Panacea Journal of Medical Sciences 2021;11(1):77–81

 

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Panacea Journal of Medical Sciences

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Original Research Article

Point prevalence study of Hospital acquired infections in intensive care units of a
tertiary care teaching hospital in Uttarakhand

Geetika Rana1, Shantanu Aggarwal2,*, Dimple Raina1, V K Kataria1

1Dept. of Microbiology, Sri Guru Ram Rai Institute of Medical and Health Sciences, Patel Nagar, Dehradun, Uttrakhand, India
2Dept. of Community Medicine, Sri Guru Ram Rai Institute of Medical and Health Sciences, Patel Nagar, Dehradun,
Uttrakhand, India

 

 

A R T I C L E I N F O

Article history:
Received 10-09-2020
Accepted 09-10-2020
Available online 29-04-2021

Keywords:
Hospital acquired infections (HAI)
Intensive care units (ICUs)
Point prevalence study

A B S T R A C T

Background: Hospital acquired infections (HAI) are one the biggest challenges that the hospitals face in
patient care. The rates are even higher in patients admitted in intensive care units (ICUs). The true burden
of HAI in our state of Uttarakhand is still unknown.
Materials and Methods: This study was done to determine the prevalence rate of HAI in the ICUs of a
tertiary care teaching hospital in Uttarakhand. A series of two 1- day point prevalence studies was conducted
in our hospital in October 2017 and February 2018 in all the ICUs of our hospital. The study comprised of
92 patients admitted for more than 48 h in the ICU. The nurses were trained to collect the data collection
form according to Centers for Disease Control and Prevention definition of HAIs.
Results: Out of 92 eligible patients in ICU, 25 (27.2%) had acquired HAI. Overall a total of 37 HAIs
were identified as few patients had >1 type of HAI. Respiratory tract infection (RTI) had the highest
prevalence of 16.3% followed by Bloodstream infections (14.1%). Mechanical ventilation was found to
have maximum association with HAI (43.6%). This association was found to be statistically significant (p
= 0.002). Acinetobacter was the most common isolate (33%).
Conclusions: The highlight of this study was raising awareness about the current HAI rates in our hospital
and reinforcing the importance of correct infection control practices amongst the doctors and nursing staff.

© 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

Hospital acquired infections (HAI) are the infections
acquired by the patient during hospital care which are not
present or incubating at the time of admission. Infections
occurring more than 48 hours after admission are usually
nosocomial. 1 HAI rate of a hospital is a direct indicator of
quality and patient care. A patient comes to the hospital with
a lot of faith and hope. It is our duty to ensure that he doesn’t
go back with HAI.

HAIs are most commonly caused by multidrug resistant
(MDR) organisms that leads to a prolonged antibiotic
treatment, longer hospital stays, escalating hospital bills
and ultimately increasing morbidity and mortality rates.

* Corresponding author.
E-mail address: drshantanu.psm@gmail.com (S. Aggarwal).

Though the threat of HAI is a globally recognised and
prioritized phenomena but the scenario in Indian hospitals
still varies. Till now, majority of hospitals in India fail to
identify the threat of raising HAI rates and fail to implement
any preventive measures to rectify this problem. Inadequate
resources, no infection control surveillance teams, non-
existent/ poorly implemented antibiotic policy, injudicious
use of invasive devices and antibiotics, non – compliant
staff, poor hygiene and sanitation are some of the major
issues leading to high HAI rates in Indian hospitals. 2

In fact, as per a review by world health organisation
(WHO), the pooled prevalence of HAI in low income
countries is 10.1% which is double the prevalence in high
income countries. 3 Periodic and routine surveillance of HAI
is an essential first step to identify local problems and

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78 Rana et al. / Panacea Journal of Medical Sciences 2021;11(1):77–81

priorities. It also helps to monitor the implementation and
efficiency of infection control measures. This is essential
to prevent the emergence and spread of multidrug resistant
organisms. Routine surveillances also spread awareness on
the importance of infection control measures and helps
to increase the compliance of healthcare personals. Thus,
reducing the HAI rates in the hospital. 4

Prospective surveillance for HAIs are routinely done in
developed countries on national level. But very scanty data
is available for developing countries like India. Although,
continuous prospective surveillance is the best approach but
it requires comprehensive resources. The biggest advantage
of point prevalence study is that it can be done on a single
day with minimum resources. Along with the HAI rates,
it also provides data on associated risk factors. Such data
can then be used to focus any interventional programmes to
reduce the burden of disease. Such a study helps to identify
target areas in hospitals for quality improvement. Hence, in
a resource limited country, point prevalence surveys are an
efficient way for determining magnitude of HAI. 5

Intensive care units (ICUs) are the most vulnerable
sites for HAIs in a hospital. ICUs have patients with
serious medical ailments, complications and pre-existing
co-morbidities. They are commonly exposed to multiple
invasive devices and procedures which make them an easy
target for MDR organisms. Poor reflexes and low immunity
favour the multiplication of pathogens thus leading to
development of various HAIs.

Therefore, our study aimed to estimate the burden of
various HAIs in the ICUs of our hospital and associated risk
factors.

2. Materials and Methods

The point prevalence study of HAI was conducted in all the
ICUs of a 1500- bedded tertiary care teaching hospital in
Uttarakhand. The study was conducted in two phases: first
in October 2017 and next in February 2018 in all the ICUs.
Since this was the first time that such a survey was being
done in our hospital, it was decided to restrict the survey
to only ICUs due to restriction of human and financial
resources.

All admitted ICU patients who had been in the
hospital for at least 48 hours were included in the study.
Ethical approval was obtained from the Institutional Ethics
Committee. Nursing staff of all the ICUs was trained by
the department of Microbiology in a series of lectures.
They were taught about HAIs and how to identify them
according to CDC definitions. 6 They were shown how to
fill the data collection performa by the help of various real
case examples. The data collection form included patient’s
demographic details, admission date, consultant speciality,
ICU location, use of urinary catheter, any surgical procedure
(during last 30 days), mechanical ventilation, intravascular
catheter, antimicrobial therapy, presence of HAI and type of

HAI. Re-enforcement of the importance of infection control
measures was also established during these sessions. On
the day of the survey, a team comprising of microbiologist,
respective doctors and nurses incharges of various ICUs
collected data from all the eligible patients.

2.1. Statistical analysis

Data was entered and analysed in SPSS version 22.

3. Results

A total of 92 patients were included in this study (44
and 48 in each phase respectively). Males (58, 63%) were
more in number than females (34, 37%). Maximum patients
belonged to the > 60 years (37%) and <18 years (32.6%)
age group (Table 1). 45 patients were in Surgical ICU, 17 in
Neonatal ICU, 10 in Medical ICU, 10 in Paediatric ICU, 7 in
Cardiac ICU and 3 in Respiratory ICU. 85.9% patients had
intravascular catheter, 70.65% had urinary catheter, 42.4%
had mechanical ventilator and 35 had undergone a surgical
procedure.

Out of 92 eligible patients in ICU, 25 (27.2%) had
acquired HAI. Overall a total of 37 HAIs were identified
as few patients had >1 type of HAI. HAI prevalence was
found to be highest in NICU (47.1%) followed by SICU-II
(41.7%), MICU (30%), SICU-I (14.3%) and PICU (10%)
(Table 2).

Mechanical ventilation was found to have maximum
association with HAI (43.6%). This association was found
to be statistically significant (p = 0.002) (Table 3).
Respiratory tract infection (RTI) had the highest prevalence
of 16.3% followed by Bloodstream infections (14.1%), line
related (4.34%), others (4.34%), urinary tract infection (1%)
and Surgical site infection (0%) (Table 4).

Microbiological culture results were available for 29
HAI (78.3%). Acinetobacter was the most common isolate
(33%) followed by Klebsiella spp. (19%), Pseudomonas
spp. (9%), E.coli (9%), Proteus (5%), S. maltophila (5%),
Enterococcus spp. (5%), Enterobacter spp (5%) Serratia
spp. (5%) and Candida spp. (5%).

4. Discussion

Ours was the first point prevalence study conducted in
our hospital. Though there have been many similar studies
reported from India and abroad but none have been reported
from Uttarakhand. In our study the overall HAI prevalence
in ICUs was found to be 27.2%. In a similar point prevalence
study conducted in a tertiary care hospital in Pune, the
HAI rates in ICU was 25%. 7 Malhotra et al in their point
prevalence study of HAI in a tertiary care hospital in Delhi
reported a high prevalence of 33.3% in their ICUs. 8 A study
done in 7 cities of India reported HAI prevalence of 9.06
per 1000 ICU days. 9 Whereas, a study conducted by ECDC
in European acute care hospitals showed a prevalence



Rana et al. / Panacea Journal of Medical Sciences 2021;11(1):77–81 79

Table 1: Age – wise and gender-wise distribution

Age Group
Gender

Total
Male Female

Number (%) Number (%) Number (%)
0 – 18yrs 18 (31.0) 12 (35.3) 30 (32.6)
19 – 25yrs 4 (6.9) 1 (2.9) 5 (5.4)
26 – 40yrs 3 (5.2) 5 (14.7) 8 (8.7)
41 – 60yrs 12 (20.7) 3 (8.8) 15 (16.3)
>60yrs 21 (36.2) 13 (38.2) 34 (37.0)
Total 58 (100) 34 (100) 92 (100)

Table 2: HAI prevalence by ICU type
ICU Total Patients Patients With

Hai
HAI Prevalence (%) Odds Ratio 95% C.I

CCU 7 0 0.0 0.00 -
MICU 10 3 30.0 0.60 0.12 – 2.91
NICU 17 8 47.1 1.24 0.36 – 4.35
PICU 10 1 10.0 0.16 0.02 – 1.43
RICU 3 0 0.0 0.00 -
SICU- I 21 3 14.3 0.23 0.05 – 1.01
SICU- II 24 10 41.7 1.00
Total 92 25 27.2

ICU: intensive care unit, CCU: cardiac care unit, MICU: medical intensive care unit, NICU: neonatal intensive care unit, PICU: paediatric intensive care
unit, RICU: respiratory intensive care unit, SICU: surgery intensive care unit

Table 3: HAI prevalence by risk factors type
S. No Risk Factors No. of

patients
Presence
of HAI

HAI prevalence
%

Odds Ratio (95% CI) p Value

1 Surgery 35 11 31.4 1.41(0.55 – 3.58) 0.47
2 Urinary Catheter 65 16 24.6 0.65(0.24 – 1.74) 0.39
3 Mechanical Ventilator 39 17 43.6 4.35(1.63 – 11.62) 0.002
4 Intravascular Catheter 79 23 29.1 2.26(0.46 – 10.99) 0.30

Table 4: Number, percentage and prevalence of HAI, by type
HAI site Total % of total Prevalence (%)
SSI 0 0 0
UTI 1 2.7 1
BSI 13 35.13 14.1
RTI 15 40.54 16.3
Line Related 4 10.8 4.34
Others 4 10.8 4.34
Total 37 100

SSI: surgical site infection, UTI: urinary tract infection, BSI: bloodstream infection, RTI: respiratory tract infection

of 19.5% in their ICUs. 10 Aliki M et al in their point
prevalence study done in three Swiss hospitals reported
HAI prevalence in ICU as 26.2%. 11 Similar multicentic
study done in hospitals of Ireland reported a prevalence of
23.3%. 12 While a multicentre 1-day point prevalence study
in hospitals of Turkey reported a high prevalence of 48% in
their ICUs. 13

A review of literature done on similar studies showed
ICUs to have the highest burden of HAIs in hospitals.
This is because of many associated risk factors. Exposure
to medical devices, underlying immunocompromised

conditions, co morbidities, antimicrobial therapy, any
surgical procedures, prolonged stay are some of the
important risk factors. As a result patients in ICUs
suffer from increased morbidity, mortality and financial
costs. 7,9,14 Our study included all the ICUs of our hospitals
including neonatal and paediatrics. Neonatal ICU was
shown to have the highest HAI prevalence (47.1%) followed
by surgical ICU (41.7%) but this association was not found
to be significant.

In our study, respiratory tract infection (RTI) had the
highest prevalence of 16.3% followed by bloodstream



80 Rana et al. / Panacea Journal of Medical Sciences 2021;11(1):77–81

infections (14.1%). Our results were corroborated by Esen
S et al, in which lower respiratory tract infection (28.0%)
followed by bloodstream infection (23.3%) were the most
frequent types of HAI. 13 Dasgupta et al also reported
Pneumonia as the most frequent type of HAI (62.07%) in
their study. 15 Whereas, Nair et al in their study reported
surgical-site infections (SSIs) as the most common HAI
(23.94%) followed by hospital-acquired pneumonia (HAP)
(18.31%). 7 Malhotra et al reported UTI to be the most
common type of HAI in their study. 8 This difference could
be because of the fact our study was restricted only to
ICUs of our hospital whereas these studies also included the
wards.

We studied common risk factors for HAIs like surgery,
mechanical ventilation, urinary catheter and intravascular
catheter. It was found that mechanical ventilator had a
statistically significant association (p = 0.002) and the
highest odds of acquiring HAI (OR = 4.35, 95% Confidence
interval = 1.63 – 11.62). Our findings were also corroborated
with study by Nair et al which reported mechanical
ventilation having the highest odds of acquiring HAI
(18.57). 7 Other similar studies also reported mechanical
ventilation as a common risk factor for acquiring HAIs. 13

These results highlight the importance of following correct
practices during device insertion and maintenance.

Acinetobacter spp. was found to be the most common
causative agent of HAI (33%) followed by Klebsiella
spp. (19%), Pseudomonas spp. (9%) and E.coli (9%).
Similar results were reported in a study by Kolpa M et al
in which the most common isolated microorganism was
Acinetobacter baumannii (25%). 16 Acinetobacter spp is
a known multi drug resistant pathogen found commonly
in the hospital environment. On the other hand, Esen
S et al 13 reported Pseudomonas aeruginosa (20.8%) and
Dasgupta et al 15 reported Enterobacteriaceae (37.5%) as the
most frequently reported isolate in their respective studies.
Acinetobacter spp. isolated in our study was found to
be multi drug resistant. The antibiotic resistance pattern
showed 100% resistance to flouroquinolones, tetracycline
and 95% resistance to carbapenems. No resistance was
observed for polypeptides.

The highlight of this study was raising awareness about
HAI and correct infection control practices amongst the
nursing staff. Extensive training during every phase of the
study helped in re-enforcing the importance of following
correct infection control practices. This study provided a
baseline data for monitoring the prevalence of HAIs in
ICUs of our hospitals. It also highlighted the need to
strengthen the infection control practices especially during
device insertion and maintenance.

Ours was the first point prevalence study undertaken
at our 1500 bedded teaching hospital in Dehradun. There
were several limitations in our study. First, due to lack
of resources, the wards were excluded from the study.
Secondly, our study did not cover all risk factors leading to

HAIs, such as underlying disease, previous hospitalisations,
types of surgeries and admission to the emergency ward.
And finally, such one day studies might not show the true
rate of infections. But in resource limited set-ups, repeated
point prevalence studies is a practical and cheaper option
instead of continuous prospective surveillance.

In conclusion, the HAI prevalence rate in ICUs of our
hospital was 27.2% and RTI being the most common type
of HAI (16.3%). Mechanical ventilation was found to be
the biggest risk factor in acquiring HAI. Acinetobacter spp.
was the most common pathogen which was also multi drug
resistant. With this baseline information of our hospital,
adequate infection control methodologies can be designed
to decrease the HAI rate of our hospital.

5. Source of Funding

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

6. Conflict of Interest

The authors declare they have no conflict of interest.

References
1. Garner JS, Jarvis WR, Emori TG, Horan TC, Hughes JM. CDC

definitions for nosocomial infections, 1988. Am J Infect Control.
1988;16(3):128–40. doi:10.1016/0196-6553(88)90053-3.

2. Pittet D, Allegranzi B, Storr J, Nejad SB, Dziekan G, Leotsakos
A, et al. Infection control as a major World Health Organization
priority for developing countries. J Hosp Infect . 2008;68(4):285–92.
doi:10.1016/j.jhin.2007.12.013.

3. Report on the Burden of Endemic Health Care-Associated Infection
Worldwide. Geneva, Switzerland: WHO; 2011.

4. Haley RW, Culver DH, White JW, Morgan WM, Emori TG, Munn VP,
et al. The efficacy of infection surveillance and control programs in
preventing nosocomial infections in US hospitals. Am J Epidemiol.
1985;121:182–205.

5. Zhang Y, Zhang J, Wei D, Yang Z, Wang Y, Yao Z, et al. Annual
surveys for point-prevalence of healthcare-associated infection in a
tertiary hospital in Beijing. BMC Infect Dis. 2016;16:161.

6. CDC/NHSN. CDC/NHSN Surveillance Definitions for Specific Types
of Infections, July 2013 CDC/NHSN Protocol Clarifications; 2013.
Available from: www.cdc.gov/nhsn/pdfs/pscmanual/17pscnosinfdef_
current.

7. Nair V, Sahni AK, Sharma D. Point prevalence & risk factor
assessment for hospital-acquired infections in a tertiary care hospital
in Pune, India. Indian J Med Res. 2017;145:824–32.

8. Malhotra S, Sharma S, Hans C. Prevalence of Hospital Acquired
Infections in a tertiary care hospital in India. Int Inv J Med Med Sci.
2015;1(7):91–4.

9. Mehta A, Rosenthal VD, Mehta Y, Chakravarthy M, Todi SK, Sen
N, et al. Device-associated nosocomial infection rates in intensive
care units of seven Indian cities. Findings of the International
Nosocomial Infection Control Consortium (INICC). J Hosp Infect .
2007;67(2):168–74. doi:10.1016/j.jhin.2007.07.008.

10. European Centre for Disease Prevention and Control. Point prevalence
survey of healthcare- associated infections and antimicrobial use in
European acute care hospitals. Stockholm: ECDC; 2013.

11. Aliki M. Point prevalence of healthcare-associated infections and
antibiotic use in three large Swiss acute-care hospitals. Swiss Med
Wkly. 2018;148:14617.

http://dx.doi.org/10.1016/0196-6553(88)90053-3
http://dx.doi.org/10.1016/j.jhin.2007.12.013
www.cdc.gov/nhsn/pdfs/pscmanual/17pscnosinfdef_current
www.cdc.gov/nhsn/pdfs/pscmanual/17pscnosinfdef_current
http://dx.doi.org/10.1016/j.jhin.2007.07.008


Rana et al. / Panacea Journal of Medical Sciences 2021;11(1):77–81 81

12. Health Protection Surveillance Centre, Point Prevalence Survey of
Hospital Acquired Infections & Antimicrobial Use in European Acute
Care Hospitals: May 2012. Republic of Ireland Critical Care Report:
February . 2012;.

13. Esen S, Leblebicioglu H. Prevalence of nosocomial infections
at intensive care units in Turkey: A multicentre 1-day point
prevalence study. Scand J Infect Dis . 2004;36(2):144–8.
doi:10.1080/00365540410019156.

14. Kumar A, Biswal M, Dhaliwal N, Mahesh R, Appannanavar SB,
Gautam V, et al. Point prevalence surveys of healthcare-associated
infections and use of indwelling devices and antimicrobials over
three years in a tertiary care hospital in India. J Hosp Infect .
2014;86(4):272–4. doi:10.1016/j.jhin.2013.12.010.

15. Hazra A, Dasgupta S, Das S, Chawan NS. Nosocomial infections in
the intensive care unit: Incidence, risk factors, outcome and associated
pathogens in a public tertiary teaching hospital of Eastern India. Indian
J Crit Care Med. 2015;19(1):14–20. doi:10.4103/0972-5229.148633.

16. Kołpa M, Wałaszek M, Gniadek A, Wolak Z, Dobros W. Incidence,
Microbiological Profile and Risk Factors of Healthcare-Associated
Infections in Intensive Care Units: A 10 Year Observation in a
Provincial Hospital in Southern Poland. Int J Environ Res Public

Health. 2018;15(1):1.

Author biography

Geetika Rana, Assistant Professor

Shantanu Aggarwal, Assistant Professor

Dimple Raina, Associate Professor

V K Kataria, Professor and Head

Cite this article: Rana G, Aggarwal S, Raina D, Kataria VK. Point
prevalence study of Hospital acquired infections in intensive care units
of a tertiary care teaching hospital in Uttarakhand. Panacea J Med Sci
2021;11(1):77-81.

http://dx.doi.org/10.1080/00365540410019156
http://dx.doi.org/10.1016/j.jhin.2013.12.010
http://dx.doi.org/10.4103/0972-5229.148633

	Introduction
	Materials and Methods
	Statistical analysis

	Results
	Discussion
	Source of Funding
	Conflict of Interest