Key words
valproic acid - hepatotoxicity - liver failure - pharmacovigilance
Introduction
Valproic acid (VPA, 2-propylvaleric acid) was first synthesised as an organic solvent
by the US chemist Burton in 1881. Its anticonvulsant properties were recognised incidentally
in seizure experiments with VPA as a vehicle [1]. VPA was first released in France in 1967 and has been approved by the US Food and
Drug Administration for treatment of epilepsy, bipolar affective disorder [2] and migraine and cluster headaches [3]. Potentiation of GABA-ergic transmission by inhibition of GABA transaminase [4], direct effects on potassium channels [5], and attenuation of NMDA-receptor-mediated neural excitation [6] have all been assumed to play a role in the neurochemical activity of VPA, whereas
the mood-stabilising function appears to be related to cellular inositol depletion.
VPA is considered to be safe when administered according to the well-established therapeutic
serum drug level. Nonetheless, Sztajnkrycer described 373 cases of major toxicity
and 16 deaths in the USA in the year 2000 after intentional and unintentional overdose
(acute VPA intoxications) [7].
Within the normal dose range, VPA is often clinically administered in combination
with other antiepileptic drugs, antidepressants or antipsychotics. Side effects typically
evolve acutely, and most frequently observed side effects include fatigue, nausea,
vomiting, haemorrhages, seizures, and ataxia. Liver failure, bleeding, and pancreatitis
represent rare but life-threatening adverse events [8]
[9]. The severity of hepatotoxicity can range from reversible hepatic dysfunction to
irreversible liver failure [10]. Reports of fatal liver failure related to VPA monotherapy are anecdotal, and systematic
analyses of these complications are scarce. Large pharmacovigilance studies specifically
addressing VPA-associated hepatotoxicity with both fatal and non-fatal outcome covering
children and adults are lacking. Bryant and Dreifuss focussed on VPA-associated fatalities
in the U.S.A. and reported 29 deaths identified between 1987 and 1993 [11]. Koenig and co-workers performed a questionnaire-based study and reported 31 non-fatal
and 9 fatal cases of VPA-associated hepatotoxicity in Germany between 1994 and 2003
[8]. There is only one large pharmacovigilance study that investigated drug-induced
hepatic injury in children between 12 and 17 years of age [12].
We set out to study the frequency and risk factors of VPA-associated liver failure
in a first pharmacovigilance study using data from the German federal authority, irrespective
of VPA indication. We sought to determine the roles of the absence or presence of
co-medications, gender and age.
Methods
To investigate VPA-associated liver failure, we analysed all reported cases of VPA-associated
hepatopathy and liver failure in Germany that had been submitted to the responsible
federal authority, the German Federal Institute for Drugs and Medical Devices (Bundesinstitut
für Arzneimittel und Medizinprodukte [BfArM], UAW Datenbank, Germany), between 1993
and 2009. BfArM is responsible for the surveillance of risks due to medical products
in Germany. Among other functions, BfArM records spontaneous reports about serious
adverse events from clinicians and gains information through systematic studies of
published reports from Germany. Each BfArM report is documented in a separate standard
form filled out by the reporting clinician. Each case report about VPA-associated
liver failure includes age, gender, co-medication, and outcome (fatal vs. non-fatal).
Admittance to the data base of cases with VPA-associated hepatotoxicity requires causality
classified by BfArM as either “suspected” or “possible”. Cases in which a causal relationship
between liver failure and VPA use was regarded unlikely were not evaluated because
they are not recorded by the BfArM.
The cases were analysed irrespective of the indication for administration of VPA or
diagnosis and they were studied systematically, regardless of whether they occurred
with VPA monotherapy or under a regime of VPA plus comedication. In addition, the
correlation between occurrence of VPA-associated hepatotoxicity and gender or age
was assessed. In a second step we evaluated the subgroup of fatal VPA-associated liver
failures among all cases of VPA-induced hepatotoxicity. We calculated the relative
association (percentage) of VPA-associated liver failure for each substance used as
a comedication with VPA to establish a rank order of risk for the entire set of cases
and for the subgroup of fatal cases. Additionally, case-fatality rates were determined
within the medication groups.
Finally, we evaluated the number of reported cases of VPA-associated liver failure
between 1993 and 2009 and divided the results in 4 time periods (1993–1997, 1998–2001,
2002–2005, and 2006–2009) for all cases and for the fatal cases. The frequencies of
reported cases across these 4 time intervals were compared with the chi2 test assuming an equal distribution over time. Furthermore, the association between
gender and outcome (non-fatal vs. fatal) was tested for significance using the chi2 test. Age differences between the 2 outcome groups were tested with the the Mann-Whitney
U test.
Results
A total of 132 cases of serious hepatic adverse effects associated with application
of VPA were reported to the German federal authority (BfArM) between 1993 and 2009
([Table 1], left column); of these, 34 cases had a fatal outcome and this subgroup is further
described below ([Table 1], right column).
Table 1 All 132 cases of VPA-induced hepatic side effects and the sub-group of 34 fatalities
(right column).
|
Co-medication
|
Total group (N=132)
|
Sub-group with fatal outcome (N=34)
|
|
Multiple mentioning of listed medications allowed; nota bene: * reported percentages
in the sub-group with fatal outcome (right column) are based on the total number of
cases treated with the respective medication (as given in the left column)
|
|
Other co-medications reported in 3 cases or less: β-receptor antagonists, ACE inhibitors,
angiotensin antagonists, aldosteron antagonists, corticosteroids, calcium antagonists,
nitrates, oral anticoagulants, statins, thyroxine, acetylsalicylic acid, clopidogrel,
anti-arrhythmics, biperiden, metoclopramide, levodopa, Iprazochrome, virostatics,
alendronate, opioids, and muscle relaxants
|
|
none (VPA only)
|
46 (34.8%)
|
11 (23.9%*)
|
|
yes (VPA plus …)
|
86 (65.2%)
|
23 (26.7%*)
|
|
– antiepileptics
|
46 (34.8%)
|
11 (23.9%*)
|
|
topiramate
|
13 (9.8%)
|
3 (23.1%*)
|
|
carbamazepine
|
11 (8.3%)
|
5 (45.5%*)
|
|
lamotrigine
|
10 (7.6%)
|
2 (20%*)
|
|
ethosuximide
|
7 (5.3%)
|
0 (0%*)
|
|
oxcarbazepine
|
6 (4.5%)
|
0 (0%*)
|
|
phenytoin
|
5 (3.8%)
|
2 (40%*)
|
|
– benzodiazepines
|
22 (16.7%)
|
8 (36%*)
|
|
– antipsychotics
|
9 (6.8%)
|
3 (30%*)
|
|
– diuretics
|
8 (6.0%)
|
5 (63%*)
|
|
– antidepressants
|
7 (5.3%)
|
2 (29%*)
|
|
– antibiotics
|
6 (4.5%)
|
3 (50%*)
|
|
– NSAID
|
5 (3.8%)
|
3 (60%*)
|
|
– proton pump inh.
|
5 (3.8%)
|
1 (20%*)
|
|
– other hypnotics
|
4 (3.0%)
|
2 (50%*)
|
|
– heparin
|
3 (2.3%)
|
2 (67%*)
|
|
– propofol
|
2 (1.5%)
|
2 (100%*)
|
The total sample of 132 cases consisted of 76 female and 54 male (gender not reported
for 2) patients, resulting in a female-to-male ratio of 1.41–1. The median of age
was 16.0 years (range 10 months to 86 years; age not reported for 11).
In 46 of the 132 cases, hepatic adverse effects were reported to have occurred under
VPA monotherapy (34.8%), while in the majority of the reported cases, VPA was administered
with other comedication (86 of 132=65.2%).
Comedications grouped by substance classes are provided in [Table 1] (left column). They came from a wide range of substance groups. In descending order,
they were antiepileptics (34.8%), benzodiazepines (16.7%), antipsychotics (6.8%),
antidepressants (5.3%), diuretics (6%), antibiotics (4.5%), proton pump inhibitors
(3.8%), non-steroidal anti-inflammatory drugs (NSAID) (3.8%), hypnotics (3%), heparin
(2.3%) and propofol (1.5%). Among all licensed antiepileptics, topiramate, carbamazepine,
lamotrigine, and ethosuximide showed the highest number of serious hepatic adverse
effects with additional VPA medication.
Sub-group with fatal liver failure
34 out of the 132 patients with VPA-associated liver failure deceased during the further
course, representing a fatality rate of 25.8% ([Table 1], right column and [Table 2] for further clinical details). Of these, eleven (32.4% of all 34 fatal cases) were
treated with VPA monotherapy, while the remaining 23 (67.6% of all 34 fatal cases)
were treated with VPA and various comedications (see [Table 1] right column for details). The relative number of fatal cases was similar in patients
with mono-therapy (11 out of 46=23.9%) or with combined medications (23 out of 86=26.7%).
A disproportionally high rate of fatal outcomes was found for propofol (2 out of 2=100%),
heparin (2 out of 3=66.7%), diuretics (5 out of 8=62.5%), antibiotics (3 out of 6=50%),
carbamazepine (5 out of 11=45.5%), and phenytoin (2 out of 5=40%) ([Table 1]).
Table 2 Subgroup of 34 fatal cases of VPA-associated liver failure.
|
N
|
Gen
|
Age
|
Indication for VPA
|
Concomitant illnesses
|
VPA since
|
Hepatic risk factors
|
Comedication
|
|
Gen=Gender; f=female; m=male; NR=not reported; y=years; mo=months; we=week; Epi=epilepsy;
F-Epi=focal epilepsy; S-Epi=status epilepticus; nos=not otherwise specified; int over=intentional
overdose
|
|
1
|
f
|
21 y
|
F-Epi
|
borrelia encephalitis
|
3 mo
|
no
|
clobazam, chloralhydrate, PHE, metoclopramide
|
|
2
|
f
|
1 y
|
Epi nos
|
acute virus infection
|
8 mo
|
no
|
aspirine, paracetamol, diazepam (after seizure)
|
|
3
|
m
|
23 y
|
F-Epi
|
status post meningoencephalitis
|
4 we
|
no
|
CBZ, phenobarbital, furosemide, vitamine k
|
|
4
|
f
|
75 y
|
Epi (first episode)
|
psychotic depression, hepatitis A
|
5 we
|
no
|
dibenzepin, melperon
|
|
5
|
m
|
36 y
|
F-Epi
|
infantile brain damage after meningitis, acute pneumonia
|
>30 y
|
liver cirrhosis
|
CBZ, acute: penicillin, aminoglycoside, cephalosporine
|
|
6
|
m
|
86 y
|
F-Epi
|
cerebral infarct, urosepsis
|
6 days
|
no
|
clonazepam, L-Dopa, omeprazole, clopidogrel, furosemide, ciprofloxacine, diclofenac,
heparin
|
|
7
|
f
|
24 y
|
grand mal Epi
|
mental retardation
|
>y
|
NR
|
lamotrigine (2 we before death), aspirine, primidon, amoxicillin, clindamycin, metamizol,
paracetamol, metoclopramide, dimenhydrinat, etilefrine
|
|
8
|
m
|
73 y
|
S-Epi
|
bladder neoplasm, cerebral metastasis, cerebral infarct
|
7 days
|
no
|
diazepam, zolpidem, certoparin
|
|
9
|
f
|
9 y
|
grand mal Epi
|
mental retardation
|
3 mo
|
no
|
topiramate
|
|
10
|
f
|
49 y
|
F-Epi
|
traumatic intracerebral haematoma
|
1 y
|
no
|
lamotrigine (3 we before death)
|
|
11
|
f
|
25 y
|
S-Epi
|
NR
|
NR
|
NR
|
nos
|
|
12
|
m
|
NR
|
cluster headache
|
NR
|
int over
|
NR
|
nos
|
|
13
|
m
|
NR
|
NR
|
metabolic encephalopathy
|
NR
|
NR
|
nos
|
|
14
|
m
|
11 y
|
Epi nos
|
von Willebrands disease
|
NR
|
no
|
nos
|
|
15
|
f
|
10 y
|
absence Epi
|
von Willebrands disease, mental retardation, pancreatitis
|
NR
|
no
|
topiramate
|
|
16
|
m
|
54 y
|
Epi nos
|
perinatal hypoxic brain damage, acute pneumonia
|
20 y
|
no
|
isosorbide dinitrate, hydrochorothiazide, triamteren, thyroxine
|
|
17
|
f
|
14mo
|
recurrent S-Epi
|
developmental delay
|
NR
|
no
|
diazepam
|
|
18
|
m
|
6 y
|
myoclonic Epi, S-Epi
|
mental retardation, acute pneumonia
|
2 mo
|
no
|
phenobarbital (hypnotic), propofole
|
|
19
|
f
|
28 y
|
myoclonic Epi, S-Epi
|
MERRF
|
1 mo
|
no
|
nos
|
|
20
|
m
|
11 y
|
idiopath. generalized Epi
|
no
|
6 mo
|
hepatitis A
|
nos
|
|
21
|
f
|
21 y
|
symptomatic Epi
|
post infectious encephalitis
|
3 mo
|
no
|
CBZ, Clonazepam, PHE
|
|
22
|
m
|
12 y
|
symptomatic Epi, S-Epi
|
mental retardation
|
NR
|
hepatitis A
|
propofole
|
|
23
|
m
|
23 y
|
symptomatic Epi
|
post meningoencephalitis, mental retardation
|
1 mo
|
no
|
CBZ
|
|
24
|
m
|
30 y
|
Epi nos
|
no
|
NR
|
no
|
nos
|
|
25
|
m
|
29 y
|
F-Epi
|
mental retardation, Friedreichs Ataxia
|
2 mo
|
no
|
CBZ
|
|
26
|
f
|
10 y
|
pseudo Lennox Gastaut
|
mental retardation
|
3 mo
|
no
|
topiramate
|
|
27
|
m
|
54 y
|
symptomatic Epi
|
perinatal hypoxic brain damage, femur fracture operation
|
21 y
|
no
|
isoflurane, thiopental, triamteren, hydrochlorothiazide, thyroxine, isosorbide dinitrate
|
|
28
|
f
|
17 y
|
myoclonic Epi
|
Alpers disease
|
NR
|
NR
|
nos
|
|
29
|
f
|
10 y
|
myoclonic Epi
|
Alpers disease
|
NR
|
NR
|
nos
|
|
30
|
m
|
17 y
|
myoclonic Epi
|
Alpers disease
|
NR
|
NR
|
nos
|
|
31
|
m
|
8 y
|
S-Epi
|
NR
|
NR
|
NR
|
nos
|
|
32
|
f
|
52 y
|
impulse control disorder
|
schizophrenia, reduced intelligence
|
3 mo
|
no
|
thioridazine, levomepromazine
|
|
33
|
f
|
10 mo
|
S-Epi
|
Alpers disease
|
12 we
|
no
|
midazolam
|
|
34
|
f
|
58 y
|
bipolar depression
|
hypertonia
|
19 days
|
NR
|
duloxetine, risperidon, candesartan, lorazepam
|
In contrast to a preponderance of female patients in the total number of cases, no
differences in the number of fatal cases were found for men and women (17 vs. 17).
However, the association between gender and outcome (fatal vs. non-fatal) was not
statistically significant (chi2=1.36, df=1, p=0.244). Regarding age, there was no overall significant difference
between the groups (fatal and non-fatal liver failure) (z= − 1.61, p=0.106) (age not
reported for 2 of the fatal cases). When inspecting the age distribution of the 2
groups ([Fig. 1]), there seemed to be an increased occurrence of serious hepatic side effects in
children under 11 (0–10) years while the number of fatalities seemed equally distributed.
An exploratory post hoc test of significance revealed that children under 11 have
a lower risk of fatality (9 out of 54=17%) as compared to patients with higher age
(23 out of 67=34%) (chi2=4.79, df=1, p=0.029).
Fig. 1 Age distribution for cases with severe hepatic side effects (non-fatal) and for cases
with fatal liver failure.
Frequency of reported liver failure cases (1993–2009)
The number of reported cases of VPA-associated liver failure between 1993 and 2009
was evaluated. Therefore, all cases and fatal cases were subdivided according to the
date of report in 4 time periods: 1993–1997, 1998–2001, 2002–2005, and 2006–2009.
There were 14 reports from 1993 to 1997, 12 reports from 1998 to 2001, 29 reports
from 2002 to 2005, and 111 reports from 2006 to 2009. 4 fatal cases were reported
between 1993 and 1997, 2 from 1998 to 2001, 6 from 2002 to 2005, and 22 cases from
2006 to 2009. The chi2 test indicated a significant increase in both, in all cases (chi2=159.3, df=3, p<0.001) and the subgroup of the fatal cases (chi2=29.5, df=3, p<0.001).
Discussion
This is the first pharmacovigilance study that evaluated all cases of VPA-associated
liver failure with fatal or non-fatal outcome irrespective of the indication of VPA
covering all ages (children and adults). Within a total sample of 132 cases of VPA-associated
liver failure 34 fatalities occurred, representing the largest published sample of
fatal liver failure to date [11]. As compared with available studies, our pharmacovigilance study based on reported
data to the German federal authority between 1993 and 2009 has a comparatively long
observation period of 17 years (e. g., 7 years in [11]).
Considering the total number of cases with serious hepatic adverse effects a preponderance
of female patients was observed resulting in a female-to-male ratio of 1.41–1. Regarding
comedication, one third of the hepatic adverse effects were reported to have occurred
under VPA monotherapy, while in the majority of the reported cases, VPA was administered
with other comedication, most frequently substances with extensive hepatic metabolism
such as antiepileptics, benzodiazepines, antipsychotics, diuretics, antidepressants
and antibiotics. Approximately one quarter of patients who developed serious hepatic
adverse effects due to VPA-treatment deceased in the further course (fatal VPA-associated
hepatotoxicity). This observation showed no statistically significant difference regarding
gender and age of affected patients. While children under the 11 years of age seem
to be particularly at risk for developing any serious hepatic AE related to VPA this
age group might feature a lower risk of fatal liver failure. Of the reported fatal
cases one third were treated with VPA monotherapy, while two thirds received comedication
in addition to VPA. The relative number of fatal cases was similar in patients with
monotherapy or with combined medications (about a quarter).
To put our results in a larger perspective, Binek and colleagues estimated a risk
of 1:5 000 to 1:10 000 of fatal liver failure with VPA in adults [13]. Dreifuss et al. found this risk to be approximately 1 in 37 000 in adults with
VPA monotherapy [14]; as for children between 0 and 2 years old receiving valproate as polytherapy, they
found a much higher risk of fatalities (1 out of 500 cases). A particularly high risk
for fatal hepatotoxicity under VPA was described for patients on additional antiepileptic
drugs, with congenital metabolic disorders, with severe epileptic seizures in mental
retardation or children, especially those under the age of 2 years (Box Warning [15]). Thus, the risk of VPA-induced hepatotoxicity in adults without these additional
risk factors was thought to be definitely lower. This is in contrast with the study
by Koenig et al. who counted 9 fatalities resulting from VPA-induced hepatopathy in
Germany from 1994 to 2003 from questionnaires sent to all members of the German section
of the League against Epilepsy [8]. They found that 5 out of 9 reported fatalities occurred in adults and 3 out of
9 patients had VPA monotherapy. Hence, this study was not in line with the generally
accepted concept that VPA-induced hepatopathy occurs only in children or adults with
risk factors such as polypharmacy [11]. Bauer et al. even reported a case of fatal fulminant liver failure under VPA monotherapy
in a patient with bipolar affective disorder without any comorbidity [16].
The present study supports the view that VPA hepatotoxicity is not restricted to specific
risk constellations except for age and comedication. We found a slightly higher occurrence
of non-fatal hepatic injury in children younger than 11 years while the risk of a
fatal outcome was about 2 times lower than in older patients. Otherwise no effect
of age was observed. The majority of VPA-induced liver failure occurs in patients
with VPA plus comedication. This finding is consistent with the earlier assumption
that polypharmacy is still an important factor in VPA-induced hepatotoxicity. If comedication
was present, substances that are extensively metabolised in the liver were found to
be common (see [Table 1] for details), so that in the presence of such substances liver function should be
monitored even closer than in VPA monotherapy. The observed increase of registered
cases of serious and fatal hepatic side effects over time might be explained by either
changes in prescription practise or increased reporting to the BfArM pharmacovigilance
data base.
We are aware of some limitations of our study. As a pharmacovigilance study, it is
retrospective and fully depends on the physicians’ reporting discipline (leaving room
for an unknown number of unreported cases) as well as the quality of the data provided.
We cannot explain whether the observed increase in the occurrence of VPA-associated
liver failure depends on a better reporting practice or the increased use of VPA in
general. Further, it appears to be possible that comedication was not reported in
every case, leading to an overestimation of hepatotoxicity in VPA monotherapy. Our
study does not allow for drawing either general causality conclusions or aetiological
considerations about VPA-related fatalities and fully relies on the factors reported
to the federal authority such as age, gender and comedication. We cannot provide any
information regarding the time interval between onset of VPA treatment and the development
of liver failure because the BfArM data base does not contain usable information for
this important question. In addition, our German data cannot be generalised for other
countries. Thus, similar studies in other countries would be desirable.
Across countries the recommended laboratory function tests before and after starting
VPA therapy differ significantly. In Germany, the summary of product characteristics
recommends several baseline tests (coagulation parameters including fibrinogen, total
protein, whole blood cell count, bilirubin, transaminases, gamma-glutamyl-transferase,
lipase and amylase, and serum glucose) and monthly clinical and laboratory controls
(transaminases, bilirubin, coagulation parameters and amylase) for half a year; in
case of pathologies after 4 weeks, 3 further controls with a maximum delay of 2 weeks
each and subsequent monthly controls until 6 months after initiating VPA treatment
should be performed [17]. In children, additional safety measures are recommended (laboratory controls at
every second clinical appointment and parent education about signs of liver dysfunction)
[17]. For the United States, the manufacturer recommends that “liver function tests should
be performed prior to therapy and at frequent intervals thereafter, especially during
the first 6 months” (without providing details about the tests and the intervals)
[15]. Some authors highlighted that severe VPA-associated hepatotoxicity usually manifests
within the first 90 days after treatment initiation [18] and thus, in addition to above-mentioned controls recommended by the manufacturers
particular attention to clinical and laboratory signs of liver dysfunction should
be paid for the first 3 months.
Management of VPA-associated hepatoxicity is largely supportive, and the prognosis
for patients with acute liver failure due to idiosyncratic drug reactions is poor,
with a 60–80% mortality rate without liver transplantation [19]. In 2001, Bohan et al. proposed the intravenous use of carnitine because carnitine
deficiency, either as a pre-existing condition or induced by VPA therapy, appears
to promote VPA-induced liver failure [20]. Carnitine is well tolerated and has been shown to reduce fatal outcomes if supplementation
therapy was initiated early in severe VPA-induced hepatic dysfunction, especially
in children [9]
[21]
[22]. However, further investigation is needed to evaluate its clinical value and the
appropriate dosage.
Conclusion
Our study indicates a higher rate of both non-fatal and fatal liver failure associated
with VPA plus comedication as compared to VPA monotherapy. However, comedication per
se does not increase the risk of fatalities, but is reported in the majority of non-fatal
and fatal cases. Particular attention to liver function should be paid when co-medications
with extensive hepatic breakdown, e. g.. other antiepileptics (topiramate, carbamazepine,
or lamotrigine in particular), benzodiazepines and antipsychotics, are used with VPA.
Some comedications such as propofol or heparin appear to have a disproportionally
high risk of fatal liver failure when used with VPA.
Considering the growing number of reported cases of VPA-induced hepatic failure greater
focus on the early detection of VPA-related hepatotoxicity is warranted. From a patient’s
perspective, detailed knowledge of possible VPA side effects is indispensable and
patients need sufficient information about early clinical signs. While patients on
VPA should be instructed to immediately seek medical help if gastrointestinal symptoms,
general weakness, gait ataxia, or elevated temperature occur, future advances in proteomics,
metabonomics and genomics will hopefully pave the way to personalised medications
in which the beneficial effect of VPA is maximised and its toxicity minimised.
