Drug Safety 7 (5): 364-373, 1992
0114-5916/92/0009-0364/$05.00/0
© Adis International Limited. All rights reserved.

ORS1 99

Adverse Effects of Diuretics

Edward D. Freis
Veterans Administration and Georgetown University Medical School, Washington, D.C., USA

 

Contents

 

Summary
1. Do Thiazide Diuretics Cause Myocardial Infarction or Sudden Death?
2. Thiazide Diuretics and Electrolyte Balance
2.1 Potassium
2.2 Magnesium
. Effect of Thiazide Diuretics on Monitored Cardiac Arrhythmic Activity
. Diuretics in the Presence of Acute Myocardial Infarction
. Diuretics and Cholesterol
. Diuretics and Blood Glucose Control
6.1 Hyperinsulinism and Insulin Resistance
. Hyperuricaemia and Gout
. Quality of Life - Sexual Function
9. Conclusions and Clinical Implications

Ra & Ww

oO

 

Summary

Analysis of the available evidence indicates that diuretics do not increase coronary heart dis-
ease morbidity and mortality. The multiclinic trials supporting the cardiotoxicity hypothesis are
few in number and flawed in design. The majority of the trials, including the well designed trials,
indicate no excess of coronary heart disease (CHD) events in diuretic-treated patients compared
with those given other drugs or placebo.

Recent studies indicate no increase in cardiac arrhythmias after diuretic treatment. Also, al-
though depletion of intracellular potassium and magnesium occurs in patients with congestive
heart failure even without diuretics, intracellular concentration of these ions is not significantly
reduced by diuretics in patients with uncomplicated hypertension.

Modest elevations of serum cholesterol may occur during the first 6 to 12 months of treatment
with thiazide diuretics. However, after this time these elevations fall to or below the pretreatment
level. The fall may be greater in patients receiving other drugs but the differences are small and
their clinical significance is questionable.

The incidences of hyperglycaemia and diabetes were only minimally increased in long term
clinical trials while the importance of hyperinsulinism and insulin resistance in causing CHD
remains unproven in patients. Thiazides remain, therefore, a safe and effective treatment for
patients with hypertension.

 
Adverse Effects of Diuretics

365

 

Few drugs in common use today have been ac-
cused of more serious adverse effects than the thia-
zides and related diuretics. The allegations include
increased risk of myocardial infarction and sudden
death due to either associated hypokalaemia, hy-
pomagnesaemia, hypercholesterolaemia or hyper-
insulinism. Additional reactions include hypergly-
caemia with aggravation of diabetes as well as the
nonketotic, hyperglycaemic syndrome. Hyperuri-
caemia is common but seldom leads to gout. In
addition, diuretics have been associated with ad-
verse effects on quality of life including impotence,
fatigue and weakness. This review assesses the va-
lidity of these alleged reactions.

1. De Thiazide Diuretics Cause
Myocardial Infarction or Sudden Death?

The multiclinic trials have shown a striking re-
duction in stroke but with few exceptions they have
shown little benefit in preventing the complica-
tions of coronary heart disease (CHD) [table I]. It
has been proposed that the difference might be due
to adverse effects of the thiazides which were used
as 1 treatment arm in the major clinical trials.

It is widely believed that the above hypothesis
has gained support from the Multiple Risk Factor
Prevention Trial (Multiple Risk Factor Interven-
tion Trial Research Group 1985b). The patients
were randomly assigned to 2 groups: the special
intervention (SI) group treated in hypertension
clinics in large teaching hospitals, and the usual
care (UC) group who were referred to their usual
community care facilities. There was no essential
difference in CHD mortality in the 2 groups (table
I). However, subgroup analysis of the patients who
had minor baseline resting electrocardiogram (ECG)
abnormalities revealed insignificantly greater CHD
mortality in the SI than in the UC patients. Could
this be due to thiazide treatment which was given
more frequently to the SI patients?

The hypothesis seems unlikely for the following
reasons: (a) another retrospective analysis from the
same study (Multiple Risk Factor Intervention Trial
Research Group 1985a) in patients who had ab-
normal baseline exercise ECGs indicated a 57%

higher CHD mortality in the UC patients than in
the SI group (p = 0.002). This was directly contra-
dictory to the previous subgroup analysis; (b) the
results of nonrandomised subgroup analysis are
known to be unreliable, as was shown by these 2
opposing results; (c) the trial was not a clear com-
parison of diuretics versus placebo or other drugs,
as only 56% of the SI group received diuretics while
33% of the UC group received similar treatment,
over half of whom were given rather large doses;
(d) the results were skewed in the UC group with
minor resting ECG abnormalities in that they ex-
hibited an abnormally low CHD mortality, lower
than the UC group without such baseline abnor-
malities; (e) there were no correlations between
CHD mortality and hypokalaemia or with size of
the diuretic dose. Also, the more reliable total ran-
domised trial showed no difference in CHD mor-
tality between the SI and UC groups. The above
evidence, therefore, provides no convincing sup-
port for the existence of cardiotoxicity due to thia-
zides.

The Metoprolol Atherosclerosis Prevention in
Hypertension Study (MAPHY trial) found more
CHD mortality with thiazides than with metopro-
lol (Wilkstrand et al. 1988). However, the MAPHY
trial was a subgroup of the Heart Attack Primary
Prevention in Hypertension trial (HAPPHY trial).
The parent HAPPHY study reported no signifi-
cant difference between the diuretic- and £-
blocker-treated groups in CHD mortality (Wil-
helmsen et al. 1987). The other subgroup that made
up the HAPPHY trial (receiving atenolol), there-
fore, must have had fewer CHD deaths with thia-
zides than with @-blockers.

The Oslo trial (Holme et al. 1984) indicated a
higher CHD death rate with thiazides, but this study
was too small to draw any valid conclusions (6
deaths per 1000 patient years in thiazide recipients
versus 2 in the placebo group).

These observations indicate that the evidence
for diuretic-induced CHD mortality derived from
only a minority of the clinical trials is weak and
contains many contradictions. On the other hand,
there were 9 other therapeutic trials which found
quite different results (table I). The largest and one
366 Drug Safety 7 (5) 1992

 

Table |. Coronary heart disease (CHD) mortality and morbidity with thiazides versus placebo or other drugs (from Freis 1989,
published with permission from the American Medical Association)

 

 

 

 

Trial No. of Diuretic and dose All CHD events Fatal CHD events
patients (mg) —
thiazide other thiazide other

Trials associating thiazides with increased CHD risk

MRFIT (Multiple Risk Factor . 2 4788 Chiorthalidone; 29,2 17.7

Intervention Trial Research Group hydrochlorothiazide 50

1985b)

Oslo trial (Holme et al. 1984) 747 Hydrochlorothiazide 50 20° 13 6° 2

MAPHY (Wilkstrand et al. 1988) 3 234 Hydrochlorothiazide 50-100; 434 36
bendroflumethiazide 5-10

Trials indicating thiazides do not increase CHD risk

EWPHE (Amery et al. 1985) 840 Hydrochlorothiazide 25-50; tac 23
triamterene 50-100

MRC (Medical Research Working 17 354 Bendroflumethiazide 10 §.2¢ 6.5 2.5¢ 2.3

Party on Mild Hypertension 1985)

Veterans Administration (Veterans 380 Hydrochlorothiazide 100 118 13 6° 11

Administration Cooperative Study

Group on Antihypertensive Agents

1970)

Australian trial (Report by the 3 427 Chlorothiazide 500-1000 70° 88 2e 8

Management Committee 1980)

Public Heaith Service (Smith 1977) 785 Hydrochlorothiazide 50 ge 7 2e 2

HDFP (Williams et al. 1986) 10 940f Chlorthalidone 25-100 1314 1489

HAPPHY (Wilhelmsen et al. 1987) 6 569 Bendroflumethiazide § 9.5¢ 10.6 41 4.4
hydrochlorothiazide 50

IPPPSH9 (The IPPPSH 6 372

Collaborative Group 1985)

MPPCD? (Miettiner et al. 1985) 1 203 Hydrochlorothiazide 50

a Subgroup with baseline ECG abnormality among 12 888 total patients.

b Per 1000 patients.

c Per 1000 person-years of observation.

d_ Total deaths due to myocardial infarction plus other ischaemic heart disease.

@ Number of events.

f Total patients. See text for analysis of subgroups with and without resting ECG abnormalities.

g Randomised to receive placebo or oxprenolol, but diuretics were soon added in 67% of the oxprenolol group and 82% of the

placebo group. Numerical data were not given but no significant association found between diuretic usage and cardiovascular
events.
h_ Coronary events tended to be accumulated in subgroups treated with £-blocking agents or clofibrate but there were few in those
receiving probucol or diuretics.
Abbreviations: MRFIT = Multiple Risk Factor Intervention Trial; ECG = electrocardiogram; MAPHY = Metoprolol Atherosclerosis
Prevention in Hypertension study (a subgroup of the Heart Attack Primary Prevention in Hypertension [HAPPHY] trial);
EWPHE = European Working Party on High Blood Pressure in the Elderly; MRC = Medical Research Council of Great Britain;
HDFP = Hypertension Detection and Follow-up Program; IPPPSH = International Prospective Primary Prevention Study in Hypertension:
MPPCD = Multifactorial Primary Prevention Trial of Cardiovascular Disease in Middie-Aged Men.

 

of the best controlled trials was the Medical Re- 1985). Propranolol, thiazide or placebo were ran-
search Council (MRC) trial of Great Britain (Medi- domly assigned. There was no difference in CHD
cal Research Working Party on Mild Hypertension events in the thiazide recipients compared with the
Adverse Effects of Diuretics

367

 

propranolol or placebo group. However, stroke was
reduced by 69% in the thiazide group and by 27%
in the propranolol-treated patients compared with
the placebo group. Although a subgroup of non-
smokers showed fewer CHD deaths in the pro-
pranolol as compared with the thiazide patients,
the HAPPHY trial found no’ such difference be-
tween @-blockers and thiazide among nonsmokers.

Another well controlled trial, the Australian trial
(Report of the Management Committee 1980),
noted a trend toward a lower incidence of nonfatal
CHD events in the thiazide recipients as compared
to those receiving placebo. The results of these 9
trials (table I) indicated no significant difference in
CHD morbidity and mortality between thiazide re-
cipients and those receiving placebo or other drugs.
Therefore, the majority of the trials including those
which were best controlled outweigh the contrary
evidence supplied by the few flawed trials. An ad-
ditional recent study, the large SHEP trial in el-
derly patients, with isolated systolic hypertension
(SHEP Cooperative Research Group 1991) re-
ported a smaller number of CHD events in di-
uretic-treated patients compared with placebo. The
questions of hypokalaemia, hypomagnesaemia,
elevations of cholesterol with thiazides and insulin
resistance are discussed later but it seems evident
that if thiazides increase CHD risk from any cause
then a higher incidence of CHD events with thia-
zides should have been manifested in the majority
of the clinical trials.

2. Thiazide Diuretics and
Electrolyte Balance
2.1 Potassium

The intracellular concentration of potassium is
many times greater than the extracellular content.
This gradient is maintained by a Nat,K+-ATPase
metabolic pump which actively extrudes sodium
from the cells but retains potassium. Therefore, ex-
tracellular potassium concentrations bear little re-
lation to the intracellular content. Sodium and po-
tassium loss in the urine following continuous
thiazide administration increases during the first 2
or 3 days but then comes back into balance with

intake, thus preventing excessive body losses dur-
ing continuous treatment (Papademetriou 1984). A
review of many studies indicated that after long
term administration of thiazide diuretics the re-
duction of intracellular potassium approximates
only 5%, which is physiologically unimportant
(Kassirer & Harrington 1977).

The Nernst equation expresses the electrical po-
tential across the cell membrane. The transmem-
brane voltage is related to the ratio of various ions
inside to outside the cell. A reduction in the ratio
of potassium outside to that inside the cell (such
as occurs with thiazide diuretics) increases the ne-
gativity of the resting membrane potential which
stabilises or reduces its electrical excitability (Guy-
ton 1981). Thus, predominantly extracellular hy-
pokalaemia should reduce rather than increase
cardiac arrhythmic activity.

2.2 Magnesium

Thiazide-induced magnesium deficiency had
been widely considered to be a cause of cardiac
arrhythmias. However, interest in this hypothesis
has declined in recent years because of the follow-
ing considerations.

The influence of diuretics on intracellular mag-
nesium and potassium is controversial. Some in-
vestigators have found only negligible reductions
(Araoye et al. 1978; Bergstrom et al. 1973) while
others have reported a deficit of both ions (Dyck-
ner & Webster 1979; Lim & Jacob 1972). As in-
dicated in the previous section, biologically insig-
nificant changes were found in intracellular
potassium with thiazide treatment of patients with
uncomplicated hypertension (Kassirer & Harring-
ton 1977) and intracellular magnesium concentra-
tions paralleled potassium concentrations (Lim &
Jacob 1972). Therefore, as is the case with potas-
sium, only small reductions in intracellular mag-
nesium would be expected with thiazide adminis-
tration. Also, thiazides should not have much
influence on magnesium excretion because these
diuretics act in the early distal tubules while mag-
368

Drug Safety 7 (5) 1992

 

nesium is absorbed predominantly in the loop of
Henle (Ryan 1986).

The controversial findings of different investi-
gators on reduction in potassium and magnesium
is probably the result of patient selection. The stud-
ies which found deficiencies of these ions were
conducted in patients who mostly had congestive
heart failure or myocardial infarction complicated
by heart failure (Dyckner & Webster 1979; Lim &
Jacob 1972).

It has been known for many years that patients
with congestive heart failure have significant def-
icits of intracellular potassium (and, therefore,
magnesium) even in the absence of diuretics. Iseri
et al. (1952) and Cort and Mathews (1954) found
marked reductions in potassium in muscle tissue
taken by biopsy in patients with congestive heart
failure and severe myocardial infarction in the era
before thiazides were available.

Treatment with magnesium- and potassium-
sparing diuretics may possibly have a place in the
treatment of congestive heart failure, although evi-
dence from well controlled studies is lacking. It is
also possible that the use of thiazides in combi-
nation with potassium-sparing diuretic may be
helpful in elderly diabetics whose diet may be po-
tassium poor. However, in patients with uncom-
plicated hypertension there does not appear to be
any indication for routine replacement therapy.

3. Effect of Thiazide Diuretics on
Monitored Cardiac Arrhythmic Activity

Early studies (Holland et al. 1981; Hollifield &
Slaton 1981) indicating increased cardiac arrhyth-
mias following thiazide diuretics have been refuted
by subsequent better-designed trials. Papademe-
triou et al. (1983) selected 16 hypertensive patients
receiving hydrochlorothiazide 50mg twice daily
whose serum potassium levels averaged 2.8 mmol/
L. The ECG was monitored for 24h following which
hypokalaemia was normalised by appropriate
treatment for 4 weeks. There were no significant
ECG differences between the hypokalaemic and the
normokalaemic periods, including couplets and
runs of ventricular tachycardia. The lack of effect

of thiazides on cardiac arrhythmias was confirmed
by other investigators (Lief et al. 1984; Madias et
al. 1984). Papademetriou et al. (1985) also found
that thiazides caused no increase in arrhythmias in
thiazide-treated patients with hypertension and left
ventricular hypertrophy.

4. Diuretics in the Presence of Acute
Myocardial Infarction

The stress of an acute myocardial infarction is
often associated with increased levels of plasma
catecholamines (Struthers et al. 1983). Because
catecholamines reduce the levels of plasma potas-
sium, severe myocardial infarction is often accom-
panied by hypokalaemia, even in the absence of
thiazide diuretics. The question has been raised that
thiazides may increase the risk of fatal arrhythmias
by aggravating the hypokalaemia.

This hypothesis is not supported, however, by
the multiclinic trials. The majority of these trials
have found that the incidence of fatal myocardial
infarction is no greater in thiazide recipients than
in patients receiving other regimens (table I). Mor-
tality is, however, related directly to the level of
circulating catecholamines (Karlsberg et al. 1981).
These results suggest that the arrhythmias are not
due to the hypokalaemia per se, but rather to the
direct arrhythmogenic effects of catecholamines on
the heart in the setting of myocardial cell injury,
tissue ischaemia and other factors related to the
myocardial insult. Nordrehaug et al. (1985) found
that catecholamines were raised in the initial pe-
riod following an infarction. Plasma potassium
levels were inversely related to ventricular tachy-
cardia during this early period. However, patients
receiving diuretics at this time did not show a sig-
nificant increase in ventricular arrhythmias. These
investigators also showed that 8 hours following
the infarction, when catecholamine levels had
fallen, the degree of hypokalaemia also was not re-
lated to the incidence of cardiac arrhythmias, again
suggesting that other factors were the cause of the
arrhythmias.

Another reason for doubting the importance of
hypokalaemia in worsening the course of acute
Adverse Effects of Diuretics

369

 

myocardial infarction is the negative results ob-
tained with potassium replacement therapy
(Fletcher et al. 1968; Rogers et al. 1979). ‘Polar-
izing solutions’ have been used in the past which
contained potassium, glucose and insulin. Intra-
venous infusion of these solutions in sufficient
amounts to raise the plasma potassium level to
normal failed to prevent ventricular arrhythmias
or reduce mortality in patients with acute myo-
cardial infarction.

5. Diuretics and Cholesterol

Numerous investigators have demonstrated an
increase in serum cholesterol during the first few
months of treatment with thiazide diuretics (Ames
& Hill 1976; Schoenfeld & Goldberger 1964). The
elevations were small, averaging less than 0.28
mmol/L.

Long term studies, usually longer than | year,
have shown either no change in cholesterol or a
slight decrease compared with baseline (table IJ).
Other long term studies have shown a greater drop
in serum cholesterol with other drugs than with
thiazides (Lasser et al. 1984; Williams et al. 1986).
Again, the differences were small, averaging 0.10
to 0.18 mmol/L with the other drugs as compared
to thiazides and were probably clinically unimpor-
tant. It should also be noted that the various clinical
trials used considerably larger doses of diuretics
than are used today. Cholesterol levels may be fur-
ther reduced with smaller doses during long term
treatment.

6. Diuretics and Blood Glucose Control

It has been recognised for many years that thia-
zide diuretics may raise blood glucose but the in-
cidence, severity and duration of the rise have been
unclear. The best evidence should be found in long
term clinical trials. After 5 years of diuretic treat-
ment the MPPCD (Helsinki) trial found a mean
rise 1h after a glucose load of only 0.3 mmol/L
from baseline as compared to 0.7 mmol/L in the
control group (Miettiner et al. 1985).

The HAPPHY trial involving approximately

6000 patients reported an incidence of diabetes over
a 45-month period of 6.1 per 1000 patient-years in
diuretic recipients compared with 6.9 per 1000
patient-years in those on 6-blockers (Wilhelmsen
et al. 1987).

In the MRC trial there were no significant
changes in casual blood glucose levels, although
there was a slight increase at 1 year followed by a
fall after 2 years (Medical Research Working Party
on Mild Hypertension 1977). On the other hand,
the HDFP trial reported an incidence of 1.6% of
diabetes or hyperglycaemia in chlorthalidone re-
cipients compared with 0.1% in those receiving re-
serpine and none in those receiving methyldopa
(Williams et al. 1986).

A 10-year controlled trial indicated that low
doses of thiazides are not diabetogenic (Berglund
et al. 1986). Thus, aside from HDFP and consid-
ering the natural increase of diabetes in middle-
aged to elderly patients, the reported increased in-
cidence of diabetes with thiazides is low and in
some studies nonexistent (Berglund et al. 1986).

The hyperosmolar nonketotic syndrome is char-
acterised by an acute, severe elevation of blood
glucose occurring without ketosis. It is not limited
to diabetic patients. It usually occurs in patients
receiving diuretics (Curtis et al. 1972). These
patients often develop severe dehydration and oc-
casionally coma. The syndrome is manifested by
polyuria and markedly elevated levels of blood glu-
cose. Rapid rehydration is indicated. It is often
possible to transfer the patient to a chemically dif-
ferent diuretic such as chlorthalidone in place of a
thiazide or vice-versa without recurrence of the
hyperglycaemic state.

6.1 Hyperinsulinism and Insulin Resistance

The association between hypertension and dia-
betes represents a major health problem affecting
2.5 million Americans (Working Party on Hyper-
tension in Diabetes 1987). The presence of hyper-
tension in diabetes greatly increases the risk of both
CHD and nephropathy. Nephropathy but not CHD
has been favourably influenced by reduction of
blood pressure (Christlieb 1982; Mogensen 1989).
370

Drug Safety 7 (5) 1992

 

Table il. Changes in serum cholesterot level with short term versus long term treatment of hypertension with diuretics (from Freis
1989, published with permission from the American Medical Association)

 

 

Trial No. of Diuretic and dose Duration of Mean change in
patients (mg) treatment cholesterol (mmol/L)

Trials indicating a rise in cholesterol

Ames and Hill (1976) 74 Chlorthalidone 25-100 1-3 months +0.28

VA-NHLBI (Goldman et al. 1980) 302 Chiorthalidone 50-100 1 year +0.26

Grimm et al. (1981) 57 Chiorthalidone 100 or 1.5-3 months +0.18

hydrochlorothiazide 100

Studies indicating no change or a fall in cholesterol

EWPHE (Amery et al. 1985) 190 Hydrochlorothiazide 25-50 2 years -0.52

Framingham study (Kannel et al. 288 Thiazides 2 years ~0.16

1977)

MRC (Medical Research Working 17 354 Bendroflumethiazide 10 3 years +0.054

Party on Mild Hypertension 1985)

MRFIT (Multiple Risk Factor 10215 Chlorthalidone or 6 years ~0.23

Intervention Trial Research Group hydrochlorothiazide 50-100

1985b)

MPPCD (Miettiner et al. 1985) 1 203 Hydrochiorothiazide 50 5 years 0

Oslo triat (Holme et al. 1984) 300 Hydrochlorothiazide 50 3 years 0

HAPPHY (Wilhelmsen et al. 1987) 6 669 Bendroflumethiazide 5 or 1 year 9

hydrochlorothiazide 50

Trials indicating an early rise followed by a fall below baseline

VA propranolol- 147 Hydrochlorothiazide 50-200 2 months +0.16

hydrochtorothiazide (Veterans 1 year —-0.08

Administration Cooperative Study

Group on Antihypertensive Agents

1982a,b)

Alcazar et al. (1982) 236 Hydrochlorothiazide 50-100 1-3 months >oe
1-2 years <oe

HDFP (Williams et al. 1986) 7 006 Chiorthalidone 50 6-12 months +0.10
2-5 years ~-0.23

 

a Considered essentially unchanged from baseline.

b Number of patients with special interventions who received diuretics only.

c Numerical value of changes not given (p < 0.01).

Abbreviations: VA = Veterans Administration; NHLBI = National Heart, Lung, and Blood Institute; EWPHE = European Working Party
on High Blood Pressure in the Elderly; MRC = Medical Research Council of Great Britain; MRFIT = Multiple Risk Factor Intervention
Trial; MPPCD = Multifactoriat Primary Prevention Trial of Cardiovascular Disease in Middle-Aged Men; HAPPHY = Heart Attack
Primary Prevention in Hypertension trial; HDFP = Hypertension Detection and Follow-up Program.

 

Hyperinsulinism and insulin resistance may oc-
cur in diabetes, hypertension and obesity (Ferran-
ini et al. 1987; Modan et al. 1985; Mogensen 1989;
Reaven 1988), raising the hypothesis that hyper-
insulinism may be a risk factor in CHD, although
this assumption has not been convincingly dem-
onstrated. Both hypefinsulinism and insulin re-

sistance may be aggravated by thiazides in some
patients.

Sodium retention is characteristic of diabetes
(Working Party on Hypertension in Diabetes 1987),
which is aggravated by the antidiuretic effects of
insulin (Saudek et al. 1974). Therefore, thiazides
have been commonly used alone or in combina-
Adverse Effects of Diuretics

371

 

tion with other drugs in hypertensive diabetics
(Christlieb 1982).

Warram et al. (1991) in a retrospective study of
749 diabetic patients reported that both total and
CHD mortality were significantly higher in patients
receiving thiazide diuretics than in other patients.
There are a number of problems, however, with
this study. First and probably most important, it
was a retrospective study. Secondly, drug treat-
ment was most likely given to the more severe hy-
pertensives who were, therefore, at higher risk of
CHD. A prospective controlled trial is needed to
determine the validity of this report.

While diuretics have been associated with a de-
crease in insulin sensitivity and an increase in hy-
perinsulinism, an increase in risk of CHD with di-
uretics has not been confirmed by the long term
controlled trials (table I). Also, there was no or only
a minimal increase in hyperglycaemia and diabetes
in thiazide-treated patients in most of the long term
treatment control trials.

7. Hyperuricaemia and Gout

While hyperuricaemia frequently occurs with
thiazide treatment, the incidence of gout is only
slightly more common than in patients treated with
other drugs. For example, in the HAPPHY trial
(Wilhelmsen et al. 1987) involving 6500 patients,
gout was diagnosed in 63 patients receiving thia-
zides compared with 44 patients taking 8-blockers.
Furthermore, the hyperuricaemia and most attacks
of gout are preventable with uricosuric drugs. If
acute attacks of gout occur they respond rapidly to
nonsteroidal anti-inflammatory drugs such as in-
domethacin.

8. Quality of Life - Sexual Function

Little information is available on the quality of
life in patients receiving diuretics. A multicentre,
randomised, controlled trial (TAIM study) [Was-
sertheil-Smoller et al. 1991] compared chlorthali-
done 25 mg/day with atenolol 50 mg/day and with
placebo in patients on different diets. They did not
find any impairment of quality of life except for

sexual function. Sexual performance was adversely
affected in approximately 25% of patients receiving
chlorthalidone. However, this problem was pre-
vented in chlorthalidone recipients who followed a
weight reduction diet. In fact, this latter group had
the least sexual problems of any patients and also
exhibited the most effective control of their hyper-
tension. This finding contradicts the suggestion that
impaired sexual function results from reduction of
blood pressure per se.

Reduction of bodyweight, therefore, exerts sev-
eral favourable effects when combined with di-
uretics. It prevents impaired sexual function, it
considerably enhances the antihypertensive effec-
tiveness of the drug and it favourably affects car-
diovascular risk. As the authors suggest, weight re-
duction of overweight patients should be combined
with drug treatment in the general management of
patients on diuretic therapy.

9. Conclusions and Clinical Implications

The current opinion of the toxicity of diuretics,
particularly with respect to cardiotoxicity, has been
greatly exaggerated. Analysis of the long term con-
trolled clinical trials do not indicate an excess mor-
tality from CHD with thiazides compared with
other drugs. The allegations that hypokalaemia,
hypomagnesaemia, hypercholesterolaemia, hyper-
insulinaemia or insulin resistance when associated
with diuretics increase the risk of CHD either re-
main unproven or have been disproved.

The majority of the long term clinical trials have
indicated no or trivial changes in blood glucose or
increase in the incidence of diabetes. Only the
hyperglycaemic nonketotic syndrome has been def-
initely associated with thiazide diuretics but this is
an acute condition rapidly reversible with appro-
priate therapy. Also, the hyperuricaemia associated
with diuretics seldom leads to gout, which can be
controlled with uricosuric drugs and the early
treatment of the acute attacks.

The modern trend is to use small doses of di-
uretics in treating hypertension, such as 12.5 or
25mg of hydrochlorothiazide daily. This is in keep-
ing with the general principle of titration which re-
372

Drug Safety 7 (5) 1992

 

cognises that some patients respond to smaller
doses more than others. However, it fails to re-
cognise that other patients require higher doses to
achieve blood pressure control. Therefore, in view
of the low toxicity of the diuretics more patients
will be effectively controlled if the doses are ti-
trated to at least 50 mg/day of hydrochlorothiazide
or equivalent doses of other diuretics before adding
another drug. This also will result in considerable
cost saving since thiazides cost only a fraction of
the price of most other drugs.

These considerations pertain to the great ma-
jority of hypertensive patients who have uncom-
plicated hypertension. In certain patients other
drugs probably should receive preference over the
diuretics as primary therapy. Those include £-
blockers in patients with prior myocardial infarc-
tion, converting enzyme inhibitors in the presence
of congestive heart failure or nephropathy and cal-
cium antagonists in severe gout or diabetes. In the
great majority of patients who do not present such
complications, diuretics would appear to be effec-
tive, safe and far less costly than most other drugs.

References

Alcazar J, Ruilope L, Ladron deGuevara P, et al. Interrelation-
ship between uric acid, cholesterol and triglycerides in essen-
tial hypertension. Presented at the Ninth Meeting of the Inter-
national Society of Hypertension, Mexico City, Mexico,
February 22, 1982

Amery A, Birkenhager W, Brixko P, et al. Mortality and mor-
bidity results from the European Working Party on High Blood
Pressure in the Elderly Trial. Lancet 1: 1349-1354, 1985

Ames RP, Hill P. Elevation of serum lipids during diuretic therapy
for hypertension. American Journal of Medicine 61: 748-757,
1976

Araoye MA, Khatri IM, Yao LL, Freis ED. Leucocyte intracell-
ular cations in hypertension: effect of antihypertensive drugs.
American Heart Journal 98: 731-738, 1978

Bergstrom J, Hultman E, Solheim SB. The effect of mefruside on
plasma and muscle electrolytes and blood pressure in normal
subjects and in patients with essential hypertension. Acta Med-
ica Scandinavica 194: 427-432, 1973

Berglund G, Anderson O, Widgren B. A low-dose antihyperten-
sive treatment with a thiazide diuretic is not diabetogenic; a
10-year controlled trial with bendroflamethiazide. Journal of
Hypertension 4 (Suppl. 5): $525-S527, 1986

Christlieb AR. Treating hypertension in patients with diabetes
mellitus. Medical Clinics of North America 66: 1373-1388, 1982

Cort JH, Mathews HL. Potassium deficiency in congestive heart
failure: three cases with hyponatremia including results of po-
tassium replacement in one case. Lancet 1: 1202-1206, 1954

Curtis J, Harrigan F, Ahearn D, Varney B, Sandler SG, et al.
Chlorothalidone induced hyperosmolar, hyperglycemic, non-

ketotic coma. Journal of the American Medical Association
220: 1592-1593, 1972

Dyckner T, Webster PO. Ventricular extrasystoles and intracell-
ular electrolytes before and after potassium and magnesium
infusions in patients on diuretic therapy. American Heart
Journal 97: 12-18, 1979

Ferranini E, Buzzigoli G, Bonadonna R, Giorico MA, Oleggini
M, et al. Insulin resistance in essential hypertension. New Eng-
land Journal of Medicine 317: 350-357, 1987

Fletcher GF, Hurst JW, Schlant RC. Polarizing solutions in
patients with acute myocardial infarction. American Heart
Journal 6: 319-324, 1968

Freis ED. Critique of the clinical importance of diuretic-induced
hypokalemia and elevated cholesterol level. Archives of Inter-
nal Medicine 149: 2640-2648, 1989

Goldman AI, Steele BW, Schnaper HW, Fitz AE, Frohlich ED,
et al. Veterans Administration-National Heart, Lung and Blood
Institute Cooperative Study on Antihypertensive Therapy: mild
hypertension : serum lipoprotein levels during chlorthalidone
therapy. Journal of the American Medical Association 244:
1691-1695, 1980

Grimm Jr RH, Leon AS, Hunninghake DB, Leng K, Hannon P,
et al. Effects of thiazide diuretics on plasma lipids and lipo-
proteins in mildly hypertensive patients: a double-blind con-
trolled trial. Annals of Internal Medicine 94: 7-11, 1981

Guyton AC. Textbook of Medical Physiology, 6th ed., WB Saun-
ders Co., Philadelphia, 1981

Holland OB, Nixon JV, Kuhnert I. Diuretic-induced ventricular
ectopic activity. American Journal of Medicine 770: 762-768,
1981

Hollifield JW, Slaton PE. Thiazide diuretics, hypokalemia and
cardiac arrhythmias. Acta Medica Scandinavica 647: 67-73,
1981

Holme L, Helgeland A, Hjermann I, Lern P, Lundlarsen PC.
Treatment of mild hypertension with diuretics: the importance
of ECG abnormalities in the Oslo study and in MRFIT. Jour-
nal of the American Medical Association 251: 1298-1299, 1984

Iseri IT, Alexander LC, McCarghy RS, Boyle AFJ, Myers GB.
Water and electrolyte content of cardiac and skeletal muscle
in heart failure and myocardial infarction. American Heart
Journal 43: 215-227, 1952

Kannel WB, Gordon T, McGee D. Diuretics and serum choles-
terol. Lancet 1: 1362-1363, 1977

Karlsberg RP, Cryer PE, Roberts R. Serial plasma catecholamine
response early in the course of clinical acute myocardial in-
farction: relationship to infarct extent and mortality. American
Heart Journal 102: 24-29, 1981

Kassirer JP, Harrington JT. Diuretics and potassium metabolism:
a reassessment of the need, effectiveness and safety of potas-
sium therapy. Kidney International 11: 505-515, 1977

Lasser ML, Grandita G, Caggiula AW, Cutler JA, Grimm RH,
et al. Effects of antihypertensive therapy on plasma lipids and
lipoprotein in the Multiple Risk Factor Intervention Trial.
American Journal of Medicine 76: 52-66, 1984

Lief PD, Bligin I, Mates J, Bank N. Diuretic induced hypokale-
mia does not cause ventricular ectopy in uncomplicated es-
sential hypertension. Kidney International 25: 203, 1984

Lim P, Jacob E. Magnesium deficiency in patients on longterm
diuretic therapy for heart failure. British Medical Journal 2:
620-622, 1972

Madias JE, Madias NE, Gavras HP. Non-arrhythmogenicity of
diuretic-induced hypokalemia. Archives of Internal Medicine
144: 2171-2176, 1984

Medical Research Council Working Party on Mild Hypertension.
Randomized controlled trial of treatment for mild hyperten-
sion: design and pilot trial. British Medical Journal 1: 1437-
1440, 1977

Medical Research Working Party on Mild Hypertension. MRC
Adverse Effects of Diuretics

trial of treatment of mild hypertension: principle results. Brit-
ish Medical Journal 291: 97-104, 1985

Miettinen TA, Huttunem JK, Naukkarinen V, Strandberg T,
Mattilla S, et al. Multifactorial primary prevention of cardio-
vascular disease in middle-aged men: risk factor changes, in-
cidence and mortality. Journal of the American Medical As-
sociation 254: 2097-2102, 1985

Modan M, Halkin H, Almog S, Lusky A, Eshkol A, et al. Hy-
perinsulinemia: a link between hypertension, obesity and glu-
cose intolerance. Journal of Clinical Investigation 75: 809-817,
1985

Mogensen CE. The effect of blood pressure intervention on renal
function on insulin-dependent diabetes. Diabetes and Metab-
olism 15: 343-351, 1989

Multiple Risk Factor Intervention Trial Research Group. Base-
line rest electrocardiographic abnormalities, antihypertensive
treatment and mortality in the Multiple Risk Factor Interven-
tion Trial. American Journal of Cardiology 55: 1-5, 1985b

Multiple Risk Factor Intervention Trial Research Group. Exer-
cise electrocardiogram and coronary heart disease mortality in
the Multiple Risk Factor Intervention Trial. American Journal
of Cardiology 55: 16-24, 1985a

Nordrehaug JE. Hypokalemia, arrhythmias and early prognosis
in acute myocardial infarction. Acta Medica Scandinavica 217:
299-306, 1985

Nordrehaug JE, Johnssen KA, Van der Lippe G. Serum potas-
sium concentration as a risk factor of ventricular arrhythmias
early in acute myocardial infarction. Circulation 71: 645-649,
1985

Papademetriou V, Burris JF, Notargiacomo A, Fletcher RD, Freis
ED. Effect of diuretic therapy on ventricular arrhythmias in
patients with or without left ventricular hypertrophy. Ameri-
can Heart Journal 110: 596-599, 1985

Papademetriou V, Fletcher RD, Khatri IM, Freis ED. Diuretic-
induced hypokalemia in uncomplicated hypertension: effect of
plasma potassium correction on cardiac arrhythmias in am-
bulatory hypertensive patients. American Journal of Cardiol-
ogy 52: 1017-1023, 1983

Papademetriou V, Price M, Johnson E, Smith M, Freis ED. Early
changes in plasma and urinary potassium in diuretic treated
patients with systemic hypertension. American Journal of Car-
diology 54: 1015-1019, 1984

Reaven GM. Role of insulin resistance in human disease. Dia-
betes 37: 1595-1607, 1988

Report by the Management Committee: the Australian Thera-
peutic Trial in Mild Hypertension. Lancet J: 1261-1267, 1980

Rogers WH, Segall PH, McDaniel HG, Mantle JA, Russell RD,
et al. Prospective randomized trial of glucose-insulin potas-
sium in acute myocardial infarction. American Journal of Car-
diology 43: 801-809, 1979

Ryan MP. Magnesium and potassium sparing diuretics. Magnes-
jum 5: 282-292, 1986

Saudek C, Boulter PR, Knopp RH, Arky RA. Sodium retention
accompanying insulin treatment of diabetes mellitus. Diabetes
23: 240-246, 1974

Schoenfeld MR, Goldberger E. Hypercholesterolemia induced by
thiazides: a pilot study. Current Therapeutic Research 6: 180-
184, 1964

SHEP Cooperative Research Group. Prevention of stroke by anti-

373

hypertensive drug treatment in older persons with isolated sys-
tolic hypertension. Final results of the Systolic Hypertension
in the Elderly Programme (SHEP). Journal of the American
Medical Association 265: 3255-3267, 1991

Smith WM. US Public Health Service Hospitals Cooperative Study
Group. Treatment of mild hypertension: results of a ten-year
intervention trial. Circulation Research 40 (Suppl. 1): [98-1105,
1977

Struthers AD, Whitesmith R, Reid JL. Prior thiazide diuretic
treatment increases adrenaline-induced hypokalemia. Lancet
1: 1358-1360, 1983

The IPPPSH Collaborative Group. Cardiovascular Risk and risk
factors in a randomized trial of treatment based on the beta-
blocker oxprenolol: the International Prospective Primary Pre-
vention Study in Hypertension (IPPPSH). Journal of Hyper-
tension 3: 379-392, 1985

Veterans Administration Cooperative Study Group on Anti-
hypertensive Agents. Effects of treatment on morbidity in
hypertension II: results of patients with diastolic blood pres-
sure averaging 90 through 114 mm Hg. Journal of the Amer-
ican Medical Association 213: 1143-1151, 1970

Veterans Administration Cooperative Study Group on Anti-
hypertensive Agents. Comparison of propranolol and hydro-
chlorothiazide for the initial treatment of hypertension I: re-
sults of short-term titration with emphasis on racial differences
in response. Journal of the American Medical Association 248:
1996-2003, 1982a

Veterans Administration Cooperative Study Group on Anti-
hypertensive Agents. Comparison of propranolol and hydro-
chlorothiazide for the initial treatment of hypertension II: re-
sults of long-term therapy. Journal of the American Medical
Association 248: 2004- 2011, 1982b

Warram JH, Lappel LMB, Valsania P, Christlicb AB, Kraco-
lewski AJ, Excess mortality associated with diuretic in diabetes
mellitus. Archives of Internal Medicine 151: 1350-1356, 1991

Wassertheil-Smoller S, Blaufax D, Oberman A, Davis BR,
Swuenionis C, et al. Effect of antihypertensives on sexual func-
tion and quality of life: the TAIM study. Annals of Internal
Medicine 114: 613-619, 1991

Wilhelmsen L, Goran B, Elmfeldt D, Fitzsimmons T, Holzgreve
H, et ai. Beta-blockers versus diuretics in hypertensive man:
main results from HAPPHY trial. Journal of Hypertension 5:
561-572, 1987

Wilkstrand J, Warnald I, Alsson G, Tuomilehto J, Elmfeld D, et
al. Primary prevention with metropolol in patients with hyper-
tension: mortality results from the MAPHY study. Journal of
the American Medical Association 259: 1976-1982, 1988

Williams WR, Schneider KA, Borhani NO, Schnaper HW, Slat-
koff LM, et al. The relationship between diuretics and serum
cholesterol in Hypertension Detection and Follow-Up Pro-
gram participants. American Journal of Preventive Medicine
2: 248-255, 1986

Working Party on Hypertension in Diabetes. Statement on hyper-
tension in diabetes mellitus. Final report. Archives of Internal
Medicine 147: 830-842, 1987

 

Correspondence and reprints: Dr Edward D. Freis, Chief, Hyper-
tension Research Clinic, Department of Veterans Affairs Medical
Center, 50 Irving Street Northwest, Washington, DC 20422, USA.