Phys. Journal No. 3, December 2008.pmd


Relationship Between Obesity And Parasympathetic Nerve
Function

Shahin Akhter1,Noorzahan Begum2, Sultana Ferdousi3, Shelina Begum4,Taskina Ali5

Back ground: Obesity is a potential risk factor for cardiovascular morbidity and mortality. As certain
cardiovascular disorders associated with autonomic nerve which dysfunction often coexist in obese
persons, investigations of autonomic nerve function especially parasympathetic nerve function in
obese, for detection of early autonomic impairment can be potentially important to prevent
complications. Objective: The present study was done to observe the parasympathetic nerve function
status in obese persons in order to investigate the relationship of autonomic nerve function with
obesity. Study design: This study was conducted in the department of Physiology of Bangabandhu
Sheikh Mujib Medical University, Dhaka, Bangladesh during July 2006-June 2007. For  these  40
apparently healthy obese subjects of both sexes with BMI > 25 kg/sqm.  were included in study
group. Age and sex matched 40 apparently healthy non obese subjects with BMI range 18.5-22.9 kg/
sqm.  were taken as control for comparison. Methods: To assess parasympathetic nerve function
status, heart rate response to valsalva(valsalva ratio), heart rate response to deep breathing and heart
rate response to standing (30th:15th ratio) were determined by 3 noninvasive cardiovascular reflex
tests . Data were collected by recording ECG of all subjects under test condition. The correlations of
these parasympathetic nerve function parameters with BMI were also studied.  Unpaired Student‘t’
test and Pearson correlation coefficient test were used for statistical analysis. Results: Valsalva ratio
(1.47±0.24 vs 1.67±0.31), HR response to deep breathing (19.62±5.55 vs 27.59±6.51) and HR response
to standing (1.07±0.07 vs 1.13±0.018) were significantly decreased in obese subjects than those of
non obese control. All these parameters were negatively correlated with BMI. and these relatioship
were statistically significant.  Conclusion: The results of this study indicate that parasympathetic
nerve function may be reduced in apparently healthy obese subjects.

Key words: Obesity; valsalva; parasympathetic; deep breathing.

J Bangladesh Soc Physiol.2008 Dec;(3):50-54.
For author affiliations, see end of text.

http://www.banglajol.info/index.php/JBSP

reported that globally, approximately 1.6 billion
adults (age15+) were overweight and at least 400
million adults were obese. Overweight
population will reach approximately to 2.3 billion
and obese population to 700 million  by 20153.

Obesity is a condition of excess fat deposition in
the body4. Body mass index (BMI) is commonly
used to identify and classify overweight and
obesity in adult individuals4.

O

Article

Introduction:
besity is a nutritional health problem
which is gradually rising and affecting
a major section of adult population1.

Obese people have greater risk of developing
both cardiovascular and metabolic diseases like
hypertension, atherosclerosis, diabetes mellitus
and gallbladder diseases2. In the mid 1990s WHO
expressed concern to the growing obesity
epidemic throughout the world1. In 2005, WHO

50 J Bangladesh Soc Physiol. 2008 Dec;(3):50-54



According to WHO standards, overweight and
obesity are indicated by BMI > 25 and > 30
respectively. But for Asians, the cut off point for
overweight (23 to 24.9) and obese 25 are lower
than the WHO standard5.

Obesity usually results from an imbalance
between energy intake and energy expenditure
which is under a feedback regulation involving
a complex interaction among endocrine, nervous,
metabolic and psychological factors6.
Hypothalamus plays an important role in the
regulation of body weight2. The importance of
hypothalamus and autonomic nerve activity for
maintaining energy storage is supported by some
experimental observations from animal model
study7. More studies on   autonomic nervous
activity in human obese persons have reported
controversial findings; These include
hypoactivity of parasympathetic and associated
hyperactivity of sympathetic nerve function8;
both reduced sympathetic and parasympathetic
nerve activity9-10 and increased parasympathetic
activity with a decreased sympathetic nerve
activity7. Sometimes, obesity is associated with
minor impairments of autonomic nerve function
and in most of the cases, changes were found in
parasympathetic division of autonomic nervous
system which is analogous to the early stage of
autonomic neuropathy in diabetes mellitus11.

Obesity related health problems including various
cardiovascular and metabolic diseases are not
uncommon in our community. In addition to
recognized complications of obesity, autonomic
nerve dysfunction may also coexist with certain
cardiovascular disorders in obese person. In
obese persons, investigations of autonomic nerve
functions especially parasympathetic one can be
potentially important for detection of early
autonomic nerve function impairment which
there by may be helpful to prevent its
complications. But no published data on
parasympathetic nerve function status in obese
people is available in Bangladesh. Therefore, this
study was aimed to observe the parasympathetic

nerve function status in obese subjects and also
to find out any relationship between
parasympathetic nerve activity and obesity.

Methods:
This cross sectional study was conducted in
department of Physiology of Bangabandhu
Sheikh Mujib Medical University, Dhaka,
Bangladesh. For this, 80 apparently healthy
subjects of both sexes with age range from18-40
years were selected from the different areas of
Dhaka city.

On the basis of their body mass index, all  the
subjects were divided into two groups. Group
A(control) consisted of 40 nonobese subjects
with BMI between 18.50 - 22.90 kg/sqm. Group
B (study)consisted of obese subjects with BMI
> 25 kg/sqm.. The subjects with age >40 years,
overweight (BMI 23 - 24.9 kg/sqm.), diabetes
mellitus, chronic renal failure, suffering from any
obvious cardiovascular diseases, chronic
obstructive lung diseases, previous history of
head injury and smokers were excluded from this
study.

The purpose and expected outcome of the study
were explained to each subject. They were
encouraged for voluntary participation.  Written
informed consent was obtained from each subject.
Detailed medical and family history was taken and
thorough clinical examination was done. All
information were recorded in a preformed
questionnaire.  Height and weight of the subjects
were recorded and BMI was calculated. Random
blood sample was collected to determine blood
glucose and serum creatinine to exclude diabetes
mellitus and chronic renal failure. Blood glucose
and serum creatinine level were measured by auto
analyzer in the hematology laboratory of the
Physiology department. Then the autonomic nerve
function parameters like valsava ratio, heart rate
response to deep breathing and heart rate response
to standing (30th:15th ratio) were determined by
performing valsalva maneuver, deep breathing and
orthostatic test using an ECG machine and a

Parasympathetic Nerve Function and Obesity Article

J Bangladesh Soc Physiol. 2008 Dec;(3):50-54 51



mercury column attached to a mouthpiece by a
rubber tube.

Each of the subject was briefed about the
procedure in detail and encouraged to obtain
maximum efficient performance. Cardiovascular
reflex tests were conducted in the
neurophysiology laboratory from 9.00am-
2.30pm in a comfortable environment. The
subjects were allowed to rest and relax for at least
10 minutes upon arrival. In all subjects, valsalva
maneuver, deep breathing and orthostatic test
(30th:15thratio) were performed sequentially.
Before the tests, all the subjects took rest in
supine position in a bed for a minimum of 10
minutes and then their basal heart rate was
recorded. Results were compared between the
groups. Relationship of  all the parameters with
BMI were observed.

Data were entered in computerized SPSS
program version-12. All the data were expressed
as mean ± SD (Standard deviation). Statistical
analysis were done by unpaired Student’s ‘t’ test
and  Pearson’s correlation-coefficient test as
applicable.

Results:
Anthropometric details of the subjects are given
in table-I.

Both groups are matched for age and sex. Mean
weight and BMI were significantly higher
(p<0.001) in obese subjects compared to that of
nonobese control subjects. All the
parasympathetic nerve function parameters were
analyzed separately in male and female. But no
significant differences were observed between
male and female.

The results of the parasympathetic nerve function
tests are shown in table-II.

Obese subjects(Group B) had significantly lower
valsalva ratio, HR response to deep breathing and
30th :15th than those of control(group A).

The results of correlations are presented in figure 1,2,3.

All the parasympathetic nerve function
parameters showed statistically significant
negative correlation with BMI.

Table-I
Mean + SD, Age, height, weight and body

mass index in the study groups (n=80)

Parameters Group-A Group-B
(n=40) ( n=40)

Age(years) 31.02±5.04 31.77±4.66ns

(20-40) (19-40)
Height(cm) 165.02±7.64 163.37±8.69ns

(154-180) (152-180)
Weight(kg) 57.6±6.49 76.05±9.18***

(48-72) (58-98)
BMI(kg/m2) 21.44±1.24 28.45±1.78***

(18.75-22.90) (26.17-33.96)

Group A   :   Nonobese subjects having BMI between
18.50 to 22.90 kg/m2
Group B   :   Obese subjects having BMI >25 kg/m2
Values in parenthesis indicate range.n = total number
of subjects.ns= not significant.
***= significant at <0.001 level.

Table-II
Parasympathetic nerve function parameters in

the study groups (n=80)

Parameters Group-A Group-B

n=40  n=40

Valsalva ratio 1.67±0.31 1.47±0.24**

(1.21-2.34) (1.07-1.98)

Heart rate response 27.57±6.51 19.62±5.55***

to deep breathing (16.18-39.83) (9.28-31.89)
(beats/min)

Heart rate response 1.13±0.08 1.07±0.07**
to  standing (1.04-1.34) (0.9-1.25)
(30th:15th ratio)

Group A   :   Nonobese subjects having BMI between
18.50 to 22.90 kg/m2

Group B   :   Obese subjects having BMI ≥25 kg/m2

Values in parenthesis indicate range.
n = total number of subjects.**= significant at <0.01
level. ***= significant at <0.001 level.

Article Parasympathetic Nerve Function and Obesity

52 J Bangladesh Soc Physiol. 2008 Dec;(3):50-54



Discussion:
The results in the present study have shown that
HR response to valsalva maneuver, to deep
breathing and standing were significantly lower
in obese subjects than in non obese control
Which is similar to the findings observed by some
other investigators of different countries12-15. But
relatively higher valsalalva ratio and lower deep
breathing and standing test in obese subject
compared to control subjects but not statistically
significant were also found by some other group

of observers 6. In this study, all the
parasympathetic nerve function parameters
showed negative correlation with BMI and it was
statistically significant. Therefore, the present
study has shown that parasympathetic nerve
dysfunction may occur in obese people.
However,the exact mechanism that may cause
impairment of parasympathetic nerve function
has not yet been clearly established. Some
researchers suggested that gradual development
of  insulin resistance in target tissues with the
beginning of excess weight gain in obesity is
responsible for subsequent development of
hyperinsulinaemia 4. This hyperinsulinaemia has
got a role in low cardiac vagal activity in obese
person16. Though the relationship between
insulin resistance and parasympathetic
dysfunction is not clear, but several researchers
made various suggestions such as  high insulin
level or insulin resistance may cause damage to
autonomic nerves at any level of their reflex arc17,
insulin resistance may cause a deterioration of
microcirculation in many tissues including nerves
which may lead to neural ischemia17 and thereby
damage of cardiac parasympathetic nerve
terminals occur at the level of cardiac muscle or
vascular wall18.

Figure 1: Relationship between BMI and
valsalva ratio in the obese groups (n=80)

Figure 2: Relationship between BMI and HR
response to deep breathing in the obese groups (n=80)

Figure 3: Relationship between BMI and
30th:15thratio in the obese groups (n=80)

Parasympathetic Nerve Function and Obesity Article

J Bangladesh Soc Physiol. 2008 Dec;(3):50-54 53



Therefore, this  study concludes that obesity may
reduce parasympathetic nerve function.

Authors Affiliations:
*1. Shahin Akhtar,Lecturer, Physiology, Chittagong Medical

College, Chittagong     Bangladesh.
2. NoorzahanBegum, Professor and Chairman, Department

of Physiology, BSMMU. Email:noorzahanbeg@
yahoo.com

3. Sultana Ferdousi,Assistant Professor, Department of
Physiology, BSMMU.Email:sferdousiratna
@yahoo.com

4. Shelina Begum, Professor, Department of Physiology,
BSMMU.

5. Taskina Ali, Assistant Professor, Department of
Physiology, BSMMU. Email:taskinadr @gmail.com

*For correspondance

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Article Parasympathetic Nerve Function and Obesity

54 J Bangladesh Soc Physiol. 2008 Dec;(3):50-54