Hemodynamic Changes During Laproscopic
Cholecystectomy at Lumbini Medical College

Nil Raj Sharma,a,d Pradeep Timalsena,b,d Sundip DC,c,d Sarad Pantheec,d

—–—————————————————————————————————————————————

ABSTRACT:
Introduction: Laparoscopic cholecystectomy is preferred to open cholecystectomy for several reasons. Patients 
can be discharged home earlier. They have less pain in comparision to open cholecystectomy. This study aims 
to investigate the pneumoperitoneum-induced haemodynamic and ventilatory changes in patients undergoing 
laparoscopic cholecystectomy (LC). Methods: It was a prospective study comprising 400 patients of the age 15 years 
to 75 years of both sex (males n=80 and females n=320). The study was conducted in Lumbini Medical College Palpa 
over the two year period in Jan 2010 and Dec 2012. The variables recorded were: Mean arterial pressure (MAP), 
End-tidal CO2, Peak and plateau airway pressures and heart rate. Data were collected immediately after induction 
of anesthesia at five minutes after peritoneal insufflations and tilting the table into 30° head-up position at 10 min 
and finally at 10 min after exsufflation. Results: There was decrease in MAP after head up position but there was 
little change after pneumoperitoneum. More the weight of the patients, more is the increased airway pressure. The 
end tidal CO2 remained increased after pneumoperitoneum. Conclusion: Peritoneal insufflation of CO2 to create the 
pneumoperitoneum and tilting the patient to the head-up position necessary for laparoscopy induces intraoperative 
ventilatory and hemodynamic changes that complicate anesthetic management of laparoscopy.

Keywords: capnography • haemodynamic changes • laproscopic cholecystectomy • pneumoperitoneum
———————————————————————————————————————————————

___________________________________________________________________________________

a - Associate Professor
b - Lecturer
c - Medical Officer
d - Department of Anesthesiology and Critical Care
     Lumbini Medical College Teaching Hospital, Palpa, Nepal

Corresponding Author:
Dr. Nil Raj Sharma
e-mail: nilrajnp@gmail.com

How to cite this article:
Sharma NR, Timalsena R, DC Sundip, Panthee S. Hemodynamic 
changes during laproscopic cholecystectomy at Lumbini Medical 
College. Journal of Lumbini Medical College.  2013;1(1):43-5. 
doi:10.22502/jlmc.v1i1.13.
___________________________________________________________________________________

J. Lumbini. Med. Coll. Vol 1, No 1, Jan-June 2013

Original Research Article

jlmc.edu.np

https://doi.org/10.22502/jlmc.v1i1.13

INTRODUCTION:
Laparoscopic Cholecystectomy (LC) is 

preferred to open cholecystectomy (OC) for several 
reasons.1 Patients are characterized by physiological 
alterations in circulatory and respiratory functions 
during LC.2 Old patients are more prone to 
haemodynamic changes than are younger 
patients.3 Several investigators have studied on the 

haemodynamic consequences of a LC in ASA I-II 
young and healthy patients.4-6 There is alterations 
in the ventricular loading conditions resulting from 
the increased intra abdominal pressure.7 All these 
studies indicated that haemodynamic alterations 
are potentially deleterious in patients such as 
elderly patients with limited cardiac reserve. Also, 
the pneumoperitoneum in a head-up position is 
responsible for ventilatory changes.8 The respiratory 
behaviour in the elderly during this type of surgery 
is unknown.9

METHODS:
All 400 patients between 15 to 75 years 

of age with ASA grade I-II who underwent LC 
were included in this study. Informed consent and 
weight of all the patients were taken before surgery. 
All patients were premedicated with 0.15 mg/kg 
diazepam the day before surgery. General anesthesia 
(GA) was induced with 0.8mg/kg pethidine, 5 mg/
kg of thiopentone sodium. Injection vecuronium 

43



J. Lumbini. Med. Coll. Vol 1, No 1, Jan-June 2013 jlmc.edu.np

Sharma NR. et al. Hemodynamic changes during laproscopic cholecystectomy

0.1 mg/kg was given to facilitate tracheal intubation 
and maintenance of anaesthesia. After tracheal 
intubation, GA was maintained with nitrous oxide 
(60%) in oxygen and halothane. Non invasive 
arterial blood pressure, electrocardiogram (ECG), 
heart rate, capnography, and pulse oximetry were 
monitored during surgery. The expired end-tidal CO2 
was monitored continuously by a mainstream or side 
stream analyzer. During laparoscopy, intraabdominal 
pressure was maintained at 12 to 14 mm Hg by a 
CO2 insufflator. The variables recorded were: Mean 
arterial pressure, End-tidal CO2, Peak and plateau 
airway pressures and heart rate. Data were collected 
immediately after induction of anesthesia at 5 min, 
after peritoneal insufflations and tilting the table into 
30° head-up position at 10 min (routine procedure 
during LC) and finally at 15 min after exsufflation.

RESULTS:
 The maximum number of cases were between 
the age 26-35 (24%) in females and 46-55 (4.75%) 
in males. There were total of 320 (80%) females and 
80 males (20%). The male: female ratio is 1:4. Table 
1 shows that higher the weight of the patients more 
the change in airway pressure. The change in airway 
pressure after CO2 insufflation was seen maximum 
in patients > 80 kg (average change of 8 cm of H2O). 
This finding was statistically significant p<0.05. 
 Table 2 shows that the heart rate and the 
mean arterial pressure were increased after induction 
of anaesthesia in all patients. This increase was 
statistically not significant, p>0.05. 

Table 1:Average change in airway pressure according to weight
             of the patients
Weight 
(kgs)

Airway pressure 
before insufflation

Airway pressure 
after insufflation

mean 
change

>80 22 30 8 (36.4%)
71-80 20 25 5 (25%)
61-70 19 23 4 (21%)
50-60 17 19 2 (11.7%)
<50 16 17 1.3 (8.1%)

Table 2: Hemodynamic changes before pneumoperitoneum
              (Mean value)
Hemodynamics Before induction After induction

Mean arterial 
pressure 82

89 
(8.5% increased)

Heart rate 73 84 (15.07% increased)

Table 3: Hemodynamic changes after pneumoperitoneum (Mean value)
Hemodynamics Before induction At 5 minutes At 10 minutes End of surgery
Mean arterial pressure 
(mm Hg) 82

88 
(increased by 7.31%)

93 
(increased by 13.41%)

108 
(increased by 31.70%)

Heart rate (per minute) 73 79 (increased by 8.22%) 76 (increased by 4.11%) 94 (increased by 28.76%)

Table 4: Ventilatory changes (Mean of 400)
Airway pressure 
(cm H2O)

After induction Head up position Pneumoperitoneum at 5 minutes
Pneumoperitoneum 

at 10 minutes

Peak 17 14 (Decreased by 17.64%)
23 

(increased by 35.3%)
24 

(increased by 41.18%)

Plateau 11 10 (Decreased by 9.1%)
19 

(Increased by 72.73%)
19 

(increased by 72.73%)

Table 5: End tidal CO2 (Mean of 400 patients)
Before pneumo-

peritoneum
After pneumo-

peritoneum
Percent 
change

22 mm Hg 27.6 mm Hg 25.45%

 Table 3 shows that haemodynamic changes 
with respect to mean arterial pressure and heart rate 
are increased by 31.70% and 28.76 % respectively 
at the end of surgery but there is minimal change at 
5 and 10 minutes. These changes were statistically 
significant p<0.05. 
 Ventilatory changes in Table 4 shows 
that Peak and plateau both airway pressure were 
decreased during head up position and both were 
increased at 5 and 10 minutes (41.18% and 72.73% 
at 10 minutes) of pneumoperitoneum which was 
statistically significant, p<0.05. End tidal CO2 was 
increased by 25.45% after pneumoperitoneum was 
created (Table 5). This finding was statistically 
significant, p<0.05.

DISCUSSION:
 This study shows that a CO2 
pneumoperitoneum and head-up tilt is well tolerated 

44



J. Lumbini. Med. Coll. Vol 1, No 1, Jan-June 2013

Sharma NR. et al. Hemodynamic changes during laproscopic cholecystectomy

jlmc.edu.np

by all patients with regard to haemodynamic patterns 
and gas exchange. Similar studies have revealed that 
creation of CO2 pneumoperitonium at 12–14 mmHg 
has not induced major haemodynamic changes.10 Our 
study also reveals that some haemodynamic changes 
were observed during CO2 pneumoperitoneum and 
head-up tilt .There was significant change (p<0.05) 
in mean arterial pressure and heart rate after 
pneumoperitoneum at the end of surgery. More is 
the weight of the patient, greater is the change in the 
air way pressure which was statistically significant 
(p<0.05) in our study. But lesser the weight minimum 
change in airway pressure was observed. In case of 
elderly patients they do have some physiological 
cardiac and circulatory alterations that resulted in 
a decrease in myocardial performance which alters 
the haemodynamic changes.11 Cardiac preload 
could have compromised myocardial function.12 LC 
procedures induce haemodynamic disturbances in 
ASA III-IV patients.10,13 These occur even in healthy 
ASA I-II patients mainly because of decreased 

preload and increased afterload.5,13-14 In our study 
there was increased level of end tidal CO2. It was 
increased by 25.45 % (p<0.05). That is why the 
Monitoring of Et.CO2 has been shown to be useful. 
Like in our study majority of other studies concerning 
gas exchanges during LC have reported an increase 
in EtCO2. It is generally considered to be moderate 
in ASA I or II patients.15 However, high levels of 
End tidal carbon dioxide have been described during 
LC, especially in patients with previous COPD or in 
ASA III-IV patients.16 This is the reason that the End 
tidal CO2 monitoring is essential during LC.

CONCLUSION:
 Creation of pneumoperitoneum during 
LC can alter the haemodynamic and ventilatory 
parameters. The changes in End tidal CO2, MAP, 
heart rate and ventilatory parameters are the main 
indicators used for hemodynamic stability of patients 
undergoing LC.

REFERENCES:

1. Joris J, Cigarini I, Legrand M, Jacquet N, De Groote D, 
Franchimont P et.al. Metabolic and respiratory changes 
after cholecystectomy performed via laparotomy or 
laparoscopy. Br J Anaesth. 1992;69(4):341-5.

2. Schauer PR, Luna J, Ghiatas AA, Glen ME, Warren 
JM, Sirinek KR. Pulmonary function after laparoscopic 
cholecystectomy. Surg. 1993;114:389-99.

3. Critchley LA, Critchley JA, Gin T. Haemodynamic changes 
in patients undergoing laparoscopic cholecystectomy: 
measurements by transthoracic electrical bio-impedance. 
Br J Anaesth. 1993;70:681-3.

4. Cunningham AJ, Turner J, Rosenbaum S, Rafferty 
T. Transoesophageal echocardiographic assessment 
of haemodynamic function during laparoscopic 
cholecystectomy. Br J Anaesth. 1993;70(6):621-5.

5. Joris J, Honore P, Lamy M. Changes in oxygen transport 
and ventilation during laparoscopic cholecystectomy. 
Anesthesiol. 1992;77(3A):A149.

6. Joris JL, Noirot DP, Legrand MJ, Jacquet NJ, Lamy 
ML. Hemodynamic changes during laparoscopic 
cholecystectomy. Anesth Analg. 1993;76(5):1067-71.

7. Mc Laughlin JG, Bonnell BW, Scheeres DE, Dean RJ. 
The adverse hemodynamic effects related to laparoscopic 
cholecystectomy. Anesthesiol. 1992;77:A70.

8. Joris J, Ledoux D, Honore P, Lamy M. Ventilatory effects 
of CO2 insufflation during laparoscopic cholecystectomy. 
Anesthesiol. 1991;75:A121.

9. Fox LG, Hein HAT, Gawey BJ, Hellman CL, Ramsay 
MAE. Physiologic alterations during laparoscopic 
cholecystectomy in ASA III and IV patients. Anesthesiol. 
1993;79:A55.

10. Wahba RWM, Mamazza J. Ventilatory requirements 
during laparoscopic cholecystectomy. Can J Anaesth. 
1993;40:206-10.

11. Feig BW, Berger DH, Dougherty TB, Dupuis JF, Hsi B, 
Hickey RC et al. Hemodynamic effects of CO2 abdominal 
insufflation (CAI) during laparoscopy in high-risk patients. 
Anesth Analg 1994;78:S109.

12. Gunnarsson L, Tokics L, Gustavsson H, Hedenstierna G. 
Influence of age on atelectasis formation and gas exchange 
impairment during general anaesthesia. Br J Anaesth. 
1991;66:423-32.

13. Wittgen CM, Andrus CH, Fitzgerald SD, Baudendistel LJ, 
Dahms TE, Kaminski DL. Analysis of the hemodynamic 
and ventilatory effects of laparoscopic cholecystectomy. 
Arch Surg. 1991;126:997-1001.

14. Fitzgerald SD, Andrus CH, Baudendistel LJ, Dahms 
TE, Kaminski DL. Hypercarbia during carbon dioxide 
pneumoperitoneum. Am J Surg. 1992;163:186-90.

15. Feig BW, Berger DH, Dougherty TB, Dupuis JF, Hsi B, 
Hickey RC et al. Pulmonary effects of CO2 abdominal 
insufflation (CAI) during laparoscopy in high-risk patients. 
Anesth Analg. 1994;78:S108.

16. Wittgen CM, Naunheim KS, Andrus CH, Kaminski 
DL. Preoperative pulmonary function evaluation for 
laparoscopic cholecystectomy. Arch Surg. 1993;128:880-6.

45