lietti 1977].

The effects of an extract of the crude drug on bile flow and the formation of bile compounds in

anaesthetized rats after acute administration and repeated oral administration (twice a day for 7

consecutive days) were studied. A significant increase in bile flow was observed after acute treatment

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with the extract as well as after repeated administration. The choleretic effects of the extract were

similar to those of the reference compound dehydrocholic acid. Total bile acids, cholesterol and

phospholipid were determined by enzymatic assays. At the highest dose (400.0 mg/kg bw), a

significant increase was observed after single and repeated administration ( p <0.01) [Saιnz Rodriguez

et al. 2002].

The choleretic effects of four extracts of the leaves (not described) were assessed in vivo in a study in

rats. Extracts 1, 2 and 4 did not show significant choleretic activity at a dose of 1.0 and 2.0 g/kg bw.

Extract 3, however, was found to induce an increase of bile flow, which was gradual and sustained.

Cynarin and chlorogenic acid, administered as pure compounds, did not show choleretic activity at any

of the doses tested and neither of them decreased the malondialdehyde content in liver [Speroni et al.

2003].

Treatment of rats with three consecutive doses of 500.0 mg/kg bw of an extract of the crude drug,

administered by gavage 48, 24 and 1 h before CCl4 intoxication, produced a significant decrease in

glutamic-oxaloacetic transaminase, glutamic-pyruvic transaminase (also known as alanine

aminotransferase or ALT), direct bilirubin and glutathione levels, thus indicating a reduction in the

potential for hepatotoxicity [Adzet et al. 1987].

Lipid-lowering and anti-atherogenic effects

Powdered artichoke aerial parts, administered orally at 110 mg/kg body weight for 120 days to rats fed

on an atherogenic diet, lowered increases in serum and liver cholesterol and prevented the formation

of atherosclerotic plaques [Samochowiec 1959, 1962i, 1962ii]. After 60 days on an atherogenic diet,

110 mg/kg body weight of powdered artichoke aerial parts, administered orally to rats daily for 10

weeks, lowered serum cholesterol by 36% compared to 25% in the control group [Samochowiec

1962iii].

Two hydroethanolic extracts of fresh artichoke a total extract (19% caffeoylquinic acids 100 mg/kg

body weight) and a purified extract (46% caffeoylquinic acids 25 mg/kg body weight), administered

intraoeritoneally to rats four times over a 28-hours period after inducing hyperlipidaemia with Triton

WR1339, decreased total cholesterol by 14% and 45% and triglycerides by 18% and 33% respectively

[Saenz Rodriguez 2002].

Cynarin (100 and 200 mg/kg body weight) administered intravenously to rabbits, lowered serum

cholesterol by about 20% Triton WR 1339-induced hypercholesterolaemia. In rats was significantly

lowered (p=0.05-0.02) by cynarin after intraperitoneal administration (2*200 mg/kg body weight)

[Preziosi 1958]. Cynarin injected at 30 mg/kg /day significantly lowered the increases in total serum

lipids (p<0.05) and esterified serum fatty acids (p<0.001) induced in rats by giving them 15% ethanol

instead of drinking water for 20 days [Samochowiec 1971].

Other effects

The preventive effect of hydroalcoholic Cynara scolymus extract on appearance of type 1 diabetes

mellitus in male rats has been studied by [Mahmoodabadi et al. 2007].

3.1.1. Conclusions on traditional use

Based on information obtained from Member states and data retrieved from handbooks it can be

concluded that the following extracts and uses of artichoke leaves fulfil the criteria for traditional use:

 Comminuted or powdered dried leaves for herbal tea

 Powdered leaves

 Dry extract (DER 3.8-7.5:1) extraction solvent water

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 Soft extract fresh leave (DER 15-30:1), extraction solvent water

 Dry extract fresh leaves (DER 25-35:1), extraction solvent water

Safety pharmacology

No information except toxicity data presented under 3.2 below

3.2. Overview of available pharmacokinetic data regarding the herbal

substance(s), herbal preparation(s) and relevant constituents thereof

After two days of a low-polyphenol diet to 10 healthy volunteers, they have been treated with 3 x 320

mg of an artichole leaf aquaeus dry extract (4-6:1; caffeoylquinic acids 34.3 mg/g, flavonoids 5.6

mg/g) every 4 hours (at 0.4 and 8 hours). Phenolic derivatives present in the artichoke extract were

not detected in the urine either as conjugates or aglycons; however b-glucuronidase treatment of urine

revealed the presence of ferulic, isoferulic, dihydroferulic and vanillic acids as major metabolites of

caffeoylquinic acids [Rechner et al. 2001].

In order to investigate potential inhibition or activation of cytochrome P450 (CYP) isoforms by extracts

of popular herbal drugs in a screening approach to predict impending interactions [Hilgendorf &

Döppenschmidt 2003]. Methods: Human liver microsomes were employed for screening, using 8

standard subtype-specific CYP substrates. The testing included ethanolic extracts of Serenoa repens

( Sabal serrulata , SR), Hypericum perforatum (HY), Harpagophytum procumbens (HP), Piper

methysticum (Kava, KA) and Cynara scolymus (CY). Organic solvent was removed for testing. At

extract concentrations derived from dose recommendations provided by German Authorities

(Commission E), differential effects of the various plants were observed. The effects ranged from

strong activation of enzymatic turnover, i.e. HP: 272 ± 12% (p<0.001) of control (mean ± SD, n=3)

for CYP2E1 to almost complete abolition of activity, e.g. for HY: 3 ± 0.7% (p<0.0001) for 3A4 and 0%

(p<0.0001) for 2C8. Overall, most pronounced inhibitory effects were observed for HY (0%

(p<0.0001) to 73 ± 2% (p<0.001)) and KA (5 ± 4% (p<0.001) to 92 ± 9% (not significant)), while

HP exhibited inhibitory (2C19:59 ± 1% (p<0.0001)) as well as stimulatory effects (2E1: see above).

The extracts of herbal drugs broadly used in Germany accomplish inhibition as well as activation of

human CYP activity in vitro . Detailed results concerning Cynara are not presented.

[Wittemer et al. 2002, 2005] . A variety of mono- and dicaffeoylquinic acids (CCA) and flavonoids

have been described as the main constituents of artichoke ( Cynara scolymus ) extract. Among them

chlorogenic acid, cynarine and the flavonoid luteolin-7-O-glucoside (cynaroside) are the most

prominent. A wide range of in-vitro activities of artichoke have been established, e.g. antioxidative and

choleretic actions and lipid reduction. Here, the metabolism and disposition of 2 different leaf extracts

(extract A: (CCA 28.9%, flavonoids 8.8%; extract B: CCA 6.2%, flavonoids 0.9%) were investigated in

healthy volunteers enroled in a 2-way crossover study. Neither the mono- and dicaffeoylquinic acids

nor the flavonoids present in the extracts were detected in human plasma as their original moieties. No

safety relevant information is provided, no change of the safety profile.

[Wittemer & Veit 2003] . Artichoke leaf extract (water>80°C, DER 4-6:1) Hepar SL ®. A validated

method was developed for the simultaneous determination of the hydroxycinnamates caffeic (CA),

dihydrocaffeic (DHCA), ferulic (FA), dihydroferulic (DHFA), and isoferulic acid (IFA) and the flavonoid

luteolin (LUT) in human plasma as metabolites derived from artichoke leaf extract. The method

involves sample preparation followed by separation using high-performance liquid chromatography on

reversed-phase material with a polar end capping (Aqua-C (18), 250Î4.6 mm). Selectivity and

sensitivity towards the target compounds were achieved by electrochemical array detection

(CoulArray). Calibration curves were constructed in the ranges 2.1-51.7 ng/mL (CA), 2.0-76.7 ng/mL

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(DHCA), 2.2-53.7 ng/mL (FA), 2.1-79.2 ng/mL (DHFA), 1.1-52.6 ng/mL (IFA) and 2.1-258.6 ng/mL

(LUT). Values for within-day and between-day precision and accuracy were in accordance with the

international guidelines for validation of bioanalytical methods. It is concluded that this newly

developed method is appropriate for analysing samples from bioavailability and pharmacokinetic

studies after oral administration of artichoke leaf extract. The authors describe a validated HPLC

method for the determination of prominent artichoke leaf extract metabolites in human plasma. The

availability of this method may stimulate further systematic investigation into the metabolic fate of

artichoke leaf constituents.

[Wittemer et al. 2005] . Artichoke leaf extract (water>80°C, DER 4-6:1) Hepar SL ®. In order to get

more detailed information about absorption, metabolism and disposition of ALE, two different extracts

were administered to 14 healthy volunteers in a crossover study. Each subject received doses of both

extracts. Extract A) administered dose: caffeoylquinic acids equivalent to 107.0 mg caffeic acid and

luteolin glycosides equivalent to 14.4 mg luteolin. Extract B) administered dose: caffeoylquinic acids

equivalent to 153.8 mg caffeic acid and luteolin glycosides equivalent to 35.2 mg luteolin. Urine and

plasma analysis were performed by a validated HPLC method using 12-channel coulometric array

detection. In human plasma or urine none of the genuine target extract constituents could be detected.

However, caffeic acid (CA), its methylated derivates ferulic acid (FA) and isoferulic acid (IFA) and the

hydrogenation products dihydrocaffeic acid (DHCA) and dihydroferulic acid (DHFA) were identified as

metabolites derived from caffeoylquinic acids. Except of DHFA all of these compounds were present as

sulfates or glucuronides. Peak plasma concentrations of total CA, FA and IFA were reached within 1 h

and declined over 24 h showing almost biphasic profiles. In contrast maximum concentrations for total

DHCA and DHFA were observed only after 6-7 h, indicating two different metabolic pathways for

caffeoylquinic acids. Luteolin administered as glucoside was recovered from plasma and urine only as

sulfate or glucuronide but neither in form of genuine glucosides nor as free luteolin. Peak plasma

concentrations were reached rapidly within 0.5 h. The elimination showed a biphasic profile. This well

designed pharmacokinetic study reveals interesting insights into the fact of Cynara leaf extract

constituents after oral administration. However, at the presence status these data are of no relevance

for the risk benefit ratio of artichoke leaf preparations. No change of the safety profile.

Absorption and metabolism of bioactive molecules after oral consumption of cooked edible heads of

Cynara scolymus L. (cultivar Violetto di Provenza) in human subjects: a pilot study [Azzini et al.

2007].

The current growing interest for natural antioxidants has led to a renewed scientific attention for

artichoke, due not only to its nutritional value, but, overall, to its polyphenolic content, showing strong

antioxidant properties. The major constituents of artichoke extracts are hydroxycinnamic acids such as

chlorogenic acid, dicaffeoylquinic acids caffeic acid and ferulic acid, and flavonoids such as luteolin and

apigenin glycosides. In vitro studies, using cultured rat hepatocytes, have shown its hepatoprotective

functions and in vivo studies have shown the inhibition of cholesterol biosynthesis in human subjects.

Several studies have shown the effect on animal models of artichoke extracts, while information on

human bioavailability and metabolism of hydroxycinnamates derivatives is still lacking. Results showed

a plasma maximum concentration of 6·4 (sd 1.8) ng/ml for chlorogenic acid after 1 h and its

disappearance within 2 h (P<0·05). Peak plasma concentrations of 19·5 (sd6·9) ng/ml for total caffeic

acid were reached within 1 h, while ferulic acid plasma concentrations showed a biphasic profile with

6·4 (sd1·5) ng/ml and 8·4 (sd4·6) ng/ml within 1 h and after 8 h respectively. The authors observed a

significant increase of dihydrocaffeic acid and dihydroferulic acid total levels after 8 h (P<0·05). No

circulating plasma levels of luteolin and apigenin were present. The study confirms the bioavailability of

metabolites of hydroxycinnamic acids after ingestion of cooked edible Cynara scolymus L. (cultivar

Violetto di Provenza). The study shows the absorption pathways of hydroxycinnamic acids after

consumption of edible cooked artichoke in human subjects. No safety relevant information is given, no

change of the safety profile.

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3.2.1. Assessor’s overall conclusions on pharmacokinetics

Six different studies provide information on pharmakinetic properties after the administration of water

extracts of leaf artichoke to healthy volunteers. In all cases none of the constituents of the extracts

have been detected in human plasma or urine. Caffeic acid its methylated derivatives ferulic and

isoferulic acids and the hydrogenated products dihydrocaffeic and dihydroferulic acid were identified as

metabolites from caffeoylquinic acids; except for dihydroferulic acid all of the other compounds were

found as sulfates or glucuronides. The luteolin administered as glucosides was recovered from plasma

and urine only as sulfate or glucuronide.

3.3. Overview of available toxicological data regarding the herbal

substance(s)/herbal preparation(s) and constituents thereof

Acute toxicity

Herbal preparations. The oral LD 30 and interperitoneal LD 10 in male rats of hydroalcoholic total extract

of artichoke leaf (19% caffeoylquinic acids) were determined as >2000 mg/kg and >1000 mg/kg body

weight respectively. With a purified extract (46% caffeoylquinic acids) the oral LD 40 and intraperitoneal

LD 50 were 2000 mg/kg and 265 mg/kg respectively [Bombardelli et al. 1977].

In primary cultures of rat hepatocytes no cytotoxic effects from an artichoke leaf aqueous dry extract

(4.5:1) were observed at concentrations of up to 1mg per ml of culture medium [Gebhardt 1997,

1995i, 1995ii, 1996].

Cynarin. The LD 50 of cynarin in mice was determined as 1900 mg/kg body weight. Upon administration

intraperitoneally to rats at 800 mg/kg or inravenously to rabbits at 1000 mg/kg/hour, cynarin

produced no apparent side effects or signs or toxicity [Preziosi 1958].

Sub-acute toxicity

Cynarin. Cynarin administered intraperitoneally to adult rats for 15 days at doses of 50-400 mg/kg/day

produced no macroscopic or histological abnormalities or changes in blood parameters [Preziosi 1958].

The oral and intraperitoneal median lethal doses of a hydroalcoholic extract of the leaves in rats were

2.0 g/kg and 1.0 g/kg bw, respectively [Lietti 1977]. External application of a leaf extract to the skin of

white rats, at doses of 1.0–3.0 g/kg bw for 21 days, did not produce any toxic effects or have any

cumulative effects on haematological parameters or the biochemistry of rats. No skin-irritating or eye-

irritating effects were observed in guinea-pigs [Holtmann et al. 2003; WHO monographs 2009].

Chronic oral toxicity

Cynarin. Cynarin administered intraperitoneally to rats daily for 40 days at 50-400 mg/kg/day caused

no changes in overall condition or blood parameters. Increased body weight and significantly increased

kidney weight (p<0.01) were observed only in animals treated with 400 mg/kg and significantly

increased liver weight (p<0.01) in animals treated with 100-400 mg/kg. Some rats treated with

cynarin at 100,200 and 400 mg/kg showed irrigative- degenerative changes in liver and kidneys most

evident in rats receiving 400 mg. Young rabbits treated intravenously with cynarin at 50 mg/kg/day for

30 days remained in good condition with no evidence of toxicity from extensive haematological and

histological investigation [Preziosi 1958].

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Caffeic acid (and chlorogenic acid)

International Agency for Research on Cancer (IARC) has evaluated caffeic acid for its potential

carcinogenicity (IARC Monographs Volume 56). After dietary administration of high doses of caffeic

acid (intakes 2-3 g/kg bw), there were high incidences of forestomach hyperplasia and renal tubular-

cell hyperplasia in mice of both sexes and an increase in forestomach squamous-cell papillomas and

carcinomas in male mice and renal-cell adenomas in female mice. In rats, a high dietary intake (about

07-0.8 g/kg) of caffeic acid produced squamous-cell papillomas and carcinomas of the forestomach in

animals of each sex and a few renal-cell adenomas in males.

Oral administration of caffeic acid in combination with known carcinogens resulted in enhancing or

inhibiting effects depending upon the carcinogen and the time of administration. The IARC (1993)

working group decided that caffeic acid is possibly carcinogenic to humans (Group 2B), because there

is sufficient evidence in experimental animals for the carcinogenicity of caffeic acid. No data were

available on the carcinogenicity of caffeic acid to humans (it should be noted that the recent review on

coffee carcinogenicity came to the conclusion, that caffeine drinking is generally protective as regards

to cancer [Nkondjock 2009]). The Working Group noted that humans and experimental animals

metabolize caffeic acid to the same metabolites and hydrolyse chlorogenic acid to caffeic acid. In vitro

and in vivo genotoxicity tests were generally negative, except increased gene mutations and

chromosomal aberrations in cultured rodent cells at high exposures; no evaluation was made regarding

these positive findings.

Genotoxicity

Several studies on mutagenicity/ genotoxicity of Cynara scolymus are available.

Antimutagenic potential of Cynara scolymus .

[ Križková et al. 2 004] . Three different triterpenoid saponins (cynarasaponins) from involucral bracts

of Artichoke were isolated and their antimutagenic effect was assessed. Using spectrophotometric

method it was shown that all three substances possess very good absorptive capability. The

antimutagenic effect of these substances was estimated against acridine orange (AO)- and ofloxacin-

induced damage of chloroplast DNA in Euglena gracilis assay. These cynarasaponins were

experimentally confirmed to exhibit different, statistically significant activity in reducing damage of

chloroplast DNA of the flagellate E. gracilis induced by AO and ofloxacin (p t <0.05-0.01). These findings

suggest that the antimutagenic effect of these compounds against AO-induced chloroplast DNA

impairment could be a result of their absorptive capacity. As far as ofloxacin is concerned, a possible

mechanism of the reduction of the chloroplast DNA lesion was not elucidated so far.

[Miadokova et al. 2006] . The potential antimutagenic activity of ECC was assayed by a test on sex-

linked recessive lethal mutations detection in Drosophila melanogaster males treated with

ethylmethane sulfonate (EMS). The possible enhancement of cytostatic/cytotoxic effect of cis-Pt by

ECC was evaluated in the cell revitalization assay by measuring cell viability via Trypan blue exclusive

assay using mouse leukemia cells L1210. Results: EMS was both toxic and genotoxic in D.

melanogaster males. It statistically significantly increased the frequency of sex-linked recessive lethal

mutations in comparison to the negative control. Furthermore, ECC statistically significantly reduced

the genotoxic effect of EMS. It acted in a desmutagenic manner via EMS inactivation. In the cell

revitalization assay, ECC enhanced the cytotoxic/cytostatic effect of cis-Pt. The therapeutic potential of

ECC was established on the basis of statistically significantly lowered recovery of cis-Pt pre-treated

mouse leukemia cells in the presence of ECC. Concluisons: The results imply that the extract isolated

from artichoke C. cardunculus L. has marked beneficial activities (antimutagenic and therapeutic effect

enhancing) and its potential biomedical application in the combination therapy of cancer and some

neurodegenerative diseases may be suggested.

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[ Miadokova et al. 2 008] . The extract of artichoke C. cardunculus L. (CCE) was investigated for its

potential antigenotoxic and antioxidant effects using four experimental model systems. In the

Saccharomyces cerevisiae mutagenicity/antimutagenicity assay, CCE significantly reduced the

frequency of 4-nitroquinoline-N-oxide- induced revertants at the ilv1 locus and mitotic gene

convertants at the trp5 locus in the diploid Saccharomyces cerevisiae tester strain D7. In the

simultaneous toxicity and clastogenicity/anticlastogenicity assay, it exerted an anticlastogenic effect

against N-nitroso-N′-methylurea-induced clastogenicity in the plant species Vicia sativa L. On the

contrary, despite CCE not being mutagenic itself, in the preincubation Ames assay with metabolic

activation, it significantly increased the mutagenic effect of 2-aminofluorene in the bacterial strain

Salmonella typhimurium TA98. In the 1.1-diphenyl-2- picrylhydrazyl (DPPH) free radical scavenging

assay, CCE exhibited considerable antioxidant activity. The SC 50 value representing 0.0054% CCE

corresponds to an antioxidant activity of 216.8 μM ascorbic acid which was used as a reference

compound. Although the mechanism of CCE action still remains to be elucidated, different possible

mechanisms are probably involved in the CCE antigenotoxic effects. It could be concluded that CCE is

of particular interest as a suitable candidate for an effective chemopreventive agent.

[Edenharder et al. 2003] . After in vivo mouse bone marrow micronucleus assay, homogenates of

artichoke among other vegetables and fruits reduced induction of micronuclei by benzo[a]pyrene (BaP)

by 43-50%. The flavonoids quercetin and its glucoside isoquercitrin, administered orally in doses of

0.03mmol/kg body weight simultaneously with intraperitoneally given BaP, reduced the number of

micronuclei in polychromatic erythrocytes of the bone marrow of mice by 73 and 33%. Ten-fold higher

concentrations, however, reversed the effects with a particular strong increase observed with

isoquercitrin (+109%; quercetin: +16%).

The genotoxic effects of flavonoid constituents present in the crude drug (quercetin and luteolin) were

assessed in two short-term bacterial assays. In Salmonella typhimurium (strains TA1538 uvrB- and

TA1978 uvrB+) the flavonoids did not induce damage in the DNA as recognized by UvrABC nuclease.

Results of the SOS-chromotest in Escherichia coli K-12 strains PQ37 and PQ243 indicated that the

flavonoids only weakly induced the SOS system [Czeczot and Kusztelak 1993].

Teratogenicity

No data available.

3.3.1. Assessor’s overall conclusions on toxicology

Various extracts of Cynara scolymus seemed to be of low acute or subchronic toxicity potential. It

should be also noted that all carcinogenicity (and other associated) studies available are not up to

current standards. The current consensus is that forestomach tumours in rodents after high irritating

exposures are less relevant for human risk assessment [Proctor et al. 2007]. The same opinion applies

also to rodent renal adenomas. No mutagenicity or genotoxicity studies were available. There are no

data on teratogenicity or carcinogenicity. Antimutagenic potential of artichoke has been reported but

they seem incomplete.

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3.4. Overall conclusions on non-clinical data

4. Clinical Data

4.1. Clinical Pharmacology

4.1.1. Overview of pharmacodynamic data regarding the herbal

substance(s)/preparation(s) including data on relevant constituents

Primary pharmacodynamics

Antioxidative, hepatoprotective and choleretic effects of artichoke leaf extracts as well as lipid-lowering

and anti-atherogenicactivity with increased elimination of cholesterol and inhibition of hepatocellular de

novo cholesterol biosynthesis have been demonstrated in various in vitro and in vivo test systems.

Antidyspeptic effects are mainly attributed to increased choleresis [Kraft 1997; ESCOP 2003].

4.1.1.1. Assessor’s overall conclusions on pharmacodynamics

At present, the mechanism of action of artichoke and its main compounds cannot be considered clarified.

4.1.2. Overview of pharmacokinetic data regarding the herbal

substance(s)/preparation(s) including data on relevant constituents

Data on the pharmacokinetics of artichoke’s constituents are not available.

4.2. Clinical Efficacy

4.2.1. Dose response studies

4.2.2. Clinical studies (case studies and clinical trials)

 Blood lipid and cholesterol lowering effects

[Petrowicz et al. 1997] . In a randomized double-blind, placebo-controlled study, the lipid-lowering

effects of an artichoke leaf aqueous dry extract standardized dry aqueous extract (4.5-5:1) were

investigated in 44 healthy volunteers over 12 weeks. The mean initial concentration were very low in

both the verum (204.2 mg/dl, n=22) and placebo (203.0 mg/dl , n=22) groups in volunteers with

initial cholesterol>230mg/dl(n ν -n ρ =3), 640mg of extract three times daily significantly decreased

concentration of total cholesterol (p=0.015) and triglycerides (p=0.01) compared to placebo in

volunteers with initial cholesterol >220 mg/dl (n ν -n ρ =5), serum cholesterol was not significantly

different (p=0.14) after treatment with the extract compared to placebo : however a significant

difference (p=0.012) could be detected for triglycerides. In volunteers with initial cholesterol >210

mg/dl (n ν =10,n ρ =7), treatment with the extract led to a significant difference (p=0.022) for

triglycerides compared to placebo.

[Wojcicki & Winter 1975] . Daily administration of 900mg of an artichoke extract with a maximum

polyphenolic acids content of 5.5% to 10 industrial workers with long term occupational exposure to

carbon disulfide for 30days significantly lowered blood levels of cholesterol (p<0.02) free fatty acids ,

phospholipids and total lipids (p, 0.05).

[Wojcicki et al. 1981] . Decreases in cholesterol, triglycerides, three fatty acids, phospholipids and β-

lipoproteins were observed in 30 healthy elderly subjects after daily administration for 6 weeks of 0.45

or 0.9 g of an undefined artichoke extract containing 0.09% or polyphenols.

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[Wojcicki et al. 1982] . In a comparative study, 73 patients with primary hyper-triglyceridaemia

resistant to treatment with clofibrate were treated daily for 1 month with an undefined artichoke

extract( 9 tablets , each containing 5 mg of polyphenolic acids , n=25) or with cynarin (0.75 g, n=28

or 1.5 g, n=20). The artichoke extract exerted significant total lipid-, triglyceride-, and phospholipids-

lowering, effects in about 56% of the patients , whereas 0.75 g or 1.5 g of cynarin improved lipid

parameters in 61% or 405 of the patients respectively.

[Heid 1991] . In an open study, 403 patients with functional gall bladder disorders were treated with

an undefined artichoke extract (2 tablets twice daily, each containing 375 mg of extract standardized

to 1% caffeoylquinic acids). After 4 weeks of treatment, complains such as nausea, stomach pains or

loss of appetite had disappeared in more than 52% of patients and symptoms had improved in more

than 80% of patients.

[Englisch et al. 2000] . In a multicentre, randomized, placebo-controlled, double- blind study, the

effect of a fresh artichoke leaf aqueous dry extract (25-35:1) was investigated in 143 patients with

hyperlipoproteinaemia (cholesterol >280 mg/dl) . Patients received either 1800 mg of artichoke extract

(n=71) or placebo (n=72) daily as coated tablets for 6 weeks. In the verum group reductions of total

cholesterol (18.5%) and LDL- cholesterol (22.9%) from baseline to end of treatment were significantly

superior (p=0.0001) to those in the placebo group (8.6% and 6.3% respectively). The LDL/HDL ratio

decreased by 20.2% in the artichoke extract group and 7.2% in the placebo group.

[Schmidel 2002] . Lowering of the cholesterol level by artichoke and fibre. A lowering of the

cholesterol level by artichoke preparations have been known for a long time. In this study with 54 test

patients at an average duration of about 24 days the effect of a standardized preparation (aqueous

artichoke leaf extract 3.8-5.5:1) (Hepar-POS) was measured in comparison with placebo of fibre. The

average lowering of cholesterol in all test patients with verum was 16.8% compared to 10.0% in all

patients with placebo. This difference was statistically significant. An even stronger cholesterol

lowering effect could be found tendentious with a simultaneous dose of fibre. The lowering of LDL is

similar to that of total cholesterol. The LDL/HDL-quotient could be lowered in the verum and fibre

groups while it rose slightly in the placebo group. Patients with flatulence obtained under verum a

significant improvement on their troubles while the troubles remained unchanged under placebo. Under

verum, no more dropouts or side effects than under placebo were found. The investigated extract was

found to be effective in lipid lowering treatment. Adverse events/side effects: verum: hypersensitivity

reactions [SOC: immune system disorders] n=1; placebo: flatulence [SOC: gastrointestinal disorders]

n=1; further adverse events reported were nausea, headache, sleep disturbances and stomachache

without any information whether they occurred in the verum or in the placebo group. No change of the

safety profile.

[Lupatteli et al. 2004] . Artichoke juice improves endothelial function in hyperlipaemia. Artichoke

extracts have been shown to produce various pharmacological effects, such as the inhibition of

cholesterol biosynthesis and of LDL oxidation. Endothelial dysfunction represents the first stage of

atherosclerotic disease; it is usually evaluated in humans by a noninvasive ultrasound method as

brachial flow-mediated vasodilation (FMV) and by the determination of several humoral markers such

as vascular cell adhesion molecule-1 (VCAM-1), intercellular adhesion molecule-1 (ICAM-1), and E-

selectin. Aim of the study was to investigate the effects of dietary supplementation with artichoke leaf

pressed juice on brachial FMV of hyperlipemics. The authors studied 18 moderately hyperlipemic

patients (LDL cholesterol > 130 <200 mg/dl and/or triglycerides >150 <250 mg/dl) of both genders

and 10 hyperlipemic patients, matched for age, sex and lipid parameters. All subjects were under

isocaloric hypolipidic diet. A basal determination of serum lipids, soluble VCAM-1, ICAM-1, E-selectin

and brachial FMV was performed. Thereafter patients were given 20 ml/die of frozen artichoke juice.

The same parameters were repeated after 6 weeks. After artichoke treatment there was an increase of

triglycerides (156 +/- 54 vs 165 +/- 76 mg/dL, p <0.05) and a reduction of total cholesterol (261 +/-

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37 vs 244 +/- 38 mg/dL, p <0.05) and LDL cholesterol (174 +/- 31 vs 160 +/- 34 mg/dL, p <0.05).

Controls showed a significant decrease in total and LDL cholesterol (respectively: 267 +/- 22 vs 249

+/- 20 mg/dL and 180 +/- 24 vs 164 +/- 23 mg/dL, both p <0.001). After artichoke there was a

decrease in VCAM-1(1633 +/- 1293 vs 1139 +/- 883 ng/mL, p <0.05) and ICAM-1(477 +/- 123 vs 397

+/- 102 ng/mL, p <0.05), brachial FMV increased (3.3 +/- 2.7 vs 4.5 +/- 2.4%, p <0.01), while

controls did not exhibit significant changes in VCAM-1, ICAM-1, E-selectin and brachial FMV. Univariate

analysis showed that, in artichoke patients, changes of VCAM-1 and ICAM-1 were significantly related

to changes in brachial FMV (respectively: r=-0.66 and r=-0.62; both p <0.05). In conclusion, artichoke

dietary supplementation seems to positively modulate endothelial function in hypercholesterolemia.

The vasodilatory effect of artichoke leaf pressed juice has been studied. Due to the small sample size

the results have to be viewed as preliminary and need confirmation by further human studies. The

target parameters assessed in this study are not directly related to approved indications of artichoke

leaf preparations. Adverse events/side effects: not reported. No change of the safety profile.

[Bundy et al. 2008] . The objective of this trial was to assess the effect of artichoke leaf extract (ALE)

on plasma lipid levels and general well-being in otherwise healthy adults with mild to moderate

hypercholesterolemia. 131 adults were screened for total plasma cholesterol in the range 6.0-8.0

mmol/l, with 75 suitable volunteers randomised onto the trial. Volunteers consumed 1280 mg of a

standardised artichoke leaf extract (ALE), or matched placebo, daily for 12 weeks. Plasma total

cholesterol decreased in the treatment group by an average of 4.2% (from 7.16 (SD 0.62) mmol/l to

6.86 (SD 0.68) mmol/l) and increased in the control group by an average of 1.9% (6.90 (SD 0.49)

mmol/l to 7.03 (0.61) mmol/l), the difference between groups being statistically significant (p=0.025).

No significant differences between groups were observed for LDL cholesterol, HDL cholesterol or

triglyceride levels. General well-being improved significantly in both the treatment (11%) and control

groups (9%) with no significant differences between groups. In conclusion, ALE consumption resulted

in a modest but favourable statistically significant difference in total cholesterol after 12 weeks. In

comparison with a previous trial, it is suggested that the apparent positive health status of the study

population may have contributed to the modesty of the observed response.

Assessor’s comment: In conclusion, artichoke leaf extract consumption resulted in a modest but

favourable statistically significant difference in total cholesterol after 12 weeks. In comparison with a

previous trial, it is suggested that the apparent positive health status of the study population may have

contributed to the modesty of the observed response.

 Hepatobiliary effects including influence on choleresis

[Kirschhoff et al. 1994] . In one double-blind placebo-controlled cross-over study, clinical trial, 20

male volunteers with acute or chronic metabolic disorders. The choleretic effect of a single dose was

investigated. The group was separated in two randomized subgroups of 10, either 1.92 g of the extract

(the contents of 6 proprietary capsules each containing 320 mg of extract plus excipients of a

standardized dry aqueous extract (4.5-5:1) of artichoke leaf extract (Hepar SL forte, Seturner,

Germany) in 50 ml water or a placebo of similar appearance was administered via an intraduodenal

probe, the subject having empty stomach on test days. Monitoring of bile secretion was significantly

higher (p<0.01) in the verum group: 127% higher 30 min after administration, 151% after 60 min.

(the maximum effect) and 94% after 90 min result a after 120 min and 150 min were also significantly

higher (p<0.05). Placebo treatment stimulated bile secretion to a lesser extent, with a maximum

increase of 39% after 30 min. No adverse or relevant changes in laboratory safety parameters were

observed.

[Kraft 1997] . An article by Kraft summarized various post-marketing surveillance studies conducted

on patients with dyspepsia and/or diseases of the liver or bile duct. The studies included anywhere

from 417 to 557 patients and treatment duration ranged from 4 to 6 weeks. Statistically significant

Assessment report on Cynara scolymus L., folium

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reduction of symptoms (e.g., abdominal pain, bloating, flatulence, and nausea) was reported for the

surveillance studies referred to in this paper. Artichoke preparations were well tolerated (up to 95% of

cases) with a low rate of side-effects.

 Antidyspeptic and Gastrointestinal effects

[Fintelmann 1996] . A multicentre open study with average treatment duration of 43.5 days was

conducted in 553 patients with dyspeptic complaints. The daily dose was generally 3-6 capsules of

artichoke leaf aqueous dry extract (3.8-5.5:1, 320 mg per capsule). Digestive complains declined in a

clinically relevant and statistically significant manner within 6 weeks of treatment, the overall

symptoms improved by about 71%. Compared to initial values, the subjective score reduction was

approx. 66% for meteorism, 76% for abdominal pain, 82% for nausea and 88% for emesis. In

subgroup of 302 patients, total cholesterol decreased by 11.5% and triglycerides by 12.5% while HDL-

cholesterol showed a minimal rise of 2.3%. Global efficacy assessed by the physicians was excellent as

good in 87% of cases.

[Fintelmann & Petrowicz 1998] . The same extract at a daily dosage of 3-6 capsules (320 mg per

capsule) was evaluated in a 6-monthopen study of 203 patients with dyspeptic complains. After 21

weeks of treatment, the overall improvement in symptoms was 66% compared to initial values, e.g.

vomiting by 84%, abdominal pain by 78%, nausea by 76%, flatulence by 70% and meteorism by 69%.

Concentration of total blood cholesterol and triglycerides, determined tin 171 and 170 patients

decreased by10.9% and 11.0% respectively. From determinations in 159 patients, LDL-cholesterol

decreased by 1508% and HDL- cholesterol increased by 6.3%. Global efficacy assessed by the

physicians was excellent or good in 85.7% of cases. No adverse reactions were reported.

[Marakis et al. 2002, 2003] . A recent post-marketing study indicated that high doses of

standardised artichoke leaf extract (ALE) (water >80°, DER 4-6:1, min. 0.3% flavonoids) may reduce

symptoms of dyspepsia. To substantial these findings, this study investigated the efficacy of a low-

dose ALE on amelioration of dyspeptic symptoms and improvement of quality of life. The study was an

open, dose-ranging postal study. Healthy patients with self-reported dyspepsia were recruited through

the media. The Nepean Dyspepsia Index and the State-Trait Anxiety Inventory were completed at

baseline and after 2 months of treatment with ALE, which was randomly allocated to volunteers as 320

or 640 mg daily. Of the 516 participants, 454 completed the study. In both dosage groups, compared

with baseline, there was a significant reduction of all dyspeptic symptoms, with an average reduction

of 40% in global dyspepsia score. However, there were no differences in the primary outcome

measures between the two groups, although relief of state anxiety, a secondary outcome, was greater

with the higher dosage (P=0.03). Health-related quality of life was significantly improved in both

groups compared with baseline. The authors conclude that ALE shows promise to ameliorate upper

gastro-intestinal symptoms and improve quality of life in otherwise healthy subjects suffering from

dyspepsia.

Assessor’s comment: The results of this open study add some evidence to the anyway well established

use of artichoke leaf extract in functional dyspepsia. The relatively low doses which were found

effective in this study are worth mentioning. However, as the study was uncontrolled the effectiveness

of these low doses remains in question. Adverse event/side effects: constipation: n=2; loose stool:

n=2; flatulence: n=1 [SOC: gastrointestinal disorders]. No change of the safety profile.

[Holtmann et al. 2003] . This study aimed to assess the efficacy of artichoke leaf extract (ALE)

[(water > 80°C DER 4-6:1), Hepar SL capsules, 2x320 mg t.i.d], in the treatment of patients with

functional dyspepsia (FD) and irritable bowel syndrome. In a double-blind, randomized placebo

controlled, multicenter trial (RCT), of 6 weeks treatment, 247 patients with functional dyspepsia(ROME

II criteria, but concomitant IBS symptoms, not dominating the clinical picture were allowed) were

recruited and treated with either a commercial ALE LI 120 preparation (2x320 mg plant extract t.d.s.)

Assessment report on Cynara scolymus L., folium

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or a placebo. Patients with predominant reflux- or IBS-symptoms were excluded.The primary efficacy

variable was the sum score of the patient's weekly rating of the overall change in dyspeptic symptoms

(four-point scale). Secondary variables were the scores of each dyspeptic symptom and the quality of

life (QOL) as assessed by the Nepean Dyspepsia Index (NDI). Two hundred and forty-seven patients

were enrolled, and data from 244 patients (129 active treatments, 115 placebos) were suitable for

inclusion in the statistical analysis (intention-to-treat). The overall symptom improvement over the 6

weeks of treatment was significantly greater with ALE than with the placebo (8.3 +/- 4.6, vs. 6.7 +/-

4.8, P < 0.01). Similarly, patients treated with ALE showed significantly greater improvement in the

global quality-of-life scores (NDI) compared with the placebo-treated patients (41.1 +/- 47.6 vs. -

24.8 +/- 35.6, P < 0.01). Safety parameters were comparable between both groups.

Assessor’s comment: In accordance with the commonly accepted monographs of the Commission E.

and ESCOP and earlier published clinical studies the artichoke leaf preparation was superior to placebo

in the treatment of patients with functional dyspepsia. The safety profile was very good, adverse

events [SOC: gastrointestinal disorders] mostly classified as mild or moderate and self-resolving. One

serious reaction (moderate bilateral adnexitis; [SOC: infections and infestations]) occurred in the

placebo group. No change of the safety profile but additional evidence for the indication of functional

dyspepsia is concluded.

[Bundy et al. 2004] . A subset analysis of a previous dose-ranging, open, postal study, in adults

suffering dyspepsia. Two hundred and eight (208) adults were identified post hoc as suffering with IBS.

IBS incidence, self-reported usual bowel pattern, and the Nepean Dyspepsia Index (NDI) were

compared before and after a 2-month intervention period. There was a significant fall in IBS incidence

of 26.4% (p < 0.001) after treatment. A significant shift in self-reported usual bowel pattern away

from "alternating constipation/diarrhea" toward "normal" (p < 0.001) was observed. NDI total

symptom score significantly decreased by 41% (p < 0.001) after treatment. Similarly, there was a

significant 20% improvement in the NDI total quality-of-life (QOL) score in the subset after treatment.

This report supports previous findings that ALE ameliorates symptoms of IBS, plus improves health-

related QOL. Artichoke leaf extract (extraction solvent: water; 5:1) 320 or 640 mg/per day0 was used

for the study.

Assessor’s comment: This study evaluates the therapeutic value of artichoke leaf extract in those

patients with dyspepsia who suffer from irritable bowel syndrome. The analysis was performed on a

subset of patients from a previously performed study in patients with dyspepsia and indicates that

artichoke leaf extract may be of therapeutic value in IBS patients not only for the symptoms assigned

to dyspepsia but also for other symptoms. Especially the condition of alternating constipation/diarrhoea

responded very good to the artichoke extract treatment. Although not placebo controlled, this

study/subset analysis yields evidence for a possible therapeutic value of artichoke leaf extract in the

treatment of IBS, which is currently not an approved indication of artichoke products. Adverse

events/side effects were not reported. No change of the safety profile.

 Other effects

[Wone et al. 1986] . In placebo placebo-controlled, double- blind study in malaria patients, a purified

aqueous dry extract from fresh artichoke leaf juice administration intramuscularly (100 mg/day) and

orally (1600 mg/day) for 3 days continuing the oral treatment on day 4 to 7 (n=46) or placebo (n=46)

was given as additional treatment to standard quinine therapy. More rapid improvement in clinical

symptoms of malaria observed in patients given artichoke therapy in addition to quinine were

attributed to hepatoprotective effects of the artichoke extract.

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 Irritable bowel syndrome

Irritable bowel syndrome, characterized by abdominal pain and altered bowel habit, has symptoms

that overlap with those of dyspepsia. Since the crude drug is used for the treatment of dyspepsia, a

postmarketing surveillance study was performed to assess its effects on irritable bowel syndrome. A

subgroup of patients ( n =279) with symptoms of irritable bowel syndrome was identified from a sample

of individuals ( n =553) with dyspeptic syndrome who were being monitored in a post marketing

surveillance study of the extract for 6 weeks. Analysis of the data from the subgroup with irritable

bowel syndrome revealed significant reductions in the severity of symptoms including abdominal pain,

bloating, flatulence and constipation, and favourable evaluations of overall effectiveness by both

physicians and patients [Walker et al. 2001].

Overview of clinical studies with artichoke

Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

Wojcicki

& Winter

1975

10

indus

trial

work

ers

Efficacy,

tolerability

Daily administration

of 900 mg

artichoke extr. Max.

polyphenolic acids

content 5.5%

30 days 10 industrial

workers

long term

occupational

exposure to

carbon disulfide

Cholesterol

lowering effects

significantly lowered

blood levels of

cholesterol (p<0.02)

free fatty acids ,

phospholipids and total

lipids (p, 0.05)

Wojcicki

et al.

1982

73

Comparativ

e study

Undefin. ALE ( 9

tablets, of 5 mg of

polyphenolic acids ,

n=25) or 0.75 g or

1.5 g cynarin per os

1

1 month 73 patients with

primary hyper-

triglyceridaemia

resistant to

treatment with

clofibrate

Lipid lowering

effects

TheALE exerted

significant total lipid-,

triglyceride-,and

phospholipids-lowering,

effects in 56% of

patients , whereas 0.75

g or 1.5 g of cynarin

improved lipid

parameters in 61% or

45% of patients

Kirschhoff

et al.

1994

20

double-

blind,

placebo-

controlled ,

cross-over

study

1.92 g (320x6) of

stand.dry water

extr.(4.5-5:1) of

artichoke leaf (6

capsules -320 mg) in

50 ml water

or placebo admnistr

via an intraduodenal

probe

20 males in two

subgroups

acute or chronic

metabolic

disorders

bile secretion higher

(p<0.01) in verum

group: 127% higher 30

min after admin., 151%

after 60 min. (the

maximum effect) and

94% after 90 min result

a after 120 min and 150

min were also

significantly higher

(p<0.05). Placebo

treatm max. increase

39% after 30 min

Efficacy,

tolerability,

safety

Assessment report on Cynara scolymus L., folium

EMA/HMPC/150209/2009

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Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

Fintelman

n 1996

553

multicentre

open study,

safety,

Efficacy,

daily dose 3-6 caps.

ALE aqueous dry

extr. (3.8-5.5:1, 320

mg per capsule) per

os

43.5

days

553 patients with

dyspeptic

complaints

Dyspepsia

digestive

complaints

Digestive complains

declined within 6 weeks

of treatm. All symptoms

improved 71%.

Meteorism reduction

approx 66%, 76% for

abdominal pain , 82%

for nausea 88% for

emesis. In subgroup of

302 patients, total

cholesterol decreased

11.5% triglycerides

12.5%. Global efficacy

by physicians excellent

as good in 87% of cases

No AEs

Kraft

1997

417

to

557

patie

nts

post-

marketing

surveillance

studies

4 to 6

weeks

417 to 557

patients

dyspepsia and/or

diseases of the

liver or bile duct

Statistically significant

reduction of symptoms

(e.g., abdominal pain,

bloating, flatulence, and

nausea) was reported

for the surveillance

studies referred to in

this paper. Artichoke

preparations were well

tolerated (up to 95% of

cases) with a low rate of

side-effects

Petrowicz

et al.

1997

44

healt

hvolu

nteer

s

randomized

double-

blind ,

placebo-

controlled

study

640 mg of dry water

extr ), 640 mg x3

daily per os

Placebo

12

weeks

44 groups in

volunteers with

initial cholesterol

>230 mg/dl(n ν -

n ρ =3)

Lipid lowering

effects

Decreased concentration

of total cholesterol

(p=0.015) and

triglycerides (p=0.01) to

placebo in volunt.

cholesterol >220 mg/dl

(n ν -n ρ =5), significant

differ. (p=0.012) for

triglycerides compared

to placebo

Efficacy,

tolerability

Fintelman

n &

Petrowicz

1998

203 multicentre

open study,

safety,

Efficacy,

Tolerability,

daily dose 3-6

capsules ALE

aqueous dry extract

(3.8-5.5:1, 320 mg

per capsule) per os

6

months

203 patients with

dyspeptic

complains

Dyspepsia

digestive

complaints

After 21 weeks treatm

improvement of

symptoms 66% e.g.

vomit by 84% ,

abdominal pain 78% ,

Assessment report on Cynara scolymus L., folium

EMA/HMPC/150209/2009

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Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

safety,

Efficacy

nausea 76%, flatulence

70% and meteorism

69%. Total blood

cholesterol -triglycrds, in

171 among patients

decreas. 10.9% and in

159 determ. patients,

LDL-cholesterol decreas.

by 15.8% and HDL-

cholesterol by 6.3%.

Global efficacy by the

physicians excellent or

good in 85.7% of cases.

No AEs

Englisch

et al.

2000

143

Multicentrer

andomized,

placebo-

controlled,

double-

blind study

Efficacy,

tolerability

fresh artichoke leaf

water extr. (25-

35:1)

Daily 1800 mg

(n=71) or placebo

(n=72) as coated

tabs per os 1

6 weeks 143 patients with

hyperlipoproteina

emia ( cholesterol

>280 mg/dl)

Lipid lowering

effects

In verum group

reduction total

cholesterol (18.5%) and

LDL- (22.9%) from

baseline to end of

treatment signif.

superior (p=0.0001) `to

those in placebo group

(8.6% and 6.3%

respectively) LDL/HDL

ratio decreased dy

20.2% in verum group

and 7.2% in the placebo

group

Schmidel

2002

54

test

patie

nts

Stand. preparation

(aqueous ALE 3,8-

5,5:1) (comparison

with placebo

24 days 54 patients with

hyperlipoproteina

emia (

Lipid lowering

effects

The average lowering of

cholesterol in all test

patients with verum was

16.8 % compared to

10.0 % in all patients

with placebo. This

difference was

statistically significant

side effects: verum:

hypersensitivity

reactions [SOC: immune

system disorders] n=1;

placebo: flatulence

[SOC: gastrointestinal

disorders] n=1; ad. effe

Assessment report on Cynara scolymus L., folium

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Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

nausea, headache, sleep

disturbances and

stomachache without

information whether

they occurred in the

verum or in placebo

group

Lupatteli

et al.

2004

28

20 ml/die of frozen

artichoke juice

6 weeks 18 moderately

hyperlipemic

patients (LDL

cholesterol > 130

<200 mg/dl

and/or

triglycerides >150

<250 mg/dl)

10 hyperlipemic

patients

males and women

Lipid lowering

effects

Controls showed

signif.decrease in total

and LDL cholesterol

(267 +/- 22 vs 249 +/-

20 mg/dL and 180 +/-

24 vs 164 +/- 23

mg/dL, both p <0.001).

Also decrease in VCAM-

1(1633 +/- 1293 vs

1139 +/- 883 ng/mL, p

<0.05) and ICAM-1(477

+/- 123 vs 397 +/- 102

ng/mL, p <0.05),

brachial FMV increased

(3.3 +/- 2.7 vs 4.5 +/-

2.4%, p <0.01).

Bundy et

al. 2008

131

randomized

, double

blind

placebo

controlled

trial

1280mg (320 x 4)

of a standardised

artichoke leaf

extract (ALE), or

matched placebo,

daily

12

weeks

131 adults

Lipid lowering

effects

Plasma total cholesterol

decreased in the

treatment group by

average of 4.2% (from

7.16 (SD 0.62) mmol/l

to 6.86 (SD 0.68)

mmol/l) and increased

in the control group by

an average of 1.9%

(6.90 (SD 0.49) mmol/l

to 7.03 (0.61) mmol/l),

difference between

groups statistically

significant (p=0.025).

No significant

differences between

groups were observed

for LDL cholesterol, HDL

cholesterol or

triglyceride levels.

Assessment report on Cynara scolymus L., folium

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Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

Kirschhoff

et al.

1994

20

double-

blind,

placebo-

controlled ,

cross-over

study

1.92 g (320x6) of

stand.dry water

extr.(4.5-5:1) of

artichoke leaf (6

capsules -320 mg) in

50 ml water

or placebo admnistr

via an intraduodenal

probe

20 males in two

subgroups

acute or chronic

metabolic

disorders

bile secretion higher

(p<0.01) in verum

group: 127% higher 30

min after admin., 151%

after 60min. (the

maximum effect) and

94% after 90 min result

a after 120 min and 150

min were also

significantly higher

(p<0.05). Placebo

treatm max. increase

39% after 30 min

Efficacy,

tolerability,

safety

Marakis

et al.

2003

516

320 or 640

mg of ALE

daily

open, dose-ranging

postal study

2

months

516 participants

454 completed

the study

self-reported

dyspepsia.

Nepean Dyspepsia

Index and State-

Trait Anxiety

Inventory were

completed at

baseline

Dyspepsia

digestive

complaints

significant reduction of

all dyspeptic symptoms,

with an average

reduction of 40% in

global dyspepsia score.

Health-related quality of

life signif. improved

compared with baseline.

ALE ameliorates upper

gastro-intestinal

symptoms and improves

quality of life in healthy

suffering from

dyspepsia.

side effects:

constipation: n=2; loose

stool: n=2; flatulence:

n=1 [SOC:

gastrointestinal

disorders]

454

comp

leted

the

study

Holtmann

et al.

2003

247

patie

nts

(ALE)

[(water >

80° C DER

4-6:1),

Hepar SL

capsules,

2x 320 mg

t.i.d],

Double-blind,

randomized

controlled trial (RCT)

6 weeks treatment of 247

patients with

functional

dyspepsia (FD)

quality of life

(QOL) as assessed

by the Nepean

Dyspepsia Index

(NDI)

Functional

dyspepsia

data from 244 patients

(129 active treatment,

115 placebo) were

suitable statistical

analysis. All symptom

improvement was signif.

higher with ALE than

with the placebo (8.3

+/- 4.6, vs. 6.7 +/- 4.8,

P < 0.01). ALE showed

Assessment report on Cynara scolymus L., folium

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Study

ID

Stud

y

DATE

s

Pers

ons

Design

Control

type

Study

objective

Study &,

Ctrl Drugs

Dose, Route,

Duratio

n

Gender M/F

Diagnosis

Inclusion

Criteria

Primary Efficacy

Endpoint

signif. greater improvmn

in global quality-of-life

scores (NDI) compared

with placebo-treated

patients (41.1 +/- 47.6

vs. - 24.8 +/- 35.6,

P<0.01).

Bundy et

al. 2004

208

patien

ts

ALE

(extraction

solvent:

water; DER

1:5) 5:1)

320 or 640

mg/per day

subset analysis of a

previous dose-

ranging, open,

postal study

2

months

IBS self-reported

usual bowel

pattern, and the

Nepean Dyspepsia

Index (NDI)

dyspepsia

dealing with

irritable bowel

syndrome (IBS)

significant fall in IBS

incidence of 26.4%

(p<0.001) after ALE NDI

total symptom score

signif. decreased by

41% (p<0.001) after

ALE. Signif.

Improvement 20% in

NDI total quality-of-life

(QOL).

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4.2.3. Clinical studies in special populations (e.g. elderly and children)

No information available.

4.3. Overall conclusions on clinical pharmacology and efficacy

In a multicentre, randomized , placebo-controlled , double- blind study by [Englisch et al. 2000], the

effect of a fresh artichoke leaf aqueous dry extract (25-35:1) was investigated in 143 patents for its

lipid lowering effects without obtaining convincing results: In the verum group, the reduction of total

cholesterol was 18.5% and of LDL 22.9%. In another randomized double-blind, placebo-controlled

study [Petrowicz et al. 1997] studied the same effects (lipid lowering effects) with a water extract of

Cynara in 44 healthy volunteers. After 12 weeks, a decreased concentration of total cholesterol

(p=0.015) and triglycerides (p=0.01) to placebo (volunt. cholesterol >220 mg/dl (n ν -n ρ =5), significant

differ. (p=0.012) for triglycerides compared to placebo) was reported. The groups were too small to

adequately evaluate the final results. Finally, in the study of [Holtmann et al. 2003] it was aimed to

assess the efficacy of artichoke leaf extract (water > 80° C DER 4-6:1, 2x 320 mg t.i.d), in the

treatment of patients with functional dyspepsia (FD) and irritable bowel syndrome. In a double-blind,

randomized placebo controlled, multicenter trial (RCT), 247 patients with functional dyspepsia (ROME

II criteria, but concomitant IBS symptoms, not dominating the clinical picture were allowed) were

recruited and treated with either a commercial preparation (2x320 mg plant extract t.d.s.) or a

placebo. The overall symptom improvement over the 6 weeks of treatment was higher with Cynara

extract than with placebo (8.3 +/- 4.6, vs. 6.7 +/- 4.8, P<0.01) with higher improvement in the global

quality-of-life scores but enough detailed and accepted definition of functional dyspepsia.

Throughout all existing clinical trials, the efficacy was not supported sufficiently but the determined

safety of the use of Cynara extracts was evaluated adequately.

5. Clinical Safety/Pharmacovigilance

5.1. Overview of toxicological/safety data from clinical trials in humans

5.2. Patient exposure

5.3. Adverse events and serious adverse events and deaths

No major adverse events have been reported from clinical human pharmacological studies with

preparations containing extracts of artichoke leaf involving over 1600 subjects and study duration of

up to 2 years. Overall, 19 minor adverse events were reported; mainly gastrointestinal complaints

[Fintelmann 1996; Fintelmann & Petrowicz 1998; Kirschhoff et al. 1993; Englisch 2000; Petrowicz et

al. 1997; Wojcicki et al. 1975, 1981; Palacz et al. 1981; Woyke et al. 1981; Wone et al. 1986]. A

systematic review of published human studies concluded that safety data for artichoke leaf extract

indicate only mild and infrequent adverse effects [Pittler & Ernst 1998].

The following groups of adverse events / side effects are mentioned by the review authors:

 Immune system disorders

- allergic reactions

 Metabolism and nutrition disorders

- decreased appetite

Assessment report on Cynara scolymus L., folium

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 Gastrointestinal disorders

- flatulence

 General disorders and administration site conditions

- weakness

- hunger

Known allergies to artichokes and related species ( Asteraceae or Compositae ).

Obstruction of bile ducts. In case of gallstones, use only after consulting a physician.

5.3.1.1. Serious adverse events and deaths

One case (serious) was related to treatment with artichoke leaf dry extract containing medicinal

products. The other 4 cases are related to allergic reactions following ingestion of artichoke or are

connected to occupational situations, however, not transferable to the use of herbal medicinal products

containing Cynara .

A 24-year–old woman was hospitalised on 30 th of November 2005 because of asthenia and urticaria.

She had neither any medical history nor any risks of virus infection or acute or chronic alcoholic

intoxication. She had started consumption of Hepanephrol (2 ampoules/day) for slimming on 6 Nov

2005. Liver tests were normal in September 2005 on the occasion of a routine check. On 30 November

2005 she developed asthenia and urticaria requiring medical consultation. Clinical examination

revealed no fever, no icterus, no signs of hepatocellular insufficiency and no signs of hepatic

encephalopathy. Abdominal palpation revealed a painless abdomen without signs of hepatomegaly.

There were no signs of thrombosis, and auscultation of the heart was normal. Hepatic enzymes were

elevated as follows: ALAT 40 times higher than normal (N), ASAT 48 x N; GGT 1.3 x N, ALP 1.3 x N.

Bilirubin and prothrombin were in normal range. Tests for hepatitis A, B, C, herpes, cytomegaly,

Epstein-Barr, or toxoplasmosis were negative. Further tests were without findings. The ECG was

normal. Ultrasound testing of the liver and the bile ducts didn’t show any abnormal findings; no

gallstones or signs of dilatation of the bile ducts or signs of chronic hepatopathy were found. The

admistration of Hepanephrol was stopped on day of admission. Liver parameters improved within 3

weeks. A liver biopsy was not performed [Sinayoko et al. 2007].

Assessor’s comment: As stated by the authors, a causal relationship is formally possible in this case

because of a plausible temporal relationship and because of an improvement of the reaction following

the discontinuation of the product. Thus, an intolerability or hypersensitivity reaction cannot

completely be excluded here. However, the used product is insufficiently described including the

relevance of the used dosage. In addition, the product was not used in the recommended indication

(off label use). In summary, based on the available information it is assessed that this case report may

not be directly transferred to other artichoke preparations as used in Germany. If a general advice not

to use a product in case of known hypersensitivity is given in the SPC, no change of the safety profile

is concluded; no other measures have to be taken.

[Franck et al. 2005] . Anaphylactic reaction to inulin: first identification of specific IgEs to an inulin

protein compound. This case of an immediate allergic reaction resulting in an anaphylactic shock was

not caused by an artichoke leaf preparation but two food products containing added inulin (Raftilose).

However, differential diagnosis of this case led to the assumption of a cross-allergy with artichoke.

Given the extremely rare occurrence of inulin allergy the probability of an allergic cross reaction after

the intake of medicinal artichoke products in patients previously sensitised against inulin by

consumption of other inulin containing food is considered to be extremely low. No change of the safety

profile.

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[Gabdnan et al. 2003] . Acute oedema of the tongue: a life-threatening condition. This paper focuses

on a number of life-threatening cases of acute tongue edema. In one of ten cases reported in this

paper the patient had consumed an "artichoke" prior to the event. The authors assess this case as

being directly related to the artichoke consumption. However, as the artichoke was consumed as a

food, it may have been that it was prepared with a spice dressing, or was otherwise prepared or

concomitantly consumed with other, not mentioned food. Thus, the causality of artichoke for the

adverse reaction is not assessable. However, the reaction must be assessed as possible in relation to

artichoke which belongs to the family of Asteraceae . The - generally low - possibility of such reactions

against any Asteraceae is well known and adequately addressed in most products with a warning label

for patients with known allergy against any Asteraceae plant. No change of the safety profile.

[Miralles et al. 2003] . Occupational rhinitis and bronchial asthma due to artichoke ( Cynara

scolymus ): Two cases of contact allergy are reported. Both cases involved vegetable warehouse

workers who developed occupational rhinitis and bronchial asthma following exposition to artichokes.

While the symptoms described in these cases are relatively severe the article also stresses that only

two additional case reports of artichoke allergy were found in a Medline and Embase data base search.

Both cases fit into the well known picture of rarely occurring allergy against Cynara. No change of

benefit risk ratio.

Assessor’s comment: A total of 5 cases with adverse reactions during treatment with Cynara has been

identified in the literature, which did not change the benefit risk ratio.

5.4. Laboratory findings

None reported.

5.5. Safety in special populations and situations

No reports.

5.6. Intrinsic (including elderly and children) /extrinsic factors

No reports.

5.7. Drug interactions

Concomitant use with Cynara containing medicinal products may decrease the efficacy of

anticoagulants (coumarin derivates like Phenprocoumon, Warfarin) [ESCOP 2009] .

5.8. Use in pregnancy and lactation

In addition, one review deals with herbal infusions used for induced abortion [Ciganda and Laborde

2003]. In this paper, Cynara is only briefly mentioned in a table without any clinical proof. However,

due to the lack of any data and in accordance with general medical practice, Cynara- containing herbal

medicinal products should not be used during pregnancy and lactation.

5.9. Overdose

No information.

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5.10. Drug abuse

No information.

5.11. Withdrawal and rebound

No information.

5.12. Effects on ability to drive or operate machinery or impairment of

mental ability

No information.

5.13. Overall conclusions on clinical safety

Only mild adverse events were reported in all published clinical trials. The pharmaceutical forms are

therefore acceptable with respect to clinical safety.

6. Overall conclusions

Artichoke is characterized by the phenolic acid constituents, in particular cynarin. Experimental studies

( in vitro and in vivo ) support some of the result uses of artichoke. Traditionally, the choleretic and

cholesterol-lowering activities of globe artichoke have been attributed to cynarin [Lietti 1977].

However, studies in animals and humans have suggested that these effects may in fact be due to the

monocaffeoylquinic acids and cynarin present in artichoke (eg chlorogenic and neochlorogenic acids).

Clinical trials investigating the use artichoke and cynarin in the treatment of hyperlipidaemia generally

report positive results. However, further rigorous clinical trials are required to establish the benefit of

globe artichoke leaf extract as a lipid – and cholesterol-lowering agent. Hepatoprotective and

hepatoregenerating activities have been documented for cynarin in vitro and in animals rats. However,

these effects have not yet documented in clinical studies.

The existing clinical trials indicate that the artichoke leaf extracts (water dry extract of dried and fresh

leaves) is somehow effective against functional dyspepsia and also for its lipid lowering effects, but not

adequately documented, so the Well Establish Use cannot be supported.

Moreover, the following herbal preparations are since a period of 30 years on the European market and

are proposed in the monograph for T raditional Use :

a) Comminuted or powdered dried leaves for herbal tea

b) Powdered leaves

c) Dry extract (3.8 - 7.5:1), extraction solvent water

d) Soft extract fresh leaves (15-30:1), extraction solvent water

e) Dry extract fresh leaves (25-35:1), extraction solvent water

All the above herbal preparations have been proposed for traditional use, for the symptomatic relief of

digestive disorders such as dyspepsia with a sensation of fullness, bloating and flatulence, based on

long standing use.

The product is a traditional herbal medicinal product for use in the specified indication exclusively

based upon long-standing use. A total of 5 cases with adverse reactions during treatment with Cynara

have been identified in the literature, no change of benefit risk ratio.

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Due to the lack of any data and in accordance with general medical practice, Cynara-

containing herbal medicinal products should not be used during pregnancy and lactation.

Only mild adverse events were reported in all published clinical trials. The pharmaceutical

forms are therefore acceptable with respect to clinical safety .

As there is no available data on genotoxicity, carcinogenity and reproducibility on fumitory extracts,

the establishment of a Community List Entry is not possible because of safety concerns.

Annex

List of references

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Herbal Medicines for Human Use

Herbal Medicines
for Human Use