Herbal and drug hepatotoxicity represents a major clinical challenge regarding both assessment of the culprit1–4 and therapeutic measures.5 Similar to synthetic drugs, hepatotoxicity by herbs is an overall rare event in a few susceptible individuals.6 However, it is well understood that frequency of herbal hepatotoxicity may increase due to improved awareness of possible hepatotoxic side effects by herbs and the growing herbal usage in Western countries. Herbs may be taken as a drug under regulatory control or as an unregulated dietary supplement including polyherbal mixtures.3,6,7 These conditions complicate a sound causality assessment in patients with suspected herbal hepatotoxicity, especially when multi-morbidity requires a polydrug therapeutical regime. Published case reports and spontaneous reports communicated to and from regulatory agencies may also lack a thorough, structured, quantitative and hepatotoxicity specific causality assessment approach, leading to doubtful causality associations between the used herb and the observed liver disease in some cases,3,8 and herb identification may be another problem.8 Considering these limitations, hepatotoxicity may be caused by a wide range of herbs such as Aloe vera,9 Indian Ayurvedic herbs,10 Atractylis gummifera, Callilepsis laureola, Camelia sinensis, Cascara sagrada, Chelidonium majus (Greater Celandine), Dai-Saiko To, Garcinia cambogia, Hydroxycut, Jin Bu Huan, Larrea divariatica (Chaparral), Mentha pulegium (Penny Royal), Morinda citrifolia (Noni), Paeonia sp., Paulinia cupana, Senna sp., Shou wu pian, Syo-Saiko-To, Teucrium polium (Germander), Valerian,11 Boh-Gol-Zhee, Centella asiatica, pyrrolizidine alkaloids,2 HerbaLife,12 and kava.13–18

In an early case report published 1998, a positive reexposure test was described when the patient resumed her treatment with an ethanolic kava extract.13 Based on this well documented case study, the property of kava as a potentially hepatotoxic herb was generally accepted.14,15,19–21 However, due to confounding variables in cases with assumed kava hepatotoxicity following the use of ethanolic and acetonic kava extracts as well as kava-herbs mixtures, an international discussion emerged as to what extent kava may harm the liver.14–30 There is now good evidence that under certain conditions kava may be hepatotoxic in a few susceptible patients,13–21,30 but the hepatotoxic risk of kava use appears rather low provided kava treatments followed regulatory recommendations.14,15,20,21 Furthermore, the issue appears to be more complex and challenging since some uncertainties exist as to what extent the use of traditional aqueous kava extracts may also be potentially hepatotoxic.16,21,25,30

The aim of this review is to evaluate the clinical data and courses of patients with kava hepatotoxicity. An approach will be made to elucidate the challenges and pitfalls of causality assessments used in this particular disease. Finally, issues of overdose, prolonged treatment, comedication, extraction procedures, and plant quality will be discussed.

All patients with primarily suspected hepatotoxicity by any drug or dietary supplement (DDS) including kava should undergo an assessment as to whether criteria of the diagnosis of hepatotoxicity as specific disease entity are indeed fulfilled.3,31 In this context, drugs include synthetic and herbal drugs under regulatory control, and dietary supplements comprize also herbal dietary supplements which lack regulatory surveillance. DDS hepatotoxicity requires for its diagnosis values of alanine aminotransferase (ALT) and/or alkaline phosphatase (ALP) to be at least 2 N (N corresponds to the upper limit of the normal range), whereas the activities of aspartate aminotransferase (AST) and γ-glutamyltranspeptidase (γGT) are not considered in this context. For further assessment, differentiation of the hepatocellular, cholestatic or mixed form of hepatotoxicity caused by DDS is essential31 by measurements of serum activities of ALT and ALP on the day the diagnosis of kava hepatotoxicity is suspected.15 Each activity was expressed as a multiple of the upper limit of the normal range (N), and the ratio (R) of ALT: ALP was calculated. Liver injury is hepatocellular, when ALT > 2N alone or R ≥ 5; cholestatic, when there is an increase of ALP > 2N alone or when R ≤ 2; of the mixed type when ALT > 2N, ALP is increased and 2 < R < 5. Notably, for the regulatory cases with suspected kava hepatotoxicity virtually no initial data for ALT and ALP have been presented by the German regulatory agency BfArM32 concerning the kava drug under its regulatory surveillance.32,33 Therefore, the regulatory ban of kava use failed to include any information regarding a definition of suspected hepatotoxicity32 and is consequently not founded on regulatory, clinical and scientific grounds.

In the case reports and spontaneous reports of patients with regulatory suspected kava hepatotoxicity, the causality for kava was primarily evaluated on an ad-hoc basis.32 This approach was also used in other studies13,14,19,20 despite its known high rate of missed diagnoses unrelated to the use of the investigated synthetic drugs3,31 and herbs.8,34–37 Certainly, various causality methods are available and have been discussed in the past.3,21,38–43 Causality assessment was perceived as not well established in the regulatory cases,44 and ad-hoc causality assessments are generally considered as inadequate methods for causality evaluation in patients with suspected kava hepatotoxicity.17,21 In particular, the regulatory assessment of cases from Germany (n = 20) and Switzerland (n = 6) with assumed hepatotoxicity by kava using the ad-hoc approach for causality evaluation32 is not acceptable on scientific grounds.15–17,21 In a subsequent regulatory assessment, detailed appraisal of the WHO and the Naranjo scale has been presented, but it remained unclear whether one or both of these assessment methods have actually been applied to the 26 regulatory cases of assumed kava hepatotoxicity.43 It rather appears that this was not the case; intermediate causality degrees such as possible/probable have been described and attributed to some patients, but intermediate classifications are not considered by the scale of WHO or Naranjo. The two latter scales are also hepatotoxicity unspecific assessment methods and should not be applied in cases of suspected hepato-toxicity by DDS38,39 including kava.32 Similarly, the WHO scale used for the causality assessment of hepatotoxicity with kava products by the WHO30 should no longer be used for a causality assessment of suspected toxic liver disease by DDS due to lack of hepatotoxicity specificity; it may be replaced by a structured, quantitative and hepatotoxicity specific causality assessment method commonly used by hepatologists in a similar context3,31,40 and by EMA (European Medicines Agency, formerly EMEA) as outlined previously.34,35

The scale of CIOMS (Council for International Organizations of Medical Sciences)40,41 or the maintest as its updated scale3,31 represents a well validated structured, quantitative and hepatotoxicity specific causality assessment method and was em-ployed for evaluation of suspected kava hepatotoxicity in a total of 31 cases15–18 but not in other cases.13,14,19,20,30,32,43 Using a structured causality assessment method, item by item may be evaluated and published;15,18 this approach facilitates both transparency provided by the regulatory agencies and appropriate evaluation through the scientific community. Within the frame of a structured evaluation, a positive reexposure test is considered as a surrogate marker and gold standard for the diagnosis of DDS hepatotoxicity.41 Although a positive rechallenge test supports DDS etiology, the sensitivity is not 100%.3,41 For causality assessments in cases of suspected DDS hepatotoxicity, additional methods such as the pre-test for a quick evaluation and the post-test for exclusion of various differential diagnoses are available and useful.3,31

A total of 9 case series are worthy of discussion,14,19,20,30,45–49 in addition to the 13 case reports to be analyzed subsequently.13,47,50–61 In a comprehensive study of a case series published in Australia, heavy use of traditional aqueous kava extracts was associated with greatly increased serum activities of γGT and a concomitant decrease of bilirubin, but values for ALT, AST or ALP have not been published.45 In another Australian report of traditional aqueous kava extracts, serum γGT and ALP activities were increased with normal values of ALT and bilirubin and lack of AST data presentation.46 Similar results were obtained in a predominantly Tongan population in Hawaii with increased serum activities for γGT and ALP and unchanged ALT and AST values.48 Further, a case series from New Caledonia showed in heavy users of traditional aqueous kava extracts high serum γGT activities in most cases and marginally elevated ALT and AST activities in only a few ones, whereas ALP values have not been communicated.47 Considering the commonly normal or only slightly increased serum activities of ALT and AST,46–48 in none of these case series evidence is provided for signs of striking and clinically relevant hepatocellular injury in the reported cases; this is in clear contrast to high ALT and AST values observed in some other patients who used ethanolic or acetonic kava extracts15–21 or aqueous ones.16,47 However, the laboratory constellation of increased γGT45–48 and ALP46,48 deserves further pathogenetic and clinical evaluation regarding possible malnutrition due to hypocaloric diets, alcohol, hepatic enzyme induction, enzyme adaptation, or cholestasis as discussed previously16 on the basis of experimental data.47,62–64 Indeed, the rare possibility exists and cannot be excluded with certainty at present that increased values of γGT and ALP45–48 may already signify incipient but still subclinical hepatic injury of the cholestatic type; this form with high values of γGT and ALP is observed in some cases with pronounced drug induced liver injury.42 At any rate, these four case series with populations originating from Australia,45,46 New Caledonia47 and Ton-ga,48 are not suitable for further causality assessment on a quantitative basis due to lack of individual case details required for a thorough analysis.

There are five other case series of patients with primarily suspected kava hepatotoxicity.14,19,20,30,49 Three studies reached the conclusion that there was little evidence for liver disease in causal relationship to kava use.14,19,20 The fourth study49 has been criticized and judged of little value because of the reporting of wrong data, age of patients, gender, and concomitant treatments.30 Similarly, the causality assessment method used in this report49 was considered not appropriate, lacking also an item by item analysis and important case details usually required for a sound causality evaluation.18 Various data presented in the criticized study49 could not be corroborated with results published by others.13,18–20 The claim that other possible etiologies of hepatitis were ruled out in all patients49 is also difficult to reconcile in view of various pre-or coexisting and kava independent liver diseases established by thorough analysis.15 All four studies mentioned above14,19,20,49 included also published case reports and spontaneous reports with regulatory attributed causality for kava,32 and only these reports among others were further analyzed for quantitative causality assessment.15–18 In addition, there was a compilation of 93 cases with kava hepatotoxicity primarily assumed by others and described by the WHO, but the notification was explicitly added that an intensive clinical examination of each individual report was not intended.30 In general, the WHO cases were poorly documented, and most of the reports were considered incomplete to one degree or another; for instance, in 63% of the cases tests for acute viral infections were not mentioned. Nevertheless, eight of the cases were coded as having a probable association between kava use and liver disease.

A total of 13 case reports of patients with primarily suspected kava hepatotoxicity have been published,13,47,50–61 mostly as full length publications with two reports in abstract or short version form.53,54 Case reports published as full length papers referred to patients originating from Germany (n = 5),13,52,55,59,60 Switzerland (n = 2),56,57 Spain (n = 1),58 Australia (n = 1),50 New Caledonia (n = 2),47 and the United States (n = 1).51 The cases have been analyzed in detail15–21 with the exception of one case from Spain58 and two cases from Germany.59–61 In the Spanish report, kava extracts of unidentified brands with unknown applied solvents and possible other herbal ingredients have been used.58There were also daily overdoses of 750 mg kavalactones58 which were with more than six times far beyond the regulatory recommendation of 60–120 mg daily for not longer than 3 months.32,33 Since the kava containing products were taken for three months, this equates to a cumulative dose of 67.5 g.58 The latter value is far beyond the allowed amount of 10.8 g15 and suggestive of chronic intoxication due to massive overdose by a factor of 6.25. Early symptoms appeared within 2 weeks of treatment, suggesting an already ongoing liver disease such as a veno-occlusive disease (VOD). Histological changes were described as centrolubular hemorrhagic liver cell necrosis and other alterations which were considered compatible with VOD,58 a thrombotic disease of the hepatic veins commonly observed after the use of teas and herbs containing pyrrolizidine alkaloids.2 Compatible with the VOD diagnosis is the described prolonged dechallenge period of four months and raising serum activities of γGT and ALP even one month after cessation of the kava extracts. Due to lack of detailed information also regarding individual parameters, it is unclear whether hepatitis A was indeed assessed and to what extent and which indivi-dual other forms of hepatitis were excluded.58 In the one report from Germany,59 synthetic D-kavain was used rather than a claimed herbal kava extract,60 and in the other German case, signs of liver disease appeared only three weeks after the end of short term use of traditional aqueous kava extracts,61 lacking thereby a clear temporal association.

Various spontaneous reports of patients with suspected kava hepatotoxicity have been presented to national regulatory agencies such as those of European countries,30,32,43 Australia, Canada, and the United States.43 In several studies the conclusion was reached that the German regulatory data presentation of most spontaneous cases of kava hepatotoxicity was selective,3,17 and commonly of poor quality.3,14,15,17,19–23,26,44 The latter qualification was also recognized in the WHO report30 and is generally realized for other cases with suspected DDS hepatotoxicity.3,4,8,34–37 As expected, most of the regulatory presented spontaneous reports could only be partially or not assessed at all, and causality for kava was unlikely, excluded or unassessable in many cases.14,15,17–21,26,30,32 Similarly, there was little concordance of judgements when the high graded causality assignments of suspected kava hepatotoxicity proposed by the German BfArM32 were further analyzed and found to be at best low graded by the former British MCA (Medicines Control Agency),14,17,20 EMA,17,20 or the WHO.30 It is of note that 18 cases of spontaneous reports of patients origina-ting from Germany and presented by the German regulatory health agency BfArM32 were re-analyzed by the WHO report.30 Among the 18 cases from Germany, the regulatory health agency attributed causalities for kava as highly probable (n = 1), probable (n = 11), and possible/probable (n = 2),41 whereas the WHO report coded a probable causality as the highest grade for only one single case.30 The causality categories and definitions of the WHO Collaborating Centre for International Drug Monitoring were used presumably by both the WHO report30 and BfArM,43 suggesting specific problems of the two assessor groups of experts with their causality assessments. These shortcomings support the view that the hepatotoxicity unspecific causality assessment method of the WHO scale is not suitable in this particular context since diverging results were obtained with identical cases. It also appears that spontaneous reports presented to and assessed by regulatory agencies failed to significantly contribute to the overall assessment of causality for kava in patients with suspected hepatotoxicity.

In a total of 31 patients with liver disease in primarily suspected causal relation to kava, causality assessment was considered feasible due to sufficient information in most cases (Table 1).15,16,21 The ages of the 31 patients ranged from 14 to 81 years, and there were 28 females and 3 males. The activities of ALT and AST were usually greater than 5 N (upper limit of the normal range) and often fairly high, reaching values up to 3121 U/L (Table 1);15,16 also, due to missed diagnosis, low values (ALT 115 U/L, AST 53 U/L) have been reported (case 26, Table 1). The initial ratio of ALT: AST was usually greater than 1. Serum γGT and ALP activities were, in general, normal or slightly elevated.14 In all assessable cases there was an increased ratio of ALT: ALP greater than or equal to 5 when serum activities were expressed as a multiple of N. These results are compatible with hepatocellular liver disease and not with cholestatic or mixed type. Neither cytopenia nor eosinophilia in the differential blood count was commonly observed.

In 18 of 31 patients, alternative diagnoses were documented (Table 1):14,15 genuine AIH, PBC, or overlap syndrome (case 2); HSV hepatitis (case 3); LKM positive AIH and pancreatitis (case 4); genuine AIH under treatment with cortisone (case 5); liver disease of unknown etiology (case 6); genuine SMA positive AIH, EBV AIH, EBV hepatitis, possibly also VZV hepatitis (case 7); questionable liver disease of unknown etiology (case 8); questionable liver disease of unknown etiology (case 9); liver disease of unknown etiology, possibly related to comedication (case 10); PBC (case 11); liver disease probably related to kava, cholecystitis, cholangitis or myelodysplastic syndrome (case 12); preexisting cryptogenic liver cirrhosis (case 14); liver disease of unknown etiology, possibly related to kava or pancreatitis (case 15); suspected preexisting hepatobiliary disease of unknown etiology (case 17); PBC, preexisting liver cirrhosis of unknown etiology, pancreatitis (case 18); EBV hepatitis (case 22); liver cirrhosis due to genuine AIH, PBC, or overlap syndrome (case 24); hyperthyroid hepatopathy (case 25); non-alcoholic steatohepatitis (case 26); and genuine AIH (case 29). It is of note that alternative diagnoses are quite often recognized when thorough causality assessments have been done in primarily suspected DDS hepatotoxicity.3,31,34–37

The clinical course was severe in eleven out of 31 patients and included death (n = 1), death after liver transplant (LTX) (n = 3), and LTX with good outcome (n = 7) (Table 1).15,16 Confounding variables such as daily kava overdose, prolonged treatment and comedication were apparent in various patients (Table 1).15,16,21 In 28 out of 31 cases, both daily dose of kavalactones and the duration of treatment were known (Tables 1 and 2).15,16 When use of ethanolic and acetonic kava extracts was considered, only five out of evaluable 24 patients, corresponding to 217, adhered to the regulatory recommendations regarding both the daily dose of kavalactones up to120 mg and the duration of treatment up to 3 months, whereas the other 19 patients (797) did not so (Table 1).15,16 With regard to kava-herbs mixtures, both patients used a daily overdose of 180 and 200 mg kavalactones for three and four months, respectively. Information of comedication could be assessed in 30 of 31 cases and was declared in 26 patients, equating to 877 (Table 1).15,16 Furthermore, a detailed case analysis of the 26 patients with primarily suspected kava hepatotoxicity due to the use of ethanolic and acetonic kava extracts revealed that information regarding the indication for kava treatment was lacking in 5 patients (cases 4, 9, 10, 13, 17); in the remaining group of 21 patients, depression was included in the list of treatment indications for 10 patients (cases 1, 2, 5, 6, 8, 12, 14, 18, 20, 24), equating to 487. Depressive disorders have been explicitly declared by the regulators as contra-indication;33 provided the patients adhered to the regulatory recommendation regarding depression as contraindication for kava treatment, the respective risk for kava hepatotoxic could have been diminuated almost by half.

In 23 out of 31 patients (Table 1), liver histology was available, showing a wide range of histological findings.15,16 These include not only necrosis alone (cases 5,7,11,21) and combined with hepatitis (cases 17,19,29,30,31), hepatitis and intrahepatic cholestasis (cases 20 and 22), hepatitis and bile duct proliferation (case1), hepatitis, intrahepatic cholestasis, and bile duct proliferation (case 3), intrahepatic cholestasis (case 8), or hepatitis, intrahepatic cholestasis and cholangitis (case 12), but also other changes were found such as toxic hepatopathy with hepatic atrophy (case 4), piecemeal necrosis (case 24), lobular hepatitis (case 10), ballooning liver cells (case 26), intrahepatic cholestasis and fibrosis (case 18), and intrahepatic cholestasis with signs of hypersensitivity (case 2). Hepatic eosinophilia was also reported (case 21).

Basic data were obtained from various sources.14–20 Regulatory information and ad-hoc causality assessment was presented by the database of the German regulatory agency (BfArM)32 and the Swiss regulatory agency (formerly IKS).32 With the scale of CIOMS (40) or the main-test as its updated scale,3,31 causality assessment for kava and CD was achieved.15,16 For ALP, aSt, and ALP usually initial values are given. Regarding the section of specific information for each individual patient, a recurrent increase of ALT was found in some patients, indicating a kava independent cause of the liver disease as outlined previously in the qualitative CIOMS assessment.54 For the kava extracts and mixtures, the consumed amount was given in mg kavalactones/d, and the duration of treatment was presented in month(s), m in short.

A detailed causality analysis of all 31 patients has been performed with the scale of the updated CIOMS in form of the main-test.15,16,21 The studies were based on 26 regulatory cases from Germany (n = 20) and Switzerland (n = 6)41 including published reports13,53–58 with primarily assumed causality for kava by the regulators.32 In addition, five published case reports47,50–52 of patients originating from New Caledonia,47 Australia,50 the United States,51 and Germany52 with a possible or probable causality for kava alone or combined with comedicated DDS were included.16 Due to insuffient data supply essential for a hepatotoxicity specific causality assessment, some cases of other reports19,20,30 have not been considered in this analysis. In the overall group of 31 cases, a temporal association between emerging liver disease and kava use was not apparent in 4 patients (cases 9,10,17,25).15,16 Causality for kava ± comedication was unlikely or excluded in 17 of 31 cases and evident in the remaining 14 patients (Table 1). It was highly probable for kava alone (n = 1), probable for kava alone (n = 2), probable for both kava and comedication (n = 1), probable for kava and possible for comedication (n = 1), possible for kava alone (n = 1), and possible for both kava and comedication (n = 8).15,16,21 Kava has been used by these 14 patients as aqueous kava extracts (n = 3), ethanolic kava extracts (n = 5), acetonic kava extracts (n = 4), and herbal mixtures containing also kava (n = 2), and some typical features became evident (Table 2).15–18,21

A total of 14 patients (cases 1,12,13,15,16,19–21,23,27–31) with liver disease showed a highly probable, probable, or possible causality for kava ± comedication (Table 1), with involvement of all kava products (Table 2). Only these 14 patients were used as basis for the characterization of kava hepatotoxicity as a specific read disease entity (Table 3), and the data of the present analysis were supplemented by various results of previous studies.14–21 Of the 14 patients, twelve were females and two males which corresponded to a ratio of 6: 1, and the ages ranged from 14 to 60 years (Table 2). Their initial values for ALT, AST, and ALP were in the ranges of 568–4539 U/L, 220–3500 U/L, and 163–530 U/L, respectively (Table 1). Histology of the liver was available in eight of the 14 patients, showing liver cell necrosis and hepatitis (cases 1,12,19–21,29–30,31), combined with either bile duct proliferation (case 1) or intrahepatic cholestasis (case 20).

The indication for treatment with ethanolic and acetonic kava extracts was not declared in one (case 13) out of 9 patients, and depression was listed as indication in the documents of four patients (cases 1,12,15,20) of the remaining eight ones (Table 1). Therefore, half of the patients with kava hepatotoxicity were treated for depression as a disease which is contraindicated for kava treatment according to the regulatory statement.33 It appears that kava hepatotoxicity might have been a preventable disease in half of the patients, provided regulatory recommendations were followed and treatment with kava would not have been initiated.

Considering all 14 cases (Tables 1 and 2), daily overdose (cases 1,15,16,20,21,23, 29,30), prolonged treatment (cases 1,13,19,20,30), or both together (cases 1,20,30) was not uncommon, excluding two patients (cases 27 and 28) who used a traditional aqueous kava extract in New Caledonia. They could not be assessed regarding maximal allowed daily dose and duration of usage due to lack of general re-commendations or restrictions in the Pacific region. Toxic liver injury may occur following treatment of 1–4 months and daily doses of 120–200 mg kavalactones (ethanolic and acetonic kava extracts, herbs-kava mixtures) or after 1–2 months and a daily dose of 120 mg and 2.6 g kavalactones (aqueous kava extract).

Hepatotoxicity was observed with all extraction media (Tables 1 and 2), supporting the view of poor quality of the kava raw material as contributory factor.15,16,20,21,30,65 Comedication was described in nine of 14 patients (cases 1,13,16,19,20,23, 29–30,31). Therefore, confounding variables such as daily overdose, prolonged treatment, comedication, and poor kava quality have to be considered in the context of specific causality assignment.14–23,30,65,66

In ten out of the 14 patients, hepatotoxicity showed restoration after kava and drug cessation with a good clinical outcome (cases 1, 12, 13, 15, 16, 19, 23, 27, 28, 30, 31; Tables 1 and 2).15,16 Three other patients (cases 20,21,30) required liver transplant (LTX) and survived, whereas a lethal course after LTX was described for another patient (case 29). The former patient (case 20) had a daily overdose of kavalactones, increased length of kava therapy, high cumulative dose of kavalactones, and comedication with probable causality for both kava and comedication; the second patient (case 21) had a daily overdose of kavalactones and an increased cumulative dose of kavalactones with a possible causality for kava; the third patient (case 30) used a herbs-kava mixture and comedication with ibuprofen, had a daily overdose and an increased cumulative dose of kavalactones as well as a prolonged treatment, and was coded with a possible causality for both kava and comedication; and the fourth patient (case 29) used a herbs-kava mixture, had a daily overdose and increased cumulative dose of kavalactones, and causality assessment was probable for kava and possible for comedication, but as alternative diagnosis genuine AIH has to be considered in this particular patient who experienced a lethal outcome in the course of LTX.

In one of the 14 patients, a positive reexposure test has been reported 3 months after the end of an initial treatment with an oral contraceptive, paroxetine, St. John’s Wort, and an ethanolic kava extract (60 mg kavalactones/d) of 6 months duration (case 19, Table 1)13 and thereby twice as long as recommended by the regulators.33 Despite these shortcomings, this case reached a highly probable causality for kava upon quantitative, structured and hepatotoxiity specific causality assessment.15 The positive reexposure test in this particular case clearly shows that kava has the potency of hepatotoxicity, and this is commonly acknowledged.14,16–21 This highly probable causality for kava in one single patient (case 19, Table 1) in connection with a probable causality for kava ± co-medication in four other patients (cases 12,20,28,29) (Tables 1 and 2) creates concern on clinical grounds and pharmacovigilance considerations. On the other hand, in nine out of 14 cases and thereby in the majority of patients (cases 1,13,15,16,21,23,27,30,31) (Tables 1 and 2), causality of hepatotoxicity for kava ± comedication was graded as only possible and thus weak (Table 2).

The present results of kava hepatotoxicity (Table 3) are in line with characteristics described for cases of liver injury induced by chemical drugs and dietary supplements, including herbal ones.1–6,42 Should kava as a drug return to the market, certain measures are requisite. There is an urgent need to adhere to treatment recommendations including regulatory indication, to avoid comedication, and to implement standards for good kava quality.

Herbal hepatotoxicity by the use of aqueous, ethanolic and acetonic kava extracts and herbs-kava mixtures was verified in a few patients in connection with overdose, prolonged treatment and come-dication, most probably also as a consequence of poor quality of the kava raw material contained in a few kava extracts. To minimize hepatotoxic risks due to kava use, efforts have to be undertaken to improve treatment modalities and to implement kava quality standards.

• •

  AIH: Autoimmune hepatitis.

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  ALP: Alkaline phosphatase.

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  ALT: Alanine aminotransferase.

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  AMA: Antimitochondrial antibodies.

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  ANA: Antinuclear antibodies.

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  BfArM: Bundesinstitut für Arzneimittel und Medizinprodukte (German regulatory health agency).

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  BMI: Body mass index.

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  CD: Comedicated drug(s).

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  CIOMS: Council for International Organizations of Medical Sciences.

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  CMV: Cytomegalovirus.

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  EBV: Epstein Barr virus.

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  γGT: γ-glutamyltranspeptidase.

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  HAV: Hepatitis A virus.

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  HBV: Hepatitis B virus.

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  HCV: Hepatitis C virus.

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  HEV: Hepatitis E virus.

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  HIV: Human immunodeficiency virus.

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  HSV: Herpes simplex virus.

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  IKS: Interkantonale Kontrollstelle Schweiz (Swiss regulatory agency).

• •

  IgM: Immunglobulin M.

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  IgG: Immunglobulin G.

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  LKM: Liver kidney microsomal antibodies.

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  LTX: Liver transplantation.

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  MCV:;Median cell volume.

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  p-ANCA: Perinuclear antineutrophil cytoplasmic antibodies.

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  PBC: Primary biliary cirrhosis.

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  SLA: Soluble liver antigen.

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  SMA: Smooth muscle antibodies.

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  VZV: Varicella zoster virus.