Panacea Journal of Medical Sciences 2021;11(3):395–400

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Panacea Journal of Medical Sciences

Journal homepage: http://www.pjms.in/  

 

Original Research Article

Alterations in pulmonary function following laparoscopic cholecystectomy

Malaya Kumar Patel1, Sheela Ekka1, Mahendra Ekka1,*, Pujarini Beuria2,
Sapan Kumar Jena1

1Dept. of Anaesthesiology, Veer Surendra Sai Institute of Medical Sciences and Research, Burla, Odisha, India
2Dept. of Anaesthesiology, S.C.B. Medical College and Hospital, Cuttack, Odisha, India

 

 

A R T I C L E I N F O

Article history:
Received 12-01-2021
Accepted 13-03-2021
Available online 24-11-2021

Keywords:
Lungphysiology
Pulmonary function tests
Laparoscopic
Cholecystectomy

A B S T R A C T

Background: In laparoscopic cholecystectomy, inflammation of the punctured abdominal wall or gall
bladder bed, carbon dioxide pneumo-peritoneum and intraoperative patient position has significant effect
in the pathogenesis of pulmonary dysfunction. The objective of this study is to detect any changes in
pulmonary functions following laparoscopic cholecystectomy using bedside spirometry and to detect
degree of impairment of pulmonary function, their complications and the time taken for recovery of post-
operative spirometry measurements to the preoperative (baseline) values.
Materials and Methods: This was a prospective observational study in which the preoperative
and postoperative spirometry of 70 patients undergoing laparoscopic cholecystectomy under general
anaesthesia was compared. Pre-operative spirometry was performed to record the baseline values. Patients
who had normal FVC, FEV1, PEFR values were included in the study. Those who were not able to perform
acceptable maneuver were excluded from the study. Pulmonary function testing was done twice following
surgery on postoperative day one and on postoperative day three. Adequate pain relief was given to attain
a VAS score of less than 40. Spirometry values were compared using paired t-test. P-value of <0.05 was
considered statistically significant.
Results: Significant differences were found for the Forced Vital Capacity variable (p=0.001), Forced
Expiratory Volume in the first second (p=0.020) and peak expiratory flow rate (p=0.000) between the pre-
and immediate postoperative periods, indicating restrictive ventilator dysfunction.
Conclusion: Light restrictive respiratory disturbances were observed after laparoscopic cholecystectomy,
wih rapid recovery of pulmonary function, which may lower postoperative pulmonary morbidity and
mortality.

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1. Introduction

Changes in pulmonary function account for significant
morbidity andmortality following surgery. 1 Abdominal
surgery results in the greatest depression in pulmonary
function which has been reported to be as high as 70% 2

and micro atelectasis is regarded as a uniform occurrence.
The most common post-operative complicationsare

* Corresponding author.
E-mail address: mekka15071976@gmail.com (M. Ekka).

atelectasis, pulmonary edema, pneumonia, pulmonary
thromboembolism and acute exacerbation of COPD. They
increase mortality, morbidity, length of hospital stay&
overall medical cost.

Although laparoscopic cholecystectomy results in
postoperative pulmonary complication, but there is faster
recovery of postoperative pulmonary function and less
atelectasis and hypoxemia than open cholecystectomy.

Inflammation of the punctured abdominal wall or gall
bladder bed, or both, carbon dioxide pneumo-peritoneum

https://doi.org/10.18231/j.pjms.2021.079
2249-8176/© 2021 Innovative Publication, All rights reserved. 395



396 Patel et al. / Panacea Journal of Medical Sciences 2021;11(3):395–400

or intraoperative patient position has significant effect
in the pathogenesis of this pulmonary dysfunction. 3 The
impact of upper abdominal surgery on respiratory function
parameters, including lung volumes, flow rates, arterial
blood gases and diaphragmatic function, was investigated
in several studies. 4,5

The aim of my study is to detect degree of impairment of
pulmonary functions and complications after laparoscopic
cholecystectomy using bedside spirometry, so that early
diagnosis and interventions may decrease post-operative
morbidity and mortality.

2. Materials and Methods

1. Spirometer for pulmonary function testing (Easy One)
2. Pulse oximeter for measuring SPO2

2.1. Spirometry specifications

1. Easy One(T M ) DIAGNOSTIC 6.5(c) ndd 2000-2010
2. Product of ndd Medical technologies

2.2. Test specifications

1. Value selection- Best trial
2. System interpretation- GOLD 2008 / HARDIE
3. Predicted- KNUDSON 83
4. Paediatric predicted- POLGAR

2.3. Methodology

After obtaining institutional ethical approval, this
prospective observational study was carried out on a
total of 70 patients of either sex between 20-60 years
of age, BMI between 18.5-29.9 kg/m2, belonging to
ASA physical status I and II, scheduled for elective
laparoscopic cholecystectomy under general anaesthesia.
Written informed consent was obtained from all the patients
before the surgery. The patients were subjected to detailed
clinical examination and routine investigations to exclude
any systemic disorder. Emergency surgery, patients with
cardio-respiratory diseases, pregnant women, patients with
smoking history, duration of surgery exceeding 60 minutes
were the exclusions.

Based on previous studies, 6 a sample size of 53 was
required considering an error margin of 5% and a power of
80%. Considering a dropout rate of more than 10%, a total
of 70 patients were enrolled in the study.

Patients have been explained about the study procedure,
benefits, importance of post-op lung function and the need
to do spirometry in the immediate postoperative period.
Then the pre-op spirometry was performed to record the
baseline values. Patients who had normal FVC, FEV1,
PEFR values only were included in the study. Patients who
were unable to perform acceptable maneuver excluded from

the study. Following a standardized anesthetic protocol,
all the cases were done under general anaesthesia with
inj. Glycopyrrolate 0.04mg/kg, inj. Midazolam 0.05mg/kg
and inj. Nalbuphine 0.1mg/kg as premedication. Inj.
Diclofenac 1.5mg/kg was given as additional intra-op
analgesia. Induction was done with inj. Propofol 2mg/kg
and inj. Succinylcholine 1.5mg/kg. Endotracheal intubation
was done with appropriate size cuffed endotracheal
tube. Adequate plane of anaesthesia was maintained
with sevoflurane (1%-2%) and N2O in a 50% mixture
with O2. Adequate muscle relaxation attained by using
inj. vecuronium in standard prescribed dosage. ETCO2
monitoring was done for all patients to ensure adequate
ventilation and CO2 elimination. The beginning of surgery
corresponded to the moment of the skin incision and the end,
the last stitch of the skin suture.

The patients were all operated on by the same surgeon
using the similar surgical technique. Incision was given at
the upper edge of the umbilical scar in supine position.
Intra-abdominal pressure was maintained at a pressure ≤ 12
mmHg throughout the laparoscopic procedure. At the end of
procedure, abdomen was compressed to release the residual
gas from peritoneum.

The patients underwent serial Spiro metric
measurements. The first test was carried out pre-operatively.
The second test was within the first 24 post-operative hours.
And third test was undertaken on post-operative day3. Most
patients were discharged from hospital on postoperative
day 3, so we could not perform spirometry after day
3. The spirometry was always conducted by the same
professional – a respiratory function technician – with
the same equipment: Easy OneTM DIAGNOSTIC 6.5
software pc based portable spirometer, which can measure
pulmonary flow and volume parameters and is validated
by the American Thoracic Society (ATS). The device,
in addition to generating flow-volume and volume-time
curves, discriminated 12 spirometric variables and the
results were printed out automatically. The parameters
were analyzed based on Knudson’s regression equation.
Preparation for each spirometry session included calibrating
the spirometer through an appropriate calibration syringe,
adjusted to ambient temperature (25ºC to 40ºC) and
atmospheric pressure.

The individual variables height (in cm), weight (in kg),
gender and date of birth were recorded and stored in the
spirometer. After 10 minutes of rest in a calm environment,
each patient underwent three valid and reproducible
tests. The spirometry reports were always provided and
interpreted by the same person, a specialist in lung function
tests, blinded to the patients’ clinical history. The variables
FVC, FEV1 and PEFR were analyzed individually, pre-
and postoperatively, up to the point when their values
normalized (80 % of the pre-calculated theoretical value for
FVC, FEV1 and PEFR). The hypothesis that means between



Patel et al. / Panacea Journal of Medical Sciences 2021;11(3):395–400 397

groups were equal before and after surgery was tested
through paired t-test. The value of P<0.05 was considered
statistically significant.

Inj. tramadol at a dose of 1mg/kg intramuscular was
given for postoperative analgesia. Patients were followed
up to post-op ward where first post-op spirometry was done
within first 24hrs after assessing the pain scale. VAS (visual
analogue scale from 0-100) was used to assess the pain
score. VAS score less than 40 was taken as acceptable
score since it indicates minimal pain which won’t affect the
performance of spirometry. When pain scores were more
than 40, intravenous paracetamol was given at a dose of
15 mg/kg body weight over 20 min as infusion. Once pain
score is within acceptable limits post-op spirometry was
performed at the bedside. Those patients whose pain score
was more than 40 excluded from the study.

3. Results

Fig. 1: CONSORT Diagram

A total of 60 patients were analyzed after exclusion due
to various reasons. Data were collected in a prescribed
format and tabulated in Microsoft excel 2016 and
analyzed using SPSS version 23. Normality assumption
was examined by the Shapiro-wilk W test. According
to normality testing, the variables used in analysis were
expressed in mean ± SD. Descriptive statistics were
presented in the form of frequency, percentages, mean ± SD,
minimum maximum, the difference between mean of three
PFT parameters (FEV1, FVC, PEFR) of the same study
group at different time (i.e. pre operatively, on postoperative
day1 and on postoperative day3) were evaluated using
one way repeated measure ANOVA after fulfilling the

parametric tests prerequisites. Statistical significance was
set at P< 0.05.

The percentage of participants in 20-30yrs, 30-40yrs, 40-
50 years, 50-60 years age group are 31.7%,35.0%, 26.7%,
6.7% respectively with a mean age of 36.3 years and the
range was 21-58yrs.

Majority of the patients in this study group belonged to
the female gender group (n=38, 63.3%). Male gender was
only 36.7%.

Majority of the patients in this study group belonged
to the 51-60kgs weight, class interval (n=21, 35%) with a
mean weight of 57.6kgs.Minimum weight of the patient was
42kg and maximum was 85kg. Height of the patients in this
study group was between 142 to 170 cm with maximum
percentage in 151-160cms height (n=24, 40%) & mean
height of157.1cms. BMI range of the patients was 19-29
kg/m2 with a mean of 23.3 ± 2.9 kg/m2.

Fig. 2: Comparison of mean of FEV1 in PREOP. and post op.
period

Mean FEV1 values preoperatively, post operatively on
day 1 and post operatively on day 3 are 2.63 L, 2.16L
& 2.54L respectively. The results of ANOVA indicated a
significant effect of time on FEV1 values, F value=79.271,
P value<0.05. It means that there is significant change in
FEV1 value of patient before and after operation.

Follow up comparisons indicated that each pair wise
difference was significant, i.e. P< 0.05. There is a
significant decrease in FEV1 value on day 1 following lap
cholecystectomy as well as on day 3 following operation.
But FEV1 on day 3 post op is significantly higher compared
to day 1 post op. Pre- operative FEV1.>Post op day 3 FEV1
(96.4%)> post op day 1 FEV1 (81.9%).

3.1. Distributionof FVC values during PRE OP,

One way repeated measure ANOVA test was used to
compare the mean FVC values of total 60 patients before
operation, on day 1 and day 3 following operation. The
test shows a statistically significant difference in mean FVC



398 Patel et al. / Panacea Journal of Medical Sciences 2021;11(3):395–400

Table 1:
Mean Value Preoperative Post-operative day 1 Post-operative day 3
FEV1 2.635 2.160(81.9%) 2.541(96.4%)
FVC 3.029 2.487(75.6%) 2.885(95.2%)
PEFR 6.509 5.393 (82.8%) 6.159 (92.6%)

Fig. 3: Comparison of mean of FVC values during pre op, post op
day 1 and post op day 3

values when compared at three different time periods with F
value= 74.05, P value < 0.05 and eta2= 0.719.

Further pair wise comparison was done between each
possible pair. It is clearly evident from the above table that
mean FVC value in preoperative period is more than mean
FVC in postoperative day 1 and day 3 and the difference in
the mean values are significant.

However, the mean FVC value during post op day 1
is lower as compared to post op day 3 and the difference
in is also significant.(P value<0.05) So, the conclusion
is there is a significant change in FVC values after
lap cholecystectomy. However, FVC parameter gradually
improves on day 3 following operation. Pre-op FVC> Post
op day 3(75.6%)> Post op day 1(95.2%)

One way repeated measure ANOVA test was used to
compare the mean PEFR values of total 60 patients before
operation, on day 1 and day 3 following operation. The test
shows a statistically significant difference in mean PEFR
values when compared at three different time periods with F
value=118.14, P value < 0.05.

Here difference of mean of PEFR between each group
was compared, where 1=preoperative, 2= postoperative day
1, 3= postoperative day 3 and I time is the reference group
to which other group (J time) are compared

Based on estimated marginal means

1. The mean difference is significant at the 0.05 level.
2. Adjustment for multiple comparisons: Bonferroni.

Further pair wise comparison was done between each
possible pair. It is clear from the above table that mean

Fig. 4: Comparison of mean of PEFR values during PREOP, post
op day 1 and post op day 3

PEFR value in preoperative period is more than mean
PEFR in postoperative day 1 and day 3 and the difference in
the mean values are significant.

However, the mean PEFR value during post op day 1 is
lower as compared to post op day 3 and the difference in is
also significant.(P value<0.05).

So, the conclusion is there is a significant change in
PEFR values after lap cholecystectomy. However, FVC
parameter gradually improves on day 3 following operation.

Pre-op PEFR> Post op day 3 PEFR (94.6%)> Post op
day 1 PEFR (82.8%).

Statistically significant differences occurred in all the
three variables when preoperative and postoperative values
were compared (P=0.001for FVC, P=0.020 for FEV1,
P=0.000 for PEFR). Follow up comparisons indicated that
each pair wise difference was significant, i.e. P< 0.05. There
is a significant decrease in FEV1 and FVC value on day 1
following lap cholecystectomy. But FEV1 on day 3 post op
is significantly higher compared to day 1 post op. (Pre.>Post
day3> post day 1).

4. Discussion

Laparoscopic surgery has been a revolutionary alternative
to many open surgical procedures. For the anaesthetists,
“minimally invasive” surgery requires maximally attentive
anaesthesia. Pneumoperitoneum in conjunction with
extreme patient positioning induces transient, but
significant, multiorgan derangements that require
short-term manipulation of physiology to minimize



Patel et al. / Panacea Journal of Medical Sciences 2021;11(3):395–400 399

Table 2: Pairwise comparisons of mean fev1, VC & PEFR values during pre-operative, postop day1 and post op day 3
(I)
Time

(J)
Time

Mean
Difference FEV1 (I-J)

FEV1
Sig.

Mean
Difference
FVC(I-J)

FVC Sig. Mean
Difference PEFR

(I-J)

PEFR
Sig.

1
2 .475* .000 .542* .000 1.116* .000
3 .093* .020 .144* .000 .350* .000

2
1 -.475* .000 -.542* .000 -1.116* .000
3 -.381* .000 -.398* .000 -.766* .000

3
1 -.093* .020 -.144* .000 -.350* .000
2 .381* .000 .398* .000 .766* .000

complications. Subjectively there is no doubt that patients
recover more quickly from laparoscopic procedure,
and one of the reasons for this smoother recovery may
be this procedure’s diminished effect on postoperative
pulmonary function compared with previously standard
open procedure. Laparoscopic cholecystectomy does not
damage the abdominal muscles and diaphragmatic function
is significantly less affected compared to the open method.
This procedure is accompanied by a lower impact on
respiratory function and better oxygenation.

Post operatively all the patients had a significant fall in
FVC values measured on postoperative day 1. The reduction
was significantly more, from mean pre-op FVC 3.029 L
to post-op FVC 2.487 with a reduction of 24.4 %. The
second post-op FVC done on postoperative day3 revealed
improvement in capacities. The FVC recovered to 2.885 L
which is just 4.8% less compared to pre-op values. Hence
FVC measurements after lap-cholecystectomy were found
to be significantly low both during first and third post-
operative day, this is similar to the findings published by
Hasukic S et al, S.M.Ravimohan et al. 7,8

Post operatively all the patients had a significant fall in
FEV1 values. The pre-op mean FEV1 value of 2.635 L was
reduced to 2.160 L on postoperative day1, with a reduction
of 18.1% which later improved significantly to 2.541 L on
postoperative day3,is again a reduction of 3.6 % compared
with the pre-op value. The mean FEV1 values after
laparoscopic cholecystectomy were significantly reduced
both on first and third postoperative day, this is like the
findings reported by Hasukic S et al. and Suter M. et al. 7

PEFR value in mean was of 6.5 L/min in preop which
decreased to 5.39 L/min with a reduction of 17.2% on
postoperative day1. It later recovered well at 6.16 L/min
measured on postoperative day 3 which was still 5.4%
less compared with pre-op values. The PEFR values were
significantly reduced in laparoscopic cholecystectomy both
during first and third postoperative day. This is like the
findings reported by Hasukic S et al. 7

In the present study, mild restrictive ventilatory defects
were observed, with FVC, FEV1 and PEFR reduction,
when these three variables were compared pre- and
postoperatively, and the decrease in FVC is more than that
of FEV1. Therefore, it can be concluded that laparoscopic

cholecystectomy also results in postoperative spirometric
changes, an observation that agrees with several other
scientific journals. However, in the present study, the more
pronounced decreases in FVC, FEV1 and PEFR were
24.4%, 18.4% and 17.2% respectively on postoperative day
1, in relation to the baseline values.

But on postoperative day 3, the more pronounced
decrease in FVC, FEV1 and PEFR are 4.8%, 3.6% and
5.4% respectively. This implies that postoperative day3
spirometric values are comparable to normal tests when
compared with the predicted values. Reports were found
of scientific observations like those made in the present
study. More marked alterations are usually found, even in
laparoscopies, with decreases between 20% and 30% 9 in
all the variables or even more expressive reductions, greater
than 40%.

Several studies 10,11 showed that for patients who
underwent upper abdominal surgery, compared with
the abdominal cavity, the thoracic wall provided major
postoperative contributions in respiratory movement.
Showing that after upper abdominal surgery, (1) the
artificial stimulation of phrenic nerves produced normal
trans-diaphragmatic pressure; and (2) diaphragmatic
pressures developed during inspiration were shown to be
decreased. As for why general anaesthesia and analgesia
had no effects, the diaphragmatic activity is not affected by
perceptible postoperative pain. However, a reflex inhibition
regarding diaphragmatic motility seems to occur with the
aid of the abdominal region nerves being activated during
the operation.

Thus, in the present study, reduced diaphragm
dysfunction a characteristic of laparoscopic procedures,
along with shorter anaesthetic and surgical time, were the
main determinants for minimally altered postoperative
spirometric values in relation to the preoperative
values. Thus, the spirometric variables decreased in
the immediate postoperative period when compared with
the preoperative values, and in the following measurement
(third postoperative day), values were already equivalent
to those of the preoperative period. Several studies pointed
to the recovery of pulmonary function after laparoscopic
cholecystectomy between 8 to 10 days 12,13 which finds
no support in the present study. The difference is likely



400 Patel et al. / Panacea Journal of Medical Sciences 2021;11(3):395–400

explained by the reduced operative time involving less
tissue injury and diaphragm dysfunction.

5. Conclusion

From the above study, we concluded that there is
mild restrictive pulmonary dysfunction after laparoscopic
cholecystectomy, which manifested as significant decrease
in FVC, FEV1 and PEFR in postoperative day1 and day3 in
comparison with preoperative (baseline) values. But there
was a faster recovery of pulmonary functions, which was
evident by the rapid improvement of FVC, FEV1 and PEFR
as seen in postoperative day 3.

6. Conflict of Interest

The authors declare that there are no conflicts of interest in
this paper.

7. Source of Funding

None.

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Author biography

Malaya Kumar Patel, Associate Professor

Sheela Ekka, Assistant Professor

Mahendra Ekka, Assistant Professor

Pujarini Beuria, Senior Resident

Sapan Kumar Jena, Senior Resident

Cite this article: Patel MK, Ekka S, Ekka M, Beuria P, Jena SK.
Alterations in pulmonary function following laparoscopic
cholecystectomy. Panacea J Med Sci 2021;11(3):395-400.