Computed Tomography of the Brain, Hepatotoxic Drugs and High Alcohol Consumption in Male Alcoholic P


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Upsala Journal of Medical Sciences

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Computed Tomography of the Brain, Hepatotoxic
Drugs and High Alcohol Consumption in Male
Alcoholic Patients and a Random Sample from the
General Male Population

Sture Mützell

To cite this article: Sture Mützell (1992) Computed Tomography of the Brain, Hepatotoxic
Drugs and High Alcohol Consumption in Male Alcoholic Patients and a Random Sample
from the General Male Population, Upsala Journal of Medical Sciences, 97:2, 183-194, DOI:
10.3109/03009739209179295

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Upsala J Med Sci 97: 183-194 

Computed Tomography of the Brain, Hepatotoxic Drugs 
and High Alcohol Consumption in Male Alcoholic 
Patients and a Random Sample from the General 

Male Population 
Sture Miitzell 

Department of Family Medicine, University Hospital of Uppsala, Uppsala, Sweden 

ABSTRACT 

Computed tomography (CT) of the brain was performed in a random sample of a total of 195 men 
and 21 1 male alcoholic patients admitted for the first time during a period of two years from the 
same geographically limited area of Greater Stockholm as the sample. The same medical, social and 
neuroradiological methods were used for examination of the alcoholic inpatients as for the random 
controls. Laboratory tests were performed, including liver and pancreatic tests. Toxicological 
screening was performed and the consumption of hepatotoxic drugs was also investigated and the 
following were the types of drugs used: antiarrhythmics, antiepileptics, antiphlogistics, mixed 
analgesics, barbiturates, sulphonamides, benzodiazepines, clomethiazole and phenothiazine 
derivatives, all of which are metabolised by the liver. The group of male alcoholic inpatients and the 
random sample were then subdivided with respect to alcohol consumption and use of hepatotoxic 
drugs: Group IA, men from the random sample with low or moderate alcohol consumption and no 
use of hepatotoxic drugs; IB, men from the random sample with low or moderate alcohol 
consumption with use of hepatotoxic drugs; IIA, alcoholic inpatients with use of alcohol and no 
drugs; and IIB, alcoholic inpatients with use of alcohol and drugs. 

Group IIB was found to have a higher incidence of cortical and subcortical changes than group 
IA. Group IB had a higher incidence of subcortical changes than group IA, and they differed only 
in drug use. Groups IIB and IIA only differed in drug use, and IIB had a higher incidence of brain 
damage except for anterior horn index and wide cerebellar sulci indicating vennian atrophy. 

Significantly higher serum (S) levels of bilirubin, gamma-glutamyl transpeptidase (GGT), 
aspartate aminotransferase (ASAT), alanine amino-transferase (ALAT), creatine kinase (CK), 
lactate dehydrogenase (LD) and amylase were found in IIB. 

The results indicate that drug use influences the incidence of cortical and subcortical aberrations, 
except anterior horn index. It is concluded that the groups with alcohol abuse who used hepatotoxic 
drugs showed a picture of cortical changes (wide transport sulci and clear-cut or high-grade cortical 
changes) and also of subcortical aberrations, expressed as an increased widening of the thud 
ventricle. 

183 



INTRODUCTION 

In recent years, there have been a large number of computed tomography (CT) studies (2-4,7- 
9,12,13,15,17,19,23,25-27,29,31) of the morphological changes in the alcoholic brain. In these 
reports, the criteria for diagnosing alcoholism have varied widely. Some researchers have focused 
on heavy social drinkers (3,7-9) and there are reports based on Zimberg’ s scale (23), the criteria 
of the National Council on Alcoholism (17), or special diagnostic criteria which were quantitatively 
determined, one, for example, being an intake of more than 50 g of ethanol per day (19). Others 
have excluded cases of delirium tremens, withdrawal seizure or Korsakoff‘ s syndrome from their 
studies (7,8). Background factors, including sex , age, duration of alcohol drinking or 
complications, also vary from report to report; only male patients were studied in some reports (2- 
4,19,29) while a few females were included in others (7-9,12,13,23,27). The criteria for 
exclusion of complications such as epilepsy, drug dependence other than alcoholism, head injury, 
intracranial hematoma, severe liver dysfunction and hepatocerebral syndrome differ among the 
reports. 

Some authors have tried to assess the cerebral morphological status among persons without 
alcohol problems by comparison with various control groups. However, it is clear from the 
selection criteria of the groups that they cannot be considered representative of a general population. 

controls but smaller than those of alcoholics (18). In a 6-year follow-up of 50 patients with primary 
dependence on sedative and hypnotic drugs, 26 patients (52%) were abusing drugs andfor alcohol 
at the time of follow-up. CT of the brain was performed in 33 of these 50 patients, and in 17 
patients, 10 of whom were currently abusing drugs, there were indications of cortical atrophy (1). 
Rumbaugh et al. (30) reported on 6 drug abusers with dilatation of the ventricles and subarachnoid 
spaces, suggesting that cerebral atrophy can be related to drug abuse. 

Caballeria et al. (6) found that systemic effects of alcohol may be exacerbated in patients receiving 
cimetidine and Leo et al. (20) found that hepatic cytosolic retinal dehydrogenase activity was 
increased 8-fold after phenobarbitone and ethanol administration, but no extrahepatic induction was 
observed. 

The purpose of the present interdisciplinary study was to compare a random sample of men from 
the general population with alcoholic inpatients with regard not only to the incidence and location 
of morphological cerebral changes but also to the laboratory findings in relation to drinking habits 
and to the use of hepatotoxic drugs in combination with alcohol intake. 

populations. 

Benzodiazepine users, as a group, have been found to have larger ventriclebrain ratios than 

A special feature of this study is that the same instrument has been applied in different 

184 



MATERIAL AND METHODS 

The study comprised a sample from the general population and alcoholic inpatients consisting of 
men living in the catchment area of the Karolinska Hospital, a geographically limited area in the 
northern part of Stockholm (Solna and Sundbyberg) with about 80,000 inhabitants. The sample 
was drawn randomly from the National Register covering all Swedish inhabitants. The sample was 
stratified with regard to age and it was intended that a sample of 200 men should be drawn, with 
40 in each of the age-groups 20-29,30-39,40-49,50-59 and 60-65 years, in order to achieve the 
same degree of precision for all age-groups in the estimation of different variables. 

The initial random sample drawn consisted of 209 men aged 20-65 years. Of this sample, 2 
persons had died, 5 had moved more than 20 miles away from Stockholm, and 10 were living 
permanently abroad at the time of investigation and were thus excluded from the study. Nine 
persons refused to be examined and 2 refused to take part in the CT investigations. Thus, of the 
initial sample of 209 men, 181 were available for investigation. To increase the sample to 200, a 
supplementary sample of 19 men was drawn in exactly the same way as before, and all these men 
were available for investigation. The non-participant group was small and the drop-outs (1 1 %) did 
not differ from the examined persons with respect to social status, age, education, civil status, 
employment status or data from official registers (pS.05). Five men refused to undergo CT 
examination of the brain, and CT scans for a total of 195 men were therefore available. 

The patient group comprised 21 1 men consecutively admitted to the Magnus Huss Clinic for 
alcohol diseases at the Karolinska Hospital. All were born on an uneven date and were staying at 
the clinic for at least one week for voluntary treatment. All alcoholic patients admitted for the first 
time during a period of 2 years from the same geographically limited area as the sample were 
investigated. The same medical, social and neuroradiological methods were used for examination 
of the 21 1 alcoholic inpatients as for the 195 random controls. Laboratory tests were performed, 
including liver and pancreatic tests. Blood samples were drawn in the morning after an overnight 
fast in the random sample and in the alcoholic inpatient group. Toxicological screening with the 
following assays was performed: serum concentrations of barbiturates, other sedatives and alcohol 
and urinary concentrations of meprobamate, benzodiazepines, alkaloids, phenothiazines, tricyclic 
antidepressants, amines stimulating the nervous system and salicylic acid. The amount of alcohol 
consumed, indications of alcohol dependence and alcohol-related complications were thoroughly 
assessed by means of a standardised procedure combining a self-administered questionnaire and a 
check-up interview. Two measures of alcohol consumption were used - the amount of alcohol 
consumed in the previous week in grams of absolute alcohol per day and the typical peak 
consumption in the last six months in grams of pure alcohol per day. The consumption in the last 
week was recorded, as it was considered that the subjects’ recall would be poorer for the period 
further back in time. 

The drug consumption case history is composed of two parts. The first part focuses on drugs 
consumed during the last 24 months before admission and all prescription for the patient, data on 
type of drug and prescribing doctor. Drugs are coded in accordance with the Swedish 

185 



pharmacological register (FASS). The second part consists of a pedicine chart/questionnaire with 
special emphasis on psychotropic and addictive drugs, and the consumption of hepatotoxic drugs 
was also investigated. The following were the types of drugs used: antiarrhythmic agents, 
antiepileptic agents, antiphlogistics, mixed analgesics, barbiturates, benzodiazepines, phenothiazine 
derivatives, sulphamethizole and sulphamethoxypyridazine derivatives and clomethiazole, all of 
which are metabolised by the liver (Table 1). This latter part of the drug consumption history is 
designed for the patient’s own completion. Patients are asked to record the drugs which they are 
either using at present o r  have used during the last 24 months. Altogether 180 different drugs are 
itemised. 

Table 1. Use of hepatototoxic drugs combined with alcohol consumption in the two groups IB and 
IIB. Pharmacological groups and the doses of each drug in grams per day (g/d) after the 
generic name. Minimum time of drug consumption in months for each drug group. 

Pharmacological Group IB: Random sample Group IIB: Alcoholic 
groups and h e  doses 
in g/d Duration of drug Duration of drug 

consumption in consumption in 

Low alcohol + druos inuatients + drugs 

(n=31) months (n-) months 

Antiarhytmic drugs 
quinidine bisulph. 0.4; 
verapamil hydmchlor. 0.32 

Antiepileptics 
Phenytoin sod. 0.4 

Antiphlogistics 
ibuprofen 1.2 

Mixed analgesics 
Dolerone 2 tabletdday 

Barbiturates 
amylobarbitone 0.2; 
hexapropymate 0.4 

nitrazepam 0.01; 
diazepam 0.02; 
chlordiazepxide 0.03; 
oxazepam 0.03 

Phenothiazine derivatives 
promethazine 0.05; 
chlorprothixene 0.05; 
alimemazine 0.08 

Sulphamethizole 0.4 g, 
sulphamethoxypyridazine 0.1 g 

Clomethiazole 

Benzodiazepines 

Sulfapral4 tablets/day 

Hemineurin 0.9 

24 

24 

24 

24 

24 

24 

24 

1 

0 

1 24 

0 0 

0 0 

4 24 

10 24 

10 24 

8 24 

0 0 

7 6 

N 31 40 

186 



The validity of the drug consumption case history may be open to question. On the other hand, 
with regard to psychotropic drugs, many of the patients have shown an impressive knowledge of 
the names, doses and effects of the various drugs. 

The group of male alcoholic inpatients and the random sample were then subdivided with respect 

(IA) men from the random sample with low or moderate alcohol consumption and no use of 
drugs (n=164); 
(IB) men from the random sample with low or moderate alcohol consumption with use of 
drugs (n=31); 
(IIA) alcoholic inpatients with use of alcohol but no drugs (n=171); 
( I D )  alcoholic inpatients with use of alcohol and drugs (n=40); 

to alcohol consumption and use of hepatotoxic drugs: 
- 

- 

- 

- 

Computed tomography 

The tomographic images were evaluated with regard to ventricular, cortical and cerebellar changes. 
An anterior horn index, i.e. Evan’ s ratio, was obtained by dividing the width of the anterior horns 
by the largest inner skull diameter. Values exceeding 0.3 I were considered pathological. 

A transverse diameter of the third ventricle exceeding 6 mm was also considered pathological. A 
four-step scale of degenerative cortical changes was used, based on a general assessment of the 
tomographs by the radiologist with regard to observations of widened sulci. In this scale, 
l=normal, i.e. no sulci visible or sulci less than 3 mm in natural size, 2=suspected degenerative 
changes, i.e. up to 5 sulci exceeding 3 mm in diameter, 3= clear-cut changes, i.e. more than 5 sulci 
exceeding 3 mm in diameter and appearing in at least 2 cuts, and 4=high-grade changes, i.e. 
marked widening of a large number of sulci in all lobes. The inter-rater reliability of the scale has 
been found to be 0.81 (1 1). 

RESULTS 

Groups IA-IIB 

Characteristics of the 2 groups of alcoholic inpatients and the 2 groups from the random sample 
who used and did not use drugs are presented in Table 2. The 40 alcoholic inpatients and drug- 
users in group IIB were significantly heavier. Ethanol was present in the blood in 2% of the 
random sample using no drugs, and in 10% of those using drugs, who had consumed 32 g and 49 
g of alcohol per day respectively in the last week before examination in the hospital. Ethanol was 
present in the blood in 42% and 40% respectively of the inpatients not using and using drugs, who 
had consumed 250 g and 251 g per day respectively in the last week before admission to hospital. 
There were significantly more smokers in the 3 groups IB, IIA and ID. 

13-928572 187 



Twelve per cent of the sample who did not use drugs (group IA) and 19% of those who used 
drugs (group IB) were registered by the Temperance Board. Among the alcoholic inpatients who 
did not use drugs (group IIA) and those who used drugs (group ID), 66% were registered by the ' 
Temperance Board. 

Table 2. Characteristics of the 4 groups of men with different drinking habits with and without the use 
of hepatotoxic drugs. 

GROUP I A  GROUP IB GROUP IIA GROUP IIB 
Random sample Random sample Alcoholic Alcoholic 
Low alcohol Low alcohol inpatients inpatients 

(n=164) (n=31) (n=171) ( n 4 0 )  
- no drugs + drugs - no drugs + drugs 

Age (ye@ 44+14 4 7 ~ 1 3  44+14 45+13 
Alcohol intake previous 
week in g absolute 
alcohoVday 32k5 1 4 9 ~ 8 8  250+_115**** 251+126**** 
Registered by the 
Temperance Board (%) 12 19 66**** 66**** 
Smokers (%) 44 58**** 74**** go**** 

Alcohol in blood on 
arrival at hospital (%) 2 

Degrees of significance in comparison with low alcohol-no drugs group by Student's t-test and Chi-square 
test. *p<0.05; **p<O.Ol; ***p<O.OOl; ****p<O.OOOl. 

Liver and pancreatic tests 

The results of alcohol-related liver and pancreatic tests in the subgroups are presented in Table 3. 
Significantly higher serum levels of bilirubin, GGT, ASAT, ALAT, CK, LD and amylase were 
found in the alcoholic group using drugs (group IZB) than in the other groups. In group IIA, with a 
high alcohol consumption and no drug use, only serum alkaline phosphatase (ALP), GGT, ASAT, 
ALAT and amylase were elevated. In group IB, the men from the random sample using drugs, 
significantly higher values of serum ALP, GGT and LD were found, but these values lay within the 
given reference ranges, except GGT. 

In the men from the random sample who used drugs combined with alcohol (group IB), the drugs 
taken included antiarrhythmic agents (quinidine, verapamil), antiepileptics (Epanutin), 
antiphlogistics (Ibuprofen) dextropropoxyphene (Doleron) and benzodiazepine derivatives, all of 
which can cause increases in liver enzymes such as serum GGT, ASAT, ALAT and LD ( see Table 
1,3). Seventy per cent of the random sample using drugs (group IB) had pathological GGT values 
and 60% pathological values of ALAT. The most imprtant of these drugs are anticoagulants, 
antiepileptic agents and barbiturates (10,16). 

188 



The drug profile of the 40 patients in group IIB and the men in group IB is shown in Table 1. 
None of the subjects used cardiovascular drugs such as digitalis, antihyperlipidemics, antidiabetics, 
or uricosuric drugs. The most frequently used non-psychotropic group of drugs was antacids. With 
regard to psychotropic drugs in group IIB, 25% of the subjects had experience of amylobarbitone 
and hexapropymate, and 26% of benzodiazepines like diazepam (Table 1). As regards non- 
addictive psychotropic drugs, 19% of the men reported using phenothiazine derivatives and 17% 
used clomethiazole, which is a drug usually prescribed for alcoholic abstinence. 

Table 3. Alcohol-related liver and pancreatic disturbances in the 4 groups as reflected by mean values 
of serum bilirubin, ALP, GGT, ASAT, ALAT, CK, LD and amylase. Reference values in 
parenthesis. 

GROUP IA GROUP IB GROUP IIA GROUP IIB 
Random sample Random sample Alcoholic Alcoholic 
Low alcohol Low alcohol inpatients inpatients 
- no drugs + drugs - no drugs i drugs 
(n=164) (n=31) (n= 17 1) (n=40) 

S-bilirubin 
12+7 16+12 *** (4-21 U m O l / l )  llk7 9k4 

S-ALP 
(0.8-4.0 ukat/l) 2.94.9 3.3k1.0 * 4.9k7.8 *** 4.3k2.0 **** 
S-GGT 
(<LOO ukat/l) 0.524.42 1.21k1.14 **** 4.40+8.21**** 6.94k9.76 **** 
S-ASAT 
(c0.70 ukat/l) 0.42k0.33 0.44k0.22 1.26+1.01**** 2.26k1.91 **** 

(<0.70 ukat/l) 0.42k0.42 0.46k0.26 1.159.9 1 **** 1.6651.38 **** 

(0.6-2.7 ukat/l) 2.4~1.7 3.0+4.3 2.3k2.1 3.4k5.0 * 

(2.7-6.4 ukat/l) 5.6k0.9 6.2k2.1 ** 7.3k1.8 8.2+2.1**** 

S-ALAT 

S-CK 

S-LD 

s-Amylase 
(1.1-5.0 ukat/l) 3.3k1.6 2.89.8 3.8k1.9 ** 6.4k8.8 **** 

Significance levels tested in comparison with group IA by Student’s t-test and Chi-square test. 
*p<0.05; **p<O.Ol; ***p<O.OOl; ****p<O.OOOl. 

CT findings in groups IA-IIB 

Cortical changes were found in 80% of group IIB(p<O.OOOl compared with group IA) and 62% of 
group IIA(p<0.0001 ), and wide transport sulci in 28%(p<0.0001) of group IIB and 22% 
(p<O.OOOl) of group IIA. Users of hepatotoxic drugs had a higher incidence of cortical changes 
than non-users in groups IA and IIA vs IB and IIB respectively (Table 4). 

189 



In group IIA, 40% (p<O.OOOl) had a pathological anterior horn index, but in the groups that 
used drugs only 32-33% (p<0.05) had a pathological anterior horn index. The incidence of an 
enlarged third ventricle varied from 32 to 53% in the drug-using groups and was 35% in group IIA. 
Wide cerebellar sulci indicating vermian atrophy were observed in 35% of the men in groups IIB 
and IIA @<O.OoOl) but were found in only 6% of group IB and 1% of group IA (Table 4). 

Table 4. CT variables used in the 4 groups with different drinking habits with and without the 
use of hepatotoxic drugs. 

CT measures 

cortical 
Wide transport sulci 
Cortical changes 
(subjective rating: 
clear-cut or high-grade) 

subcortical 
Anterior horn 
index > 0.3 1 
Width 3rd 
ventricle > 6 mm 
Verrnian atrophy 

GROUP IA GROUP IB GROUP IIA GROUP IIB 
Random sample Random sample Alcoholic Alcoholic 
Low alcohol Low alcohol inpatients inpatients 
- no drugs + drugs - no drugs -+ drugs 
(n=164) (n=31) (n=17 1) ( n 4 0 )  

% % % % 

9 32**** 35**** 53**** 
1 6 35**** 35**** 

Degrees of significance tested in comparison with low alcohol-no drugs group by Chi-square test. 
*p<0.05; **p<O.Ol; ***p<O.OOl; ****p<O.OOOl. 

DISCUSSION 

Regarding potential bias, the CT images were assessed by 2 radiologists independently and the 
assessments were made blindly, i.e. without the radiologists' having any knowledge of the alcohol 
consumption of the patient in question. The study was performed on a representative sample of men 
from Greater Stockholm, and the sample was completely unselected, randomly chosen and age- 
stratified, and drawn by Statistics Sweden, a government agency. 

The subjects knew that they were to undergo a health examination, and even though they may 
have consumed some alcohol the day before, they had not taken any on the day they came to the 
hospital. Blood samples were drawn in the morning after an overnight fast in the random. sample 
and in the alcoholic inpatient group. None of the subjects was drunk at the time of the tests or had 
cerebral oedema according to the CT findings. They were thoroughly assessed concerning the 
amount of alcohol consumed, indications of alcohol dependence and alcohol-related complications, 

190 



by means of a standardised procedure combining a self-administered questionnaire and a structured 
interview. In exactly the same way as with alcoholic inpatients (24), a sample of 40 was selected 
randomly from the 200 men who answered the questions concerning alcohol habits. These men 
were asked to answer the same questions 6-24 months after the first occasion, and a test-retest 
analysis was performed using Spearman’s rank-order correlation and Kendall’s tau-b. Kappa does 
not utilise the ordinal information of the variable, and we therefore used Kendall’s tau-b with values 
between 0.56 and 1.00. 

The methods used in the assessment of the CT images of the brain are well known and have k e n  
well documented for several years (3,4,25,26). At the Magnus Huss Clinic of the Karolinska 
Hospital, the same methods have been used for these purposes since 1976, both in alcoholics and 
in healthy control persons, with each subject assessed blindly by two examiners. The reliability has 
been 2 0.81 (1 1). In consideration of the above, there should be no important sources of bias 
regarding the population sample and the alcoholic inpatients or the CT examinations of the brain. 

The drugs used are known to be metabolised by the liver and the findings in the subjects with 
combined drug abuse and alcoholism show the clinical importance of alcohol and drug interactions. 
Many of the central nervous effects of various drugs are potentiated by simultaneous intake of 
alcohol, and the elimination rates of many drugs are influenced both by chronic alcohol 
consumption and by possible liver damage (21). 

Lader et al. (18) performed CT scanning in 20 patients who had taken benzodiazepines for a long 
period. The mean ventricular/brain area as measured by planimetry was larger than the mean values 
in an age and sex-matched group of control subjects, but was smaller than that in a group of 
alcoholics. There was no significant correlation between the CT findings and the duration of 
benzodiazepine therapy. 

The present findings are in accordance with reports in the literature concerning cerebral changes 
on CT and the effects of combination of alcohol and drugs, namely that simultaneous alcohol and 
drug intake has an additive action on the central nervous system. Bergman (5) found that alcoholic 
patients had p r e r  results in neuropsychological tests and that these were related to CT changes. In 
Bergman’ s study, the subjects in the alcoholic group were severely alcoholic, whereas our heavy 
drinkers from the random sample of the male population of Greater Stockholm were not social 
outcasts but had a high alcohol consumption. From the purely CT aspect, they resembled the 
social outcasts in Bergman’s study, the difference being that they drank smaller quantities of 
alcohol but used drugs at the same time. 

their affinity for ethanol, sensitivity to 4-methylpyrazole, and electrophoretic migration) in the 
human stomach. At the high ethanol concentrations prevailing in the gastric lumen during alcohol 
consumption, the sum of their activities could account for significant oxidation of ethanol. In vivo, 
therapeutic doses of cimetidine (but not famotidine) increased blood ethanol levels when ethanol 
was given orally but not when it was given intravenously, indicating a significant contribution of 
the gastric ADH to the bioavailability and thereby the potential toxicity of ethanol. 

Hernandez-Munoz et al. (14) found two types of alcohol dehydrogenase isoenzymes (differing in 

191 



Roine et al. (28) found that aspirin may increase the bioavailability of ingested ethanol in humans, 
possibly by reducing ethanol oxidation by gastric alcohol dehydrogenase. Lieber (22) says that 
until recently it was commonly believed that the primary pathway for hepatic ethanol metabolism is 
due almost exclusively to the activity of cytosolic alcohol dehydrogenase, with a minor contribution 
from peroxisomal catalase. It is now recognised, however, that liver microsomes (through MEOS) 
participate in ethanol metabolism. 

Caballeria et al.(6) found that the areas under the curve of blood ethanol concentrations after oral 
alcohol intake were twice as large with cimetidine as without. The results indicate that gastric 
alcohol dehydrogenase activity partly governs the systemic bioavailability of ethanol. 
Consequently, systemic effects of alcohol may be exacerbated in patients receiving cimetidine, 
which is metabolised by the liver. 

The same instrument has been applied in different populations in this study and the most 
interesting and new finding seems to be the differences in levels of markers between drug-users and 
non drug-users. The pathological values often found in alcoholics could to a large extent be 
ascribed to concomitant drug use. That alcohol and drugs can interact and that the combination may 
be dangerous is well known. The importance of this in relation to the use of biomedical markers as 
screening instruments has probably not received sufficient attention. 

In the present study, the greatest cortical and subcortical changes were found in the men of the 
small group IIB, who both had a high alcohol consumption and used drugs daily, but an exception 
was the anterior horn index, where group IIA, with high alcohol intake and no drug use, had a 
pathological index in 40%. In the random sample, the greatest cortical and subcortical changes were 
found in the men of the small group IB, who both had a relatively high alcohol consumption and 
used drugs daily. What we have found is that high alcohol consumption and drug use does not 
influence the anterior horn index so much as the other measures of brain damage. 

From a purely scientific viewpoint, this means that even though there may be major CT changes 
in some patients, the use of alcohol in combination with drugs is the most important factor which 
gives pathological cortical and subcortical changes in the population and influences the changes in 
the alcoholic inpatient groups. 

combination with drugs are at greater risk and have more pathological CT scan items except the 
anterior horn index and also have more pathological liver and pancreatic tests, which has not 
previously been shown in the literature. 

It is concluded that the alcoholic inpatients and the men in the random sample who use alcohol in 

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Correspondence: 
Sture Miitzell, MD PhD 
Department of Family Medicine 
Akademiska Hospital 
S-751 85 Uppsala, Sweden 

194