Postgraduate School of Veterinary Science
in the development of cardiovascular consequences
in alloxan-induced diabetes mellitus in dogs
Postgraduate School of Veterinary Science
Témavezető: ………………………… Prof. Dr. Semjén Gábor CSc Szent István Egyetem Állatorvos-tudományi Kar Gyógyszertani és Méregtani Tanszék Témabizottsági tagok: …………………………. Prof. Dr. Vörös Károly DSc Szent István Egyetem Állatorvos-tudományi Kar Belgyógyászati Tanszék és Klinika ……………………………. Dr. Németh Tibor PhD Szent István Egyetem Állatorvos-tudományi Kar Sebészeti és Szemészeti Tanszék és Klinika ……………………………………. Dr. Balogh Éva
Diabetes mellitus is one of the most common hormonal diseases in dogs.
It is also frequent in humans and the number of patients increases
progressively. Type-2 diabetes is considerably more frequent in humans.
Diabetic complications are strongly involved in human mortality
reasons. Cardiovascular alterations are of great importance among these
The diabetes of dogs is equally important both in veterinary and in
experimental human medicine. The management of diabetic dogs is an
important issue for the veterinarian. The therapy is based almost
The present study compiles three experiments. In the first
experiment we examined the effectiveness of oral antidiabetic drugs in
There are three widely used drug families in human type-2
diabetes: alpha-glucosidase inhibitors, biguanids and sulfonylureas.
Each of them is represented in our study.
The alpha-glucosidase inhibitor acarbose, the biguanid-type
metformin and the sulfonylurea gliclazide were investigated. According
to our results, metformin was the only drug which exerted significant
blood glucose lowering effect in postprandial blood glucose level
The second and the third experiment of the study are of human and
of veterinary interest at the same time.
Endothelin-1 is an endogenous peptide with different effects.
Besides being a potent vasoconstrictor, it exerts positive inotropic and
arrhythmogenic effect on the heart and it can contribute to the
development of certain pathological states.
The aim of second experiment was to determine the changes
in endothelin-1, in N-terminal fragment of atrial natriuretic peptide
(NT-ANP) and in atrial natriuretic peptide (ANP) levels in the
peripheral blood, in the coronary arteries and in the pericardial fluid in
healthy dogs and in dogs with experimentally induced diabetes in
response to acute hemodynamic burden that was produced with
arteriovenous shunts. According to our results the endothelin system
responds differentially to acute hemodynamic load in diabetic and in
healthy dogs which can be regarded as a potentially adaptive
mechanism. Pericardial space represents a functionally different
compartment than the coronary sinus and the peripheral plasma.
As endothelin-1 is presumably implicated in natriuretic peptide
secretion, we controlled the changes in NT-ANP and in ANP levels
paralelly with that of ET-1. The alterations in NT-ANP levels followed
the hemodynamic state sensitively, while ANP levels did not show
In our third experiment the arrhythmogenic effect of endothelin-1
was examined in diabetic and in metabolically healthy dogs.
Our results showed that a diabetic heart is more prone to the
Examination of the effect of the alpha-glycosidase inibitor
acarbose, the insulin sensitiser metformin and the insulin secretiser
gliclazide on blood glucose level in alloxan-diabetic dogs.
Evaluation of the changes in the levels of endothelin-1, atrial
natriuretic peptide and N-terminal fragment of atrial natriuretic
peptide in response to acute hemodynamic load in experimental
diabetes in dogs and the determination of the possible relations
Examination of the arrhythmogenic effect of low-dose endothelin-
1 on diabetic and on healty heart in dogs. Comparison of the
reactivity of healthy and diabetic heart.
Experiment 1: Evaluation of oral hypoglycaemic drugs in alloxan-
Seventeen clinically healthy, mixed-breed, medium-sized dogs of both
The animals were housed in individual cages at a mean
environmental temperature of 20 ºC for 12 hours in artificial light and 12
hours in darkness. The dogs received complete dog food twice a day at
Diabetes was induced by a single intravenous infusion of
560µmol/kg bw alloxan. Blood glucose level of dogs selected for the
study were moderately elevated (6.5–8.3 mmol/l) when measured on the
On days 8-15, the dogs did not get any drug. Their blood glucose
level was measured twice a day. The first sampling was done just before
feeding (FBG), and the second 60 minutes later for the determination of
postprandial blood glucose (PPBG) level. Daily fasting and postprandial
blood glucose levels, measured in that period, served as control data.
On day 16 the dogs were randomly divided into three groups. The
first group of six dogs was administered 200 mg acarbose (9.1±0.8 mg/kg bw) daily. The second group of five dogs was treated with
metformin 1700 mg per dog per day (60.9±6.4 mg/kg bw). The third
group of six dogs were given 160 mg gliclazide daily (6.1±0.7 mg/kg bw). The daily dose of drugs were divided into two equal parts and
administered at the time of feeding. FBG and PPBG data were
determined every day in the following five weeks.
Haemogram, serum alanine transaminase (ALT), alkaline
phosphatase (ALP), amylase, lipase, triglyceride (TG) and total
cholesterol (TC) were tested before the induction of diabetes and
subsequently at weekly intervals during the experiment.
The insulin level was measured weekly with the exception of the
insulin secretiser gliclazide group, where samples were taken every third
The differences between postprandial and fasting blood glucose
levels were used for the statistical evaluation. The difference between
blood glucose levels after and before feeding (PPBG-FBG) resulted in
blood glucose difference (BGD) data. Daily BGDs were averaged for
the control and the treated period in each dog. Their difference resulted
in treatment difference (TD) for each dog. The average of TDs gave the
mean decrease (MD) for each drug. The significance of MD was
statistically analysed by the two-sampled paired t-test. The data were
checked using the Shapiro-Wilk normality test.
During the treatment period, FBG and PPBG levels varied in the normal
or slightly elevated range (4.0–8.5 mmol/l) in the metformin and
acarbose groups, while in the gliclazide group severe hyperglycaemia
(up to 22.4 mmol/l ) was detected several times in three dogs.
The MD was 0.49±0.58 mmol/l (P=0.09) for acarbose treatment,
1.28±0,69 mmol/l (P=0.01) for metformin and 0.08±1.33 mmol/l (P=0.88) for gliclazide.
According to the statistical evaluation, out of the investigated
agents metformin was the only drug that caused a significant decrease in
The haemogram of the dogs remained in the normal range during
the experimental period. In two cases transient eosinophilia occurred in
the metformin group, which was not proved to be associated with the
The higher initial amylase, ALT and ALP activities in some dogs
can be attributed to the alloxan treatment, which overloaded the hepatic
The plasma concentrations of lipase, TG and TC were normal in all
The insulin data most of the time remained in the reference range in
the metformin group, and were below that several times in the acarbose
Acarbose, metformin and gliclazide are oral antidiabetic drugs
extensively used in the human medicine either alone or in combination
with one another or with insulin. In our experiment we examined their
Our experimental animals were treated with alloxan, an agent that
selectively destroys beta cells. The damage of these cells is dose
dependent, so low dosages of alloxan can produce non-insulin
dependent diabetes mellitus (Cooperstein and Watkins 1981), that we
used in our study. Our experimental animals had moderately elevated
FBG concentrations, which were also indicative of NIDDM.
Our first examined drug, the acarbose did not induce a statistically
significant decrease in postprandial blood glucose compared to control.
Acarbose acts at the “beginning” of glucose metabolism; namely, it can
decrease the absorption of glucose from the gastrointestinal tract, but it
does not directly influence either the insulin secretion or the glucose
uptake of the cells. Even then it can reduce daily insulin requirements
(Balfour and McTavish 1993; Rios 1994). As acarbose slows digestive
and absorptive processes, a smaller amount of glucose enters the
systemic circulation, reaching the pancreatic beta cells in lower
concentrations (Coniff et al. 1995), which means that acarbose reduces
PPBG (Gerard et al. 1981; Dimitriadis et al. 1985; Rios 1994). Acarbose
is not absorbed systematically. The effect of acarbose can be influenced
by the diet; namely, at a higher carbohydrate content the drug
presumably can exert greater effect. Acarbose might exert its effect
slower as there may be a threshold proportion of brush border enzymes
that must be inhibited before the effects of acarbose can be identified
(Robertson et al. 1999). According to the literature, insulin secretion was
decreased in acarbose-treated healthy dogs, which could be attributed to
the drug-induced delay in the absorption of carbohydrates (Robertson et
As the target of this drug is different, it would be worth studying in
combination with insulin or metformin mainly in obese dogs.
The insulin sensitiser metformin, our second drug examined,
significantly decreased the PPBG as compared to FBG.
In our study FBG data remained on the same level (4.0–8.5 mmol/l)
during the 4–5 weeks of the experiment.
The actual mode of action of metformin is not known, although it
has several effects on glucose metabolism at different sites of action.
Metformin presumably acts in different ways in dogs: it increases
glucose uptake and oxidation in peripheral tissues, increases insulin
receptor activity, delays glucose absorption from the bowel, and some of
these effects result in a decrease in PPBG. Metformin improves insulin
sensitivity in the peripheral tissues, but it is not effective in the absence
of insulin (Stumvoll et al. 1995), although treatment with this drug has
been reported to be associated with reduced plasma insulin, indicating
that biguanides attenuate insulin resistance (Lenhard et al. 1997).
In our experimental model the sensitivity of insulin receptors was
presumably not altered as in the case of a real type 2 diabetic patient.
However, even in our experimental model metformin could significantly
reduce the PPBG level. It did not decrease insulin secretion, which in
our case was not originally high as it would have been in the case of
In view of the above facts, careful patient selection is important.
Metformin can be appropriate for controlling pre-diabetic state in dogs
with secondary diabetes mellitus, when insulin production still exists,
e.g. in oestrous diabetes or in obese dogs with decreased glucose
tolerance, until neutering or until dietary modifications restore the
physiological balance in an optimal case.
Gliclazide, the third drug of this study elicited no significant
Gliclazide induces insulin secretion in the pancreatic beta cells and
inhibits glucogenolysis and gluconeogenesis in the liver. Through
improving insulin binding to surface receptors also enhances the insulin
sensitivity of target cells and even increases the number of insulin
The insulin sensitiser metformin decreases postprandial blood
It would be worth studying metformin further in dogs.
It would be important to characterise the type of diabetes in which
this drug can be used and to determine the optimal dosage and
Experiment 2: Endothelin and natriuretic peptide levels in cardiac
hypertrophy in experimental diabetes in dogs
21 healthy and 20 diabetic dogs were involved in the study. Diabetes
was induced by a single intravenous infusion of 560µmol/kg bw alloxan
and dogs were investigated 8 weeks after the induction of diabetes.
Blood glucose level of the diabetic dogs was over 15 mmol/l.
Cardiac hypertrophy was induced with shunted circulation. Arterio-
venous side to side shunts (3-4 cm) were placed between the arteria and
vena femoralis on both sides in both distal femoral regions of the dogs.
Dogs were divided into six groups: healthy control (sham operated)
(n=10), healthy dogs with 1 day shunted circulation (n=6), healthy dogs
with 3 days shunted circulation (n=5), diabetic control (sham operated)
(n=10), diabetic dogs with 1 day shunted circulation (n=5) and diabetic
dogs with 3 days shunted circulation (n=5).
Blood pressure, mean arterial blood pressure and heart rate were
recorded. Dogs were sacrificed 1 or 3 days after the shunt operations.
The levels of endothelin-1 (ET-1), the N-terminal atrial natriuretic
peptide and the natriuretic peptide were mesured in the pericardial fluid,
in the coronary sinus blood and in the peripheral blood with
radioimmunassay. The differences of data were analyzed by analysis of
variance followed by the Mann-Whitney test.
Diabetic dogs had lower blood pressure as compared with healthy
controls, which can be explained by the profound fluid and electrolite
depletion in untreated diabetes. Shunted circulation decreased the blood
pressure further after 1 day in diabetic dogs, while it had no effect on the
Both right and left ventricular weights increased upon shunting.
Heart weight/body weight ratios and similarly left ventricular
weight/body weight ratios increased upon 1 day of shunted circulation in
the diabetic group, while similar changes were detected only after 3 days
shunted circulation in the healthy group. Beside the increase in the
heart-weight, the quantity of NT-ANP also elevated upon shunting in
diabetic and in healthy dogs indicating that our model initiated cardiac
The cardiac hypertrophic process is elicited by an increase in
cardiac load, which causes the elevation of contractile strength. The
process is followed by the elevated secretion of different autocrin and
paracrin factors for example ET-1 and angiotensin II (Sadoshima et al.
1993, Yamazaki et al. 1995). These factors considered to have primary
role in hypertrophic process (Kim and Iwao 2000).
In a study a 9% rise was found in the left ventricular weight/body
weight ratios in rats after 12 hours in angiotensin II induced pressure
overload modell, which was further increased up to 16% after 72 hours
In our experiment the ET-1 level significantly decreased upon
shunting in the coronary sinus and in the peripheral plasma in diabetic
dogs, while there was no change in the healthy groups. The lowest ET-1
level was measured in the pericardial fluid out of the three
compartments in the diabetic group, and it was not altered upon
shunting. In healthy dogs the ET-1 level was higher in the pericardial
fluid and in the coronary sinus than in peripheral plasma, while it was
significantly higher in the peripheral plasma in diabetic dogs than in
In healthy dogs the higher pericardial ET-1 concentrations are in
accordance with literature data about different species (dogs, rats and
humans) (Horkay et al. 1998). The six-fold higher elimination rate of
ET-1 from the peripheral plasma than from the pericardial fluid can
contribute to the phenomenon (Shiba et al. 1989, Szokodi et al 1998).
The analogy in the changes in the ET-1 content of the coronary sinus
and the peripheral plasma, whereas there was no change in the
pericardial fluid suggests that the pericardial space is a functionally
different compartment. ET-1 levels in the coronary sinus were slightly
higher than in the systemic plasma, suggesting that the heart actively
contributes to the maintenance of plasma levels of ET-1.
ET-1 is considered to be involved in the secretion of the natriuretic
peptide (Ruskoaho et al 1997). In our study we measured the
concentrations of endothelin, ANP and NT-ANP in all three
Levels of NT-ANP showed similar patterns in all three
compartments: it was low in the control groups and raised in shunted
The ANP level was significantly increased in the peripheral plasma
after 3 days of shunted circulation in the healthy and in the diabetic
groups and in the pericardial fluid in healthy dogs after 1 day of shunted
The endothelin and the natriuretic peptide are essential in
regulating blood pressure. Their effects are controversial: the endothelin
is a potent vasoconstrictor, while the natriuretic peptide causes
ANP and NT-ANP are widely used for the objective signalment of
cardiac function, diagnosing heart failure, examining its progression and
controlling the effectiveness of therapy. Their elevation is a sensitive
signal of deterioration of heart function (Moe 2006) in humans and also
in dogs (Boswood et al. 2008, Haddad et al. 2008, Schellenberg et al.
2008). The NT-ANP is produced in equimolar quantity like the active
derivate ANP, but has a longer half life and thus more suitable for
examination, which was also supported by our results.
Endothelin has a series of cardiovascular effects. The potent
vasoconstrictor and the direct arrhythmogenic effect can be harmful both
in the short and in the long term, and the induction of tissue proliferation
is harmful in the long term. On the other hand ET-1 is a positive
inotropic agent and influences the inotropic responses by modulating the
Frank-Starling mechanism as well, which can be beneficial in acute
Therefore we assume that the acutely observed changes in plasma
ET-1 levels did not have any short term consequences in diabetic dogs.
The endothelin system responds differentially to an acute
hemodynamic load in alloxan diabetic and in healthy dogs.
Reduction of plasma ET-1 levels in response to an acute
hemodynamic load in diabetic dogs can be regarded as a potentially
adaptive mechanism, since it reduces the chances of vasospasm and
The pericardial space represents a functionally different
Experiment 3: Effect of experimental diabetes on endothelin
Experiments were carried out on 19 healthy and 4 diabetic dogs.
Diabetes was induced with a single intravenous injection of 560 µmol/kg
bw alloxan and dogs were investigated 8 weeks after the induction of
diabetes. The blood glucose level of the diabetic dogs was over 15
Group 1 (n=4), group 2 (n=11), and group 3 (n=4) consisted of
metabolically healthy dogs, while group 4 (n=4) contained diabetic
In group 1 physiological saline was administered. In group 2
33 pmol/min ET-1 was infused. In group 3 the administration of 33
pmol/min ET-1 was accompanied by simultaneous intracoronary
glucose infusion (25 mmol/l) for characterization of possible effects of
local hyperglycemia. In group 4 33 pmol/min ET-1 was administered to
Infusions (physiological saline, ET-1 and glucose) were
administered from 0 to 40th minutes of the experiment. Experiments
were terminated in groups 2-4 when ventricular fibrillation evolved and
Mean arterial pressure, heart rate and coronary blood flow was
continously registered and standard elektrocardiogram was made.
Student t-test was used for statistical evaluation.
The hemodynamic parameters, the mean arterial pressure, the heart rate
and the coronary blood flow were practically unaltered in the control
In group 4 (ET-1-treated diabetic dogs) the mean arterial pressure
was significantly lower than in group 2 (ET-1-treated healthy dogs) in
the 40th minute, which can be attributed to the ventricular fibrillation
which emerged sooner in group 4 than in group 2.
In group 3 (ET-1 and local hyperglycaemia) the heart rate elevated
significantly comparing to that of in group 2 at the 40th minute, which
can be explained by the time of the appearance of tachycardia: 26,3±6,7
minutes in group 3, and 30,0±12,4 minutes in group 2.
There was no arrhythmia in the saline infused control (group 1). In
healthy dogs (group 2 and 3) a substantial number of ventricular
extrasystoles, occasionally couplets and triplets appeared after about 24
minutes of ET-1 infusion. These arrhythmias emerged significantly
earlier (at 18,7 minutes) in the diabetic (group 4) than in the healthy
At around 30 minutes, ET-1 administration provoked recurring non
sustained tachycardias. At about 35 minutes following the start of
infusion, sustained tachycardias developed leading finally to ventricular
fibrillation and the termination of the experiment.
Local hyperglycaemia, which was produced by simultaneous
administration of 25 mmol/l glucose with ET-1 (group 3) did not evoke
the earlier appearance of extrasystoles. There were no significant
alterations between the groups considering the number of ventricular
fibrillations or the total elapsed time until the termination of the
ET-1 is an endogenous peptide with widespread types of action. It
exerts its influence also on the heart and is also known as a potent
arrhythmogenic agent. This phenomenon can be considered as a result of
the developing myocardial ischemia, however its direct arrhythmogenic
effect was also described. Diabetes mellitus is accompanied by a series
of metabolic disfunctions. The endothelin system is also altered: higher
ET-1 levels were observed in the blood of diabetic patients as it was
According to experimental data high dose (60 pmol/min)
intracoronary ET-1 infusion resulted in myocardial ischemia. As
myocardial ischemia is an arrhythmogenic factor itself, the direct and
indirect arrhythmogenic effect of ET-1 also affected and shortened
further the time till ventricular tachycardia evolved (Yorikane et al.
Low dose (30 pmol/min) intracoronary ET-1 infusion resulted in
ventricular tachycardia without the signs of myocardial ischemia, which
can be attributed to the direct arrhythmogenic effect of ET-1 (Tóth et al.
In our experiment the coronary blood flow did not change near the
ET-1 dose applied, demonstrating that we did not provoke myocardial
ischemia and the arrhythmogenic property of ET-1 observed was a
According to literature data the hyperglycaemia observed in
diabetes results in the elevation of ET-1 concentration and in the same
time the activity of the endothelin converting enzime, which contributes
to the production of ET-1, also rises (Cardillo et al. 2002). The
hyperglycaemia-induced alterations in the endothelin system can
sensitize the diabetic heart and may induce malignant arrhythmias.
According to our results the local hyperglycaemia did not influence
the time of appearance of the extrasystoles. That is possibly why high
glucose-induced alterations cannot be observed as acute effects, the
development of diabetic complications takes a longer time.
In our experiment, ventricular arrhythmias emerged earlier in
diabetic dogs, which proves that the diabetic heart is more prone to
arrhythmogenic effects. However there was no difference in the number
of ventricular fibrillations and the termination time of the experiments.
The diabetic heart is more sensitive to the arrhythmogenic effect of
Local hyperglycaemia is not an arrhythmogenic factor itself,
although the pathological derangements upon its prolonged
existence sensitise the heart to arrhythmogenic effects.
The insulin sensitiser metformin, applied in humans, decreases
postprandial blood glucose level in dogs.
The endothelin system responds differentially to an acute
hemodynamic load in alloxan diabetic and in healthy dogs.
The reduction of plasma ET-1 levels in response to an acute
hemodynamic load in diabetic dogs can be regarded as a potentially
adaptive mechanism, since it reduces the chances of vasospasm and
A diabetic heart is more sensitive to the arrhythmogenic effect of
Local hyperglycaemia is not an arrhythmogenic factor itself,
although the pathological derangements upon its prolonged
existence sensitise the heart to arrhythmogenic effects.
PUBLICATIONS RELATED TO THE DISSERTATION
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Committee P: Pharmacy BRITISH PHARMACOPOEIA COMMISSION Committee P: Pharmacy SUMMARY MINUTES A meeting of this Committee was held at Market Towers, 1 Nine Elms Lane, London SW8 5NQ on Tuesday, 6 June 2006. Present: Dr R L Horder (Chair), Prof. A D Woolfson (Vice Chair), Prof. M E Aulton, Mrs E Baker, Dr S K Branch, Dr G Davison, Dr G Eccleston, Dr B R Matthews, Dr W F McLean,
Instructions: After reading through each section of the manual, complete this quiz. If you have difficulties, review the section one more time and attempt the quiz again. This process should be repeated until you have the correct answers for all of the questions. Directions: Fill in the blanks with the name of the correct body part. Choose from those that are listed below. 1. The ______________