Panacea Journal of Medical Sciences 2020;10(3):299–302

 

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Panacea Journal of Medical Sciences

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Original Research Article

Cardiovascular and atherogenic risk profile in young Indian PCOS Patients

Padala Ravi Kumar1,*, Indira Palo2, S R Pattanaik3
1Dept. of Endocrinology, MKCG Medical College, Berhampur, Odisha, India
2Dept. of Obstetrics & Gynecology, MKCG Medical College, Berhampur, Odisha, India
3Dept. of Endocrinology, M.K.C.G. Medical College, Berhampur, Odisha, India

A R T I C L E I N F O

Article history:
Received 03-06-2020
Accepted 06-07-2020
Available online 29-12-2020

Keywords:
PCOS
CIMT and hsCRP.

A B S T R A C T

Aim: To assess the cardiovascular risk factors and carotid intima media thickness in young Indian PCOS
patients.
Materials and Methods : The study group included 25 PCOS patients who were diagnosed according to
Rotterdam criteria and 15 healthy controls who had normal menstrual cycles. The mean age and BMI in
PCOS (age-22.3±3years, BMI 28.1±5.4 kg/m2) and control (age 21.5±0.6yrs, BMI22.3±3.7kg/m2). In
all these patients detailed clinical examination and anthropometry including height, weight were taken and
BMI was calculated. Fasting blood glucose and serum insulin, lipids, high sensitivity C-reactive protein (hs-
CRP), follicle stimulating hormone, luteinising hormone, thyroid stimulating hormone, total testosterone
were tested. HOMA-IR was calculated according to formula FPG (mmol/l)* S. insulin (µ IU/ml)/22.5.
Carotid intima media thickness was measured on either side or mean of three readings taken as final value.
Results : Carotid intima media thickness was statistically significantly increased in PCOS patients
compared to controls (0.699±0.06 vs0.558±0.05mm, p<0.001). Serum insulin, HOMA-IR, hsCRP were
significantly more in PCOS compared control. However hsCRP was non-significant when BMI and waist
circumference were included in multivariate analysis.
Conclusion: Present study shows that patients with PCOS are at increased risk of atherosclerosis in young
Indian women.

© This is an open access article distributed under the terms of the Creative Commons Attribution
License (https://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and
reproduction in any medium, provided the original author and source are credited.

1. Introduction

Polycystic ovarian syndrome (PCOS) is the most common
endocrine disorder affecting 6-10% of women in the
reproductive age group. 1,2 It is characterized by chronic
anovulation, hyperandrogenism and or polycystic ovaries.
PCOS is associated with cardiovascular risk factors
including dysglycemia, hypertension, hyperinsulinemia
and dyslipidemia. This might substantially increases
cardiovascular risk in patients with PCOS. However a long
term study which followed CVD in 780 PCOS women
for 22 years did not show increased deaths due to CVD. 3

Meta-analysis by de Groot et al showed that women with
PCOS had two times the relative risk of coronary artery

* Corresponding author.
E-mail address: padala797@gmail.com (P. R. Kumar).

disease or stroke. 4 There were few studies assessing the
atherogenic risk in patients with PCOS in Indian women
and others. 5 Compared to Caucasians the PCOS population
in India are younger and leaner and more insulin resistant
and their atherosclerotic burden is unclear. 6 There are very
few studies comparing the CIMT and hsCRP. 7 Present
study aims to assess the carotid intima medial thickness
and atherogenic profile including hsCRP which is an
inflammatory marker.

2. Materials and Methods

This study was carried out in the Endocrine clinic of
MKCG Medical College, Berhampur between Jan 2019
to May 2019. Twenty five PCOS patients attending OPD
for various symptoms including hirsutism, acne, menstrual

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300 Kumar, Palo and Pattanaik / Panacea Journal of Medical Sciences 2020;10(3):299–302

irregularities were included in this study. The PCOS was
diagnosed by using Rotterdam criteria which included
any two of three-anovulation/oligomenorrhea, clinical
hyperandrogenism/ or biochemical hyperandrogenemia or
polycystic ovaries with> 12 follicles of sizes 4-8mm in
either ovary. 8 Fifteen age matched controls who were
having regular menstrual cycles and apparently healthy
included in the study. Participants who had history of
chronic cardiovascular, hepatic, renal, hematologic or
malignant disease or any acute medical illness were
excluded. Written informed consent was taken from all
participants and the study was approved by the institutional
ethics committee.

2.1. Anthropometry

In all these subjects detailed anthropometric measurements
including their height to nearest centimeter, weight(kg),
waist circumference (WC) at midpoint between iliac crest
and lower rib cage at the end of expiration were recorded.
The BMI was calculated by weight in Kg/Meter2.

2.2. Biochemical analysis

After an overnight fast of 8-12hr blood was collected
for fasting plasma glucose (FPG), serum insulin, total
cholesterol (TC), High density cholesterol (HDL),
triglycerides (TG). LDL was calculated using Friedewald
formula. FPG and lipids (TC, HDL, TG) were measured
using Hitachi Autoanalyser and serum insulin was
measured by ELISA kits. HOMA-1R was calculated by
using the formula- fasting serum insulin (µ IU/ ml) *
fasting plasma glucose (mmol/L)/22.5.Blood was collected
and stored at -70C for LH, FSH, Testosterone, Prolactin
and TSH. Hormone analysis was done on automated
chemiluminescent immunoassay.

CIMT was performed with 10 MHz Doppler probe by a
single operator blinded to subject details. The CIMT of the
posterior wall of common carotid arteries (1 cm proximal
to the origin of the bulb) was measured at the end of
the diastole. 9 Average CIMT was taken as the mean of 3
readings on each side.

2.3. Statistical analysis

The data were entered in SPSS-14 and analyzed. Continuous
variable were expressed as mean and standard deviation
(SD). The variables were compared between PCOS cases
and controls using the unpaired Student’s t test for normally
distributed continuous data and Mann–Whitney U test for
non-normally distributed data. Spearman’s correlation was
done to assess the relation between CIMT and clinical
and biochemical parameters. Variables showing significant
correlation were entered into stepwise linear regression to
assess the magnitude of their individual effect on CIMT. p
Value of >=0.05 was considered as significant.

3. Results

There were twenty-five PCOS patients and fifteen control
subjects in the present study. The baseline characters of both
groups were shown in Table 1. The mean age of PCOS
and control patients was not different (21.58±3.9 years vs
22.37± 8.6yrs respectively). BMI and waist circumference
were significantly higher in PCOS patients compared to
controls whereas no difference with regard to SBP or DBP.
One third (33%) of PCOS patients had acne, hirsutism in
46% and skin tags in 22%. The hormonal profiles quoted
elsewhere.

The biochemical and other parameters are shown in
Table 2. There was no difference in fasting plasma glucose
or serum lipids (TC, HDL, TG, LDL) statistically between
the groups. Serum insulin and HOMA-IR were significantly
higher in PCOS patients compared to control. HOMA-
IR was more than 3 times and serum insulin was more
than two times higher compared to control group. The
inflammatory marker hsCRP and atherogenic marker CIMT
were higher in PCOS. hsCRP was correlated positively with
BMI (Pearson correlation 0.580, p 0.012) and WC (Pearson
correlation 0.718, p 0.004). hsCRP which was significantly
higher in PCOS compared to controls lost significance when
controlled for BMI and WC in multivariate analysis (p
0.907). CIMT remained significant even after controlling for
confounding factors like BMI, WC, hsCRP and HOMA-1R
(p 0.05).

Table 1: Baseline characters of PCOS and control groups.
PCOS N=25 Control

N=15
P

Age (yrs) 22.3±3.7 21.5±0.6 0.48
Weight (kg) 67±15.8 53.8±9.5 0.009
BMI KG/M2 28.1±5.4 22.3±3.7 0.004
WC(CM) 90.7±12.8 72.5±9.4 <0.001
SBP mmhg 122.5±8.7 115±7.0 0.264
DBP 78.6±3.5 75±7.0 0.226

WC- Waist circumference, SBP-Systolic Blood Pressure, DBP- Diastolic
Blood Pressure, BMI-Body Mass Index

CIMT-Carotid Intimia Media Thickness, hsCRP- High
sensitivity C-reactive Protein, HOMA-IR-Homeostatic
Model assessment of Insulin resistance.

4. Discussion

The present study showed that in young PCOS patients
from India, CIMT was significantly higher even after
accounting for body weight, WC and insulin resistance.
Insulin resistance marker (HOMA-IR) as expected was
higher in PCOS compared to controls. hsCRP was non
significant when controlled other parameters like BMI and
WC.

CIMT is an early atherosclerotic marker. Some of the
previous studies shown that it is significantly increased in



Kumar, Palo and Pattanaik / Panacea Journal of Medical Sciences 2020;10(3):299–302 301

Table 2: Biochemical parameters in PCOS and control groups.
PCOS N=25 Control

N=15
P

FPG(mg/dl) 88±7.9 81±6.4 0.114
TC (mg/dl) 170.4±28.9 166±24 0.680
HDL(mg/dl) 39.5±6.8 44.5±10.2 0.132
TG(mg/dl) 144±78.3 106.5±27.1 0.127
LDL(mg/dl) 101.7±24.9 102.4±21.4 0.935
S. Insulin
µ IU/ml

21.9±4.0 6.4±3.6 <0.05

HOMA-IR
units

4.12±10.8 1.291±0.76 <0.05

hsCRP mg/dl 4.50±3.2 1.97±1.93 0.019*
CIMT(mm) 0.699±0.06 0.558±0.05 <0.001

*hsCRP when controlled for BMI and waist circumference was
nonsignificant (P 0.907)

PCOS patients and may also increase CVD risk. In a similar
study by Karoli et al, studying the early atherosclerotic
markers observed that CIMT was significantly higher in
50 patients with PCOS compared to age matched controls.
CIMT was positively correlated with age and BMI. 10 Garg
et al studying in 54 PCOS women from south India, also
observed significantly higher CIMT compared to controls
(0.51mm vs 0.44mm). 11 In a meta-analysis of 19 studies
including 1123 PCOS patients observed a mean difference
in CIMT was+ 0.072mm compared to controls for highest
quality studies. 12 This again underscores the importance
of early atherosclerotic marker in patients with PCOS.
However all studies are not in conformity. Meyer at al in a
study of 100 overweight women with PCOS and 20 matched
controls found no difference in CIMT between the groups. 13

Atherosclerosis is condition of chronic inflammation and
endothelial dysfunction in PCOS is possibly the result of an
inflammatory state. Various inflammatory markers like CRP,
TNF α , IL6 and adiponectin have been tested in PCOS with
inconsistent results. Present study showed that although
hsCRP increased in patients with PCOS but when BMI and
waist circumference was included in regression analysis, it
lost its significance. Similar to present study, Ghani et al
found no correlation between hsCRP and PCOS but was
related to BMI. 7 Un et al, in 75 PCOS patients and similar
number of controls found no correlation with hsCRP and. 14

Although dyslipidemia is common in PCOS, the present
study could not find significant lipid abnormalities between
the groups. Increased TG and LDL and low HDL is the
common abnormality found in PCOS patients and has been
attributed to hyperinsulinemia due to insulin resistance and
hyperandrogenemia. 15 The non significant levels in the
present study could be due to small number of patients
and young age group. It is well established that increase
in CIMT correlate with future cardiovascular outcomes.
For every 0.10 increase in CIMT, the risk of myocardial
infarction increases by 15% and stroke by 18%. 16 This puts
women with PCOS at a higher risk for future cardiovascular
events.

The limitations of the present study include small
number, lack of assessment of other inflammatory markers,
no body composition analysis.

5. Conclusion

Present study reaffirms that people with PCOS are at
increased risk of atherosclerosis and might need proper risk
factor evaluation to decrease the risk.

6. Source of Funding

No financial support was received for the work within this
manuscript.

7. Conflict of Interest

The authors declare they have no conflict of interest.

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Author biography

Padala Ravi Kumar, Assistant Professor

Indira Palo, Assistant Professor

S R Pattanaik, Associate Professor

Cite this article: Kumar PR, Palo I, Pattanaik SR. Cardiovascular and
atherogenic risk profile in young Indian PCOS Patients. Panacea J Med
Sci 2020;10(3):299-302.

http://dx.doi.org/10.4103/2230-8210.190552
http://dx.doi.org/10.4103/2230-8210.190552
http://dx.doi.org/10.1093/humupd/dmr046
http://dx.doi.org/10.1210/jc.2005-0011
http://dx.doi.org/10.1016/j.ejogrb.2016.06.022
http://dx.doi.org/10.1161/circulationaha.106.628875

	Introduction
	Materials and Methods
	Anthropometry
	Biochemical analysis
	Statistical analysis

	Results
	Discussion
	Conclusion
	Source of Funding
	Conflict of Interest