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Wpływ standardowo- i niskociśnieniowej odmy otrzewnowej na stan nawodnienia otyłych kobiet poddanych laparoskopowej cholecystektomii

Łukasz Pietrzyk
,
Marta Denisow-Pietrzyk
,
Anna Torres
,
Kamil Torres

Medical Studies/Studia Medyczne 2018; 34 (1): 1-8
Data publikacji online: 2018/03/30
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Introduction

Obesity, according to the World Health Organization, has become one of the leading epidemic diseases in the world [1, 2]. Obesity influences the course of the post-operative period, which was reported to be more complicated and more commonly included occurrences of respiratory complications, wound infection with dehiscence, venous thrombus, and pulmonary embolism [3, 4].
|Laparoscopic cholecystectomy is one of the most commonly used surgical procedures performed in Surgical Departments worldwide [5]. The pneumoperitoneum may cause deterioration of cardiovascular and respiratory systems and perfusion decrease of abdominal viscera, and is considered as a fundamental risk factor for post-operative nausea and vomiting, which occurs in approximately 25–30% of patients, especially in obese females undergoing laparoscopic procedures [6–9].
|Hydration status is one of the most important factors that influence the course of the early post-operative period. Disturbances of the hydration status can increase the frequency of postoperative pain, nausea and vomiting (PONV), complicate the wound healing process in the mechanism of decreased cardiac output, tissue perfusion and thus, increase the period of hospitalization [10, 11]. These complications may be present especially in overweight and obese patients, in whom an excessive amount of adipose tissue results in changes in the fat-free mass, and the total and extracellular amount of body water [12, 13].

Aim of the research

The aim of the study was to assess the impact of obesity, the standard and low-pressure carbon dioxide pneumoperitoneum on hydration status of obese female patients undergoing laparoscopic cholecystectomy in the early postoperative period.

Material and methods

The study included 52 female individuals with asymptomatic cholelithiasis, confirmed by an ultrasound examination, treated in the Department of General, Oncological and Minimally Invasive Surgery of the 1st Military Clinical Hospital with the Outpatient Clinic in Lublin, Poland. All patients were informed about the aims of the study and written consent was obtained from each patient. The study was approved by the Ethical Committee at the Medical University of Lublin (decision No: KE-0254/247/2012).
|Patients with acute inflammation of the gallbladder, diabetes, thyroid and autoimmune disease, allergies, past surgical procedures in the abdominopelvic cavity, and with cases of ectopic pregnancies were excluded from the study.
|All patients underwent laparoscopic cholecystectomy using a standard four-trocar technique. Carbon dioxide pneumoperitoneum was obtained with a veress needle. In the standard pressure group, intra-abdominal pressure of 12–14 mmHg was maintained throughout the procedure, whereas in patients from the second group pressure of 6–8 mmHg was applied to perform surgery. The general anesthesia method was the same for both groups. Anatomic recognition of Calot’s triangle was performed in each case. The cystic duct and cystic artery were clipped and cut. The gallbladder was removed in a medical protector through an incision below the umbilicus. A histopathological examination of collected tissues did not reveal any malignancies.
|Patients were assigned to three groups according to the body mass index (BMI) and value of intra-abdominal pressure. Patients undergoing laparoscopic surgery using the standard value of intra-abdominal pressure (12–14 mmHg) with BMI < 25 kg/m2 were enrolled in group N, while patients with BMI ≥ 30 kg/m2 were classified to group OS. Patients with BMI ≥ 30 kg/m2 and undergoing laparoscopic surgery, with low-pressure (6–8 mmHg) pneumoperitoneum were enrolled to group OL.
|Evaluation of the hydration status was performed at three time points: point 0 – before the surgical procedure, point 24 – 24 hours after the beginning of the procedure, and point 48 – 48 hours after the beginning of the procedure. The following parameters indicating the state of hydration of patients were determined in each case: total body water (TBW), extracellular water (ECW), intracellular water (ICW), ECW/ICW ratio, and state of overhydration (OH).
|Evaluation of the hydration status was performed at three time points: time point 0 – before the surgical procedure, time point 24 – 24 hours after the beginning of the surgery, and time point 48 – 48 hours after the beginning of the surgery. Changes of measured parameters were evaluated in three time periods. Period 0–24: value at 24 hours after the beginning of the surgery to the value before the surgery, period 24–48: value at 48 hours after the beginning of the surgery to the value at 24 hours after the beginning of the surgery, and period 0–48: value at 48 hours after the beginning of the surgery to the value before the surgery. TBW, ECW, ICW, and fluid volume excess were measured by whole-body BIA using a body composition monitor (BCM, Fresenius Medical Care, Bad Homburg, Germany). Prior to examinations, patients’ blood pressure and heart rate were measured. Electrode pairs were placed on the wrist, proximally to the metacarpophalangeal joints, and on the ankle, proximally to the transverse metatarsal arch on the dorsal side of the foot, for current injection and voltage measurement. Bioimpedance was measured at 50 frequencies, ranging from 5 kHz to 1 MHz in supine body position. The data was achieved after approximately 1 minute and then subjected to statistical analysis.
|The Kolmogorov-Smirnov test was performed to check the normal distribution of data. Normally distributed parametric data were presented as means and standard deviations (SD), while non-parametric data were presented as median and min-max values. Differences between groups were analyzed using student’s unpaired t-test for variables with normal distribution and Mann-Whitney U test for non-parametric variables. Differences from baseline within each group were evaluated with the Wilcoxon match-pairs signed ranks test. Correlation between data was performed using the Spearman’s rank correlation tests. Differences of p < 0.05 were considered to be significant. Statistical analysis was performed using 16.0 SPSS software.

Results

Patients’ characteristics
|
| Patients’ characteristics are presented in Table 1.
|Significantly higher BMI and abdominal circumferences at the level of umbilicus and ASIS were observed in group OS in comparison to group N. There were no differences between groups OL and OS with respect to BMI.
|Before the surgery, each patient was assessed according to the ASA scale with no significant differences between groups. Additionally, there were no differences in hematological (hemoglobin, HCT, PLT) and biochemical parameters (AST, ALT, bilirubin, creatinine) examined before and after the surgery. The median body temperature and white blood count (WBC) was similar (normal ranges) in both groups during the post-operative time.
|There was no significant difference in duration of surgery when the three groups were compared. The median duration of surgery was 47.50 minutes in group N, and 50 minutes in group OS and OL.

Total body water

TBW was significantly higher in group OS in comparison to group N before and 24 hours after the operation (p = 0.002 and p = 0.007, respectively). There were no significant differences in TBW amount between groups OL and OS in the studied time points. This is presented in Table 2.
|TBW decreased significantly (p < 0.05) in the 24th post-operative hour compared to the TBW in the 48th hour after surgery (period 24–48) in group OL. In the group N and OS, there was no significant change in the TBW in the studied time periods.
|TBW elevated in the studied time points was correlated in each group with the patients’ age and BMI values. Significant negative (r = –0.713; p = 0.009) correlation between the TBW in the 24th post-operative hour and the age of patients was observed. A significant positive correlation between TBW and BMI values was observed in group OS in the 24th hour after surgery and in group OL in the 48th hour after surgery (for group OS: r = 0.535, p = 0.018; for group OL: r = 0.477, p = 0.033).

Extracellular water

ECW was significantly higher in group OS in comparison to group N in the studied time points (p < 0.001 – time point 0; p = 0.001 – time point 24; p = 0.002 – time point 48). No significant differences in the amount of ECW were observed between groups OS and OL. Results are presented in Table 3.
|ECW increased significantly (p < 0.05) in the 24th post-operative hour in comparison to the ECW before surgery (period 0–24) in groups N and OL. Additionally, in time period 24–48, there was a significant (p < 0.05) ECW decrease in group OS and OL.
|Correlation between ECW and the patients’ age and BMI values showed significant negative correlations between ECW evaluated in the studied time points and patient’s age in group N (time point 0: r = –0.596, p = 0.041; time point 24: r = –0.577, p = 0.049; time point 48 r = –0.658, p = 0.02). ECW positively correlated with the patients’ BMI in the three studied time points (time point 0: r = 0.809, p < 0.001; time point 24: r = 0.720, p = 0.001; time point 48: r = 0.786, p < 0.001) in group OS. In group OL, positive correlation (r = 0.473, p = 0.035) was observed between ECW and patients’ BMI in the time point 48.

Intracellular water

No significant differences in ICW were observed between groups OS and N as well as between groups OL and OS in the studied time points. Results are presented in Table 4.
|No changes in the ICW amount in the studied time periods were observed in the studied groups.
|A significant negative (r = –0.620, p = 0.031) correlation between ICW, evaluated in the time point 24, and patients’ BMI was observed in group N. There were no significant correlations between ICW and patients’ age and BMI values in the studied time point in group OS and OL.

Extracellular water/intracellular water ratio

The ratio of ECW/ICW did not differ significantly between group OS and N, and OL and OS in the studied time points (Table 5). However, tendency to higher ECW/ICW was observed in group OS in comparison to group N in the three studied time periods.
|There was a significant (p = 0.034) increase of ECW/ICW ratio in the time period 0–24 in group N. No significant changes were observed in group OS and OL in the studied time periods.
|ECW/ICW ratio correlates positively (r = 0.639, p = 0.025) with patient’s BMI values in the time point 24 in group N. No significant correlations were observed in group OS and OL.

Overhydration status

Overhydration status (OH) was significantly higher in the 24th and 48th hour after the surgery (p = 0.009 – time point 24; p = 0.012 – time point 48) in group N in comparison to group OS. There were no statistically significant differences in the OH between the patients of group OL and OS at the studied time points. This is presented in Table 6.
|A significant increase of OH in the 24th post-operative hour compared to the state before operation (period 0–24) was observed in group N, while a significant decrease in the same time period was observed in group OL. In group OS, there was no change of OH in the studied time periods.
|Correlation between the OH and the patients’ age and BMI values did not show significant correlations in the studied groups in the investigated time points.
|The total fluid administration within the first 24 hours after the surgery in group N was 2,500 ml (range, 1,500–3,500 ml), in group OS 2,625 ml (range, 2500–3500 ml), and in group OL was 2,500 ml (range, 1,000–3500 ml). During the next 24 hours, none of the patients required fluid administration.

Discussion

The determination of the body water amount and its distribution between the extracellular and intracellular compartments allows for the assessment of the body water balance as well as its disturbances [14]. The TBW and ICW is lower in women than in men and decreases along with age [15, 16]. Changes in the hydration status were observed in obese patients in whom the development of adipose tissue deposit was accompanied by the increase of the ECW, compared to the ICW [7]. From a clinical point of view, the hydration status is a major factor for the applicability of appropriate treatment and the inclusion of drugs regulating the state of overhydration or dehydration [18]. Knowledge of the optimum state of hydration is particularly important in patients with diagnosed chronic kidney disease to stratify prognosis, evaluate an effective treatment, and to appropriately qualify patients for renal replacement therapy [19]. Hydration status affects the course of the early post-operative period and its balance helps to reduce incidents of PONV, especially in patients operated with the use of a laparoscopic technique, and improves wound healing as well as shortenes the period of hospitalization [10, 20, 21].
|In the presented study, we evaluated the TBW, ECW, and ICW, ECW/ICW ratio as well as the state of OH in obese patients (group OS) compared to patients with normal weight (group N), who underwent laparoscopic cholecystectomy with standard intra-abdominal pressure, and evaluated differences between obese female patients undergoing laparoscopic surgery with creation of standard (group OS) and low intra-abdominal pressure (OL group) in the three time points: before surgery and in the 24th and 48th hour after surgery.
|A higher TBW was observed in obese patients compared to patients with normal weight before surgery, in the 24th and 48th hour after surgery. TBW did not differ significantly between groups OS and OL in any of the studied time points.
|Similar results of a higher TBW in obese women compared to women with normal body weight were obtained by Sartolio et al. [22]. The results, indicating a higher TBW in obese patients were received by Resende et al., studying a group of people aged 10–19 [23]. Higher TBW in obese women compared to women of normal weight was also described in the study of Silva et al., who examined a population of 371 women [24].
|The TBW varies with age; its decrease begins in middle-aged men and especially after the age of 60 in women [25, 26]. The mean TBW decrease between the age of 20 and 80 is about 4 and 6 liters, respectively, in men and women [27, 28]. In our study in the time point 24, we observed TBW decrease with the patients’ age in group N, what can confirm described above correlations. This change may result from the reduction of intracellular water and body cell mass during the aging process [25, 26].
|In our study, ECW was significantly higher in group OS as compared to group N before surgery, in the 24th, and 48th hour after surgery. There was no difference in the ECW between obese female patients operated on using two different values of intra-abdominal pressure in the studied time points. A higher ECW in obese women compared to women of normal weight has been described in a study by Waki et al. [29]. Silva et al. described a further increase of ECW accompanying weight gain [24]. This data correlates with the results obtained in our study, in which a positive correlation was observed between ECW and the patient’s BMI values in the three studied time points in group OS. These findings may indicate an increase of the extracellular compartment in obese patients, thus increasing the ECW, which in turn increases the TBW in obesity.
|In our study, ICW did not differ significantly between groups OS and N, and between groups OS and OL in the studied time points. However, there are reports suggesting higher ICW in obese women compared to women with normal body weight [29].
|In our study, neither TBW nor ECW or ICW did not differ significantly between obese female patients who underwent laparoscopic procedures with two different pneumoperitoneum pressures (group OS vs. OL). These observations may be explained by the fact that the standard value of the insufflated gas is not enough to cause the changes in the fluids compartments. It can be suggested that differences between pressure values used in our study were too low and thus, no changes were reported. Additionally, it may result from the short duration of pneumoperitoneum during laparoscopic cholecystectomies in our study, not enough to influence the patients’ hydration status.
|Obesity is characterized by an increase in fat mass and increased fat-free mass, and thus enlarged extracellular water compartment compared with the intracellular water compartment. This can be explained by a high ECW/ICW ratio of the adipose tissue [17, 30].
|In our study, there was no difference in the ECW/ICW ratio between obese patients from group OS and normal weight patients in the studied time points. Additionally, there was no difference in the ECW/ICW ratio between both obese patients’ groups OS and OL. Different results compared to those obtained in our study were described by Waki et al., who reported a higher ECW/ICW ratio in obese women compared to women of normal weight [29]. A higher ICW/ECW ratio has also been described by Mazariegos et al. in obese patients classified to surgical treatment of obesity, as compared to patients with normal body weight [30, 31]. It may suggest that the significant differences, which were not observed in our study can be visible when the difference of BMI values is higher than observed among patients enrolled to our research.
|Surgical interventions, even with usage of minimally invasive techniques, cause the stress-induced release of aldosterone, antidiuretic hormone as well as activation of the renin-angiotensin system, which leads to sodium and water retention. Furthermore, the release of inflammatory mediators in response to surgical trauma may result in SIRS, increased capillary permeability, and water shift from intravascular compartment into the interstitial space [32, 33]. Peri¬pheral and visceral edema, usually seen after major abdominal surgeries and liberal fluid administration, also in trauma patients, is a manifestation of increased capillary permeability and overhydration [34–36].
|In our study, higher dehydration in group OS in the 24th and 48th hour after surgery, compared to group N was reported. In both OL and OS there was no difference in the state of overhydration. Our observations are similar to the observations by Leonea et al. who reported that obese patients undergoing bariatric surgery are relatively more dehydrated compared to those who have never been obese [37]. It can be explained by the fact that the excess amount of adipose tissue has no capacity to store water. Therefore, larger deficiency of water occurs in obese individuals [29].

Conclusions

To conclude, it can be stated that obesity alters the hydration status. Obese female patients are characterized by the higher TBW and ECW in comparison to normal weighted females who undergo short-term laparoscopic surgery. Values of carbon-dioxide pneumoperitoneum pressure used during laparoscopic cholecystectomy did not have an influence on the hydration status of the obese female patients. Thus, low-pressure pneumoperitoneum does not seem to offer advantages over standard-pressure pneumoperitoneum in measured parameters of hydration status. However, we plan to extend our study on a group of patients, where the time of carbon dioxide pneumoperitoneum exposure will be longer. We expect that our results would put a new insight into the influence of the pneumoperitoneum on the hydration status and therefore, on the proper fluid management and the course of the early post-operative period.

Conflict of interest

The authors declare no conflict of interest.

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Address for correspondence:

Łukasz Pietrzyk, MD, PhD
Department of Didactics and Medical Simulation Chair of Human Anatomy, Medical University of Lublin
4 Jaczewskiego St.
20-094 Lublin, Poland
Phone: +48 505 918 705
Fax: +48 81 448 60 50
Email: lukasz.pietrzyk@wp.pl
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