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Original article:
Preoperative Intravenous Paracetamol Reduces Postoperative Opioid Consumption in 

Laparoscopic CholecystectomyPatients - An Experience of A Tertiary Specialized Hospital in 
Bangladesh

Sultan Reza1, Tamanna Habib2, Mohammad Ifta Khiarul Hasan1, Anik Roy Chowdhury1, Saifuddin 
Mohammad Mamun3, SM Farhad Sazib4, SM Ahsanul Habib5

Abstract:
Background: Afferent blockade of nociceptive (pain) impulses by paracetamol can bein effect 
throughout intraoperative and postoperative period. Objective: To see the effect of preoperative 
intravenous paracetamol administration in laparoscopic cholecystectomy patients. Methods: 
This single blind, randomized, prospective, case-control studywas conducted in Department of 
Anesthesiology, Square Hospitals, Dhaka, Bangladesh, between July and December of 2014. A 
total of 60 adult patients scheduled for laparoscopic cholecystectomy under general anesthesiawere 
enrolled in this study. Patients were randomly allocated equally into two groups – A (cases) and B 
(controls), through a computerized random table, with 30 patients in each group. Patients of group 
A (cases) received intravenous paracetamol 10mg/kg (in 100ml of normal saline) 10 minutes before 
skin incision, while group B (controls) received only 100 ml of normal saline 10 minutes before 
skin incision. Postoperative pain score, duration of demand of first analgesic after operation and 
amount of opioid requirement were noted down. Results: The mean age of group A was 39.3±4.3 
years and in group B 37.4±4.4 years (P>0.05).The mean pain score after 1 hour of operation was 
4.4±0.3 in group A and 4.7±0.3 in group B, which reduced to 2.7±0.3 and 2.9±0.2 after 6 hours, 
then 1.7±0.2 and 1.8±0.2 after 12 hours and 1.0±0.1 and 1.1±0.2 after 24 hours respectively 
(P<0.05). Early demand of postoperative analgesic within 10 minutes was observed much less in 
the group A, compared to group B (P<0.001). The mean amount of pethidine required at 1st hour 
was 34.8±5.4 mg and 36.6±5.0 mg in group A and group B respectively, which increased up to 
77.3±10.7 mg and 92.1±8.5 mg respectively at 6th hour. However, the amount steeply decreased at 
12th hour to 29.4±5.4 mg and 28.1±4.7 mg respectively (P<0.001). The total amount of pethidine 
needed was significantly lower in the group A than that of group B (126.8±14.4 vs. 139.6±9.5 
mg; P<0.05). Conclusion: Preoperative load of intravenous paracetamol increases the duration of 
further analgesic requirement as well as reduces postoperative opioid consumption in laparoscopic 
cholecystectomy patients.
Keywords: Intravenous paracetamol, opioid consumption, pain score, laparoscopic cholecystectomy.

Correspondence to: Dr. Sultan Reza,Associate Consultant, Neuro ICU, Square Hospitals Ltd., 
Dhaka-1205, Bangladesh. E-mail: sultanrezamanha@gmail.com

1. Neuro ICU, Square Hospitals Ltd., Dhaka-1205, Bangladesh.
2. Department of Physiology, Answer Khan Modern Medical College, Dhaka-1205, Bangladesh.
3. Department of Anesthesiology, Square Hospitals Ltd., Dhaka-1205, Bangladesh.
4. Department of Medicine, Bangabandhu Sheikh Mujib Medical University (BSMMU), Dhaka-1000, 

Bangladesh.
5. Department of Anesthesia, ICU and Pain Medicine, Apollo Hospitals, Dhaka-1229. Bangladesh.

International Journal of Human and Health Sciences Vol. 05 No. 02 April’21 Page : 246-250
DOI: http://dx.doi.org/10.31344/ijhhs.v5i2.268

Introduction:
Preoperative analgesia by administering 
intravenous paracetamol (acetaminophen) is a 
method of analgesia that starts before the noxious 
stimulus comes into action, blocking peripheral 
and central nociception1. It is assumed that this 
afferent blockade of nociceptive (pain) impulses 
can be in effect throughout intra-operative and 
post-operative periods1,2.Any antinociceptive 

treatment inducing before surgery to prevent 
establishment of altered central afferent input 
from injuries and pain sensation by timing the 
analgesic’s peak pharmacodynamic effect with 
anticipated onset of pain or peak pain response, is 
termed as ‘preemptive analgesia’2,3. Paracetamol 
when given before tissue damage (pre-emptive) 
may play an important role in preoperative pain 
management by reduction of the inflammation 



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International Journal of Human and Health Sciences Vol. 05 No. 02 April’21

mechanism and decreasing sensitization of 
peripheral nocicptors2. Paracetamol is more 
safein comparison to risks related to opioid 
and can act on both central and peripheral pain 
pathways byinhibiting N-methyl-D-Aspartate 
receptors and blocking the cyclooxygenase 2 
(COX2) pathway of inflammation4,5. Paracetamol 
is known for itscapacity of ‘preemptiveanalgesia’ 
in different operative procedures, such as 
laparoscopic cholecystectomy6-8, total abdominal 
hysterectomy9,10, orthopaedic surgery11,12. All 
those studies were done in the western countries. 
However, no such reports are available in our 
country to date. Given the circumstances, the 
present study was designed with the aim tosee the 
‘preemptive effect’ of preoperative intravenous 
paracetamol administration in laparoscopic 
cholecystectomy patients in terms of how much 
it increases the duration of further analgesic 
requirement as well as reduces postoperative 
opioid consumption.As proper pain management, 
particularly postoperative pain management, is 
a major concern for the clinicians, the findings 
of the present study are expected to enrich 
our information pool in pain medicineas well 
asfacilitate to planpostoperative pain management 
more efficiently and cost effectively.
Methods:
A single blind, randomized, prospective, case-
control studywas conducted in Department of 
Anesthesiology of Square Hospitals, Dhaka, 
Bangladesh, one of the largest tertiary specialized 
hospitals in the country, between July and 
December of 2014. All the patients enrolled 
for laparoscopic cholecystectomy surgery in 
Department of Surgery of the same hospital 
during the study period. However, we adopted the 
convenient sampling technique. The patients were 
selected after fulfilling the following inclusion 
and exclusion criteria:
Inclusion Criteria:
1. Adult surgical patients for laparoscopic 

cholecystectomy who are mentally sound and 
able to understand the procedure; and

2. Fulfilled ASA Physical Status Classification I 
or II (according to Sweitzer)13. 

Exclusion criteria:
1. Unable to understand the procedure or 

declined consent;
2. Known allergy to paracetamol 

(acetaminophen);
3. History of usage of paracetamol, opioids, 

or any other NSAIDs for a long time (≥3 

months);
4. Uncontrolled hypertension or diabetes 

mellitus, severe renal or hepatic impairment 
or chronic obstructive airway disease.

Then a total of 60 adult patients were randomly 
enrolled in this study. Primary data collection was 
done after taking written informed consent from 
each patient who fulfilled the criteria. Demographic 
profile, pulse, blood pressure, body weight, 
height, waist circumference – all were recorded. 
Patients were randomly allocated equally into 
two groups – A (cases) and B (controls), through 
a computerized random table, with 30 patients in 
each group. Pre-anaesthetic check-up was done 
on the day before surgery. Each patient was kept 
fasting for at least 6-8 hours pre-operatively. 
Each patient was administered with Ringer’s 
lactate solution 30 minutes before the induction 
of anesthesia, and the infusion was maintained 
at 8-10ml/kg/hour throughout the operative 
procedure. After standard monitorization, baseline 
heart rate (HR), non-invasive blood pressure 
(BP), oxygen saturation (SpO2), and respiratory 
rate (RR) values were recorded. General 
anesthesia was intravenously induced with 5mg/
kg thiopental and 1μg/kg fentanyl, and the 
trachea was intubated with an endotracheal tube 
under muscle relaxant (0.5 mg/kg atracurium). 
Anesthesia was maintained with isoflurane (1.5%) 
in 50% nitrous oxide with oxygen. Patients of 
group A (cases) received intravenous paracetamol 
10mg/kg(100ml) 10 minutes before skin incision, 
while group B (controls) received only 100 ml 
of normal saline 10 minutes before skin incision. 
Each patient was sent to postoperative ward and 
observed for 24 hours. Both groups received 
opioid through patient-controlled analgesia 
(PCA)14 in postoperative ward and postoperative 
pain was assessed using Visual Analogue Scale 
(VAS)15. Total opioid dose measured in the both 
groups. Intensity of pain (VAS –painscore), 
duration between operation and first analgesic 
demand after operation and opioid requirement to 
manage postoperative pain – all were noted down 
in the data collection sheet.
The results were presented in tables. Quantitative 
data were expressed as mean and standard 
deviation and qualitative data were expressed as 
frequency and percentage. Statistical analyses 
were performed using SPSS (Statistical Packages 



International Journal of Human and Health Sciences Vol. 05 No. 02 April’21

248

for Social Sciences) version 17.0 (SPSS Inc, 
Chicago, IL, USA). Association between variables 
were done by unpaired Student ‘t’ test, Repetitive 
measure paired t-test and Chi-square (χ2) test. 
P value <0.05 was considered as statistically 
significant.
Results:
In the present study, 30 patients were enrolled in 
each group – group A (cases) and B (controls). The 
mean age of the patients of group A was somewhat 
higher than that of the group B (39.3±4.3 years vs. 
37.4±4.4 years). However, the difference was not 
statistically significant (P>0.05) (Table 1). Female 
patients were predominant in the both group A 
(63.33%) and groupB (66.67%). The mean pain 
score at 1 hour after operation was 4.4±0.3 in 
group A and 4.7±0.3 in group B, which reduced 
to 2.7±0.3 and 2.9±0.2 after 6 hours, 1.7±0.2 and 
1.8±0.2 after 12 hours and 1.0±0.1 and 1.1±0.2 
after 24 hours respectively (P<0.05 ) (Table 
2).Over half of the patients in the group A required 
postoperative analgesic (pethidine) at>20 minutes 
after operation (53.33%), while 40% required 
between 10-20 minutes and the rest (6.67%) within 
10 minutes. In contrast, majority (80%) of patients 
in the group B required postoperative analgesic 
within 10 minutes and rest (20%) between 10-
20 minutes. Early demand of postoperative 
analgesicwithin 10 minutes was observed much 
less in the groupA,in comparison togroupB, which 
was statistically significant (P<0.001)(Table 3). 
The mean amount of pethidine required at 1st 
hour was 34.8±5.4 mg and 36.6±5.0 mg in group 
A and group B respectively, which increased up to 
77.3±10.7 mg and 92.1±8.5 mg respectively, after 
6 hours. However, the amount steeply decreased 
at 12th hour to 29.4±5.4 mg and 28.1±4.7 mg 
respectively (P<0.001). The total amount of 
pethidine required was significantly lower in the 
group A than that of group B (126.8±14.4 vs. 
139.6±9.5 mg; P<0.05) (Table 4).
Table 1.Comparison of age between two groups

Age 
(in years)

Group A 
(n=30)

Group B 
(n=30) P value

<35 4 (13.33%) 10 (33.34%)

35-40 16 (53.33%) 13 (43.33%)

>40 10 (33.34%) 7 (23.33%)

Mean±SD 39.3±4.3 37.4±4.4 >0.05

Student’s t test was used to reach P value.

Table 2.Comparison of postoperative pain score 
(VAS) between two groups

Duration Group A(n=30)
Group B
(n=30) P value

After 1hour 4.4±0.3 4.7±0.3

<0.05
After 6 hours 2.7±0.3 2.9±0.2

After 12 hours 1.7±0.2 1.8±0.2

After 24 hours 1.0±0.1 1.1±0.2

Data presented as mean±SD; Repetitive measure 
paired t-test was used to reach P value.

Table 3. Comparison of first postoperative 
analgesic demand between groups

Duration 
(in min.)

Group A 
(n=30)

Group B
(n=30) P value

<10 2(6.67%) 24(80%) <0.001

10-20 12(40%) 6(20%)

>20 16 (53.33%) -

Chi-square (χ2) test was used to reach P value.

Table 4. Comparison of postoperative pethidine 
requirement between groups

Duration Group A (n=30) (in mg)
Group B 

(n=30) (in mg) P value

At 1st hour 34.8±5.4 36.6±5.0

At 6th hour 77.3±10.7 92.1±8.5 <0.001

At 12th hour 28.1±4.7 29.4±5.4

Total 126.8±14.4 139.6±9.5 <0.05

Data presented as mean±SD; Student’s t- test was 
used to reach P value.

Discussion:
Apart from affecting patients’ well-being and 
satisfaction from medical care, postoperative pain 
results in tachycardia and hyperventilation, gradual 
transition towards chronic pain, subsequent 
disruption in wound healing and insomnia – all 
together worsen the operative outcomes16. In the 
present study, our data showed that the preemptive 
intravenous paracetamol administration reduces 
opioid requirements through prolongation of 
duration of first demand of analgesia and a 
tremendous reduction in post-operative pain 
scores in our patients. Similarly, Salihoglu et al.6 
studied on a total of 40 patients (20 in each group) 



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International Journal of Human and Health Sciences Vol. 05 No. 02 April’21

and found that verbal and visual pain scores of 
the paracetamol group were significantly lower 
than control group (P<0.05). First morphine 
requirement and total administered morphine dose 
and duration of staying in recovery room were 
significantly decreased in the paracetamol group 
(P<0.05). Arslan et al.8 also found that time to first 
analgesic requirement was longer in paracetamol 
preemptive group, compared to placebo group 
(P<0.05), along with a significant reduction in total 
analgesic consumption and postoperative VAS pain 
scores (P<0.05).However,Goushehet al.7studied 
on 30 patients (15 in each group) and concluded 
that the pain score was lower in paracetamol 
preemptive group in comparison to placebo group 
(P=0.01), but the morphine consumption showed 
no significant difference between the groups (up 
to 6 hours postoperatively).Hence, our findings 
are more or less supported by Salihoglu et al.6, 
Gousheh et al.7 and Arslan et al.8.
The results of these controlled clinical studies, 
as mentioned above, demonstrated that the 
recommended therapeutic dose of intravenous 
paracetamol is safe and well tolerated, with 
a profile that supports the high reliability 
similar to placebo. The reduction in total opioid 
consumption may result from opioid sparing 
effect of preemptive load of paracetamol which 
was observed in those studies as well as in others’ 
studies6-12. Moreover, paracetamol is considered a 

safe drug with no or minimum gastrointestinal and 
central nervous system side effects like opioids 
and other NSAIDs4,5,17-19.
Limitations of the study:
This was a single-center trial. The study population 
was selected from an urban hospital setting for a 
short period of time, which was confined to Dhaka 
city only. Hence, the results of the study may not 
be generalized and does not necessarily reflect the 
overall picture of the country. Small sample size 
was another limitation of the present study.
Conclusion:
Our study revealed that preoperative load of 
intravenous paracetamol increases the duration 
of further analgesic requirement as well as 
reduces postoperative opioid consumption in 
laparoscopic cholecystectomy patients. However, 
we recommend further multi-center trials with 
larger sample and high technical back up.
Conflict of interest: None to disclose.
Ethical approval issue: The study was approved 
by the Institutional Ethical Committee of Square 
Hospitals Ltd., Dhaka, Bangladesh.
Funding statement: No funding.
Authors’ contribution: Concept and study 
design: SR; Data collection and compilation: SR, 
TH, MIKH, ARC, SMM, SMFS, SMAH; Data 
analysis: SR, SMFS, SMAH; Critical writing, 
revision and finalizing the manuscript: SR, TH, 
MIKH, ARC, SMM, SMFS, SMAH.



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