Abstract
Background:
Obesity is accompanied by a number of comorbidities that gravely lower patients’ quality of life; one such comorbidity is serum lipid abnormalities. Studies have shown that weight loss decreases serum total cholesterol and low-density lipoprotein (LDL) cholesterol and increases high-density lipoprotein (HDL) cholesterol. Bariatric surgery is one of the most recent ways to treat obesity and manage weight loss in overweight patients whose options for weight loss are limited.Objectives:
The aim of this study was to assess the effect of bariatric surgery on lipid profile of surgical candidates during the three months of post-operative care.Methods:
This prospective study was performed among 36 obese candidates of bariatric surgery at Mostafa Khomeini Hospital in Tehran, Iran from April to September of 2012. Body mass index (BMI), serum cholesterol, triglyceride, HDL and LDL levels were measured before and three months following the surgical intervention.Results:
The mean age of the participants was 35.39 ± 10.32 years. Mean body mass index (BMI) of the patients before surgery was 46.74 ± 6.71 kg/m2, which was lowered to 38.24 ± 5.31 kg/m2 after the intervention. Assessments showed a statistically significant increase in the serum level of HDL and a statistically significant decrease in the serum level of triglycerides, but no significant change in the serum level of cholesterol or LDL was noted. Moreover, results showed a positive correlation between serum LDL variations and changes in BMI.Conclusions:
Our findings showed that bariatric surgery improves weight loss and can help with managing or treating co-morbid illnesses through reducing triglyceride level and increasing HDL level, both of which improve patients’ long-term cardiac, hepatic and endocrine health status.Keywords
Sleeve Gastrectomy Gastric Bypass Bariatric Surgery Lipid Profile Triglyceride Cholesterol
1. Background
The terms “Overweight” and “Obesity” refer to abnormal, excessive fat accumulation in an individual’s body, which lead to overall health impairment (1, 2). Body mass index (BMI) is a parameter commonly calculated in order to identify an individual’s weight status (3-5). According to the World Health Organization (WHO), a BMI greater than or equal to 25 kg/m2 indicates a status of overweight and a BMI greater than or equal to 30 kg/m2 indicates obesity (3). Genetics, heredity, environmental and psychological factors, lack of adequate physical activity and hormonal imbalances all play a part in the pathophysiology of overweight and obesity, but the most influential factor is the inequality between total caloric intake and expenditure (1, 5).
The prevalence of obesity is increasing; WHO reported that in 2014, 1.9 billion people over the age of 18 were suffering from overweight, 600 million of whom were obese and morbidly obese individuals. Also, 41 million children under the age of 5 are suffering from obesity (3). It is worth mentioning that obesity is the third preventable cause of death, following tobacco usage (6).
Obesity is associated with raised cardiovascular risk factors such as hypertension, type 2 diabetes mellitus and dyslipidemia (6). Abnormalities of lipid profile associated with obesity include increased serum level of total cholesterol, low-density lipoprotein (LDL) cholesterol, very low density lipoprotein (VLDL) cholesterol, triglycerides, apolipoprotein B and a reduction in serum high-density lipoprotein (HDL) cholesterol (7).
Studies showed that a weight loss equal to 1 kg results in a drop in serum total cholesterol by 0.05 mmol/L and LDL cholesterol by 0.02 mmol/L and an increase in HDL cholesterol by 0.009 mmol/L (8). The most widely accepted treatment plans for treating obesity and overweight include a single approach or a combination of the following: Diet therapy, physical activity (aerobic primarily), behavioral therapy (e.g., treating underlying psychological enablers of eating disorders), pharmacotherapy and at last resort, surgical intervention (9). Indications for bariatric surgery include morbid obesity (a BMI higher than 40 kg/m2) and severe obesity (BMI = 35 - 40 kg/m2) in a patient with co-morbid conditions such as diabetes or hypertension (10).
Regarding morbidly obese patients as the target group, bariatric surgery is a highly successful method in reaching long-term health improvements and decreased mortality rates (11). Furthermore, bariatric surgery can lead to improved glucose metabolism and lowered cardiovascular risk (12-16). Overall, bariatric surgery can improve serum lipid concentrations (17-19). However, when we become specific regarding which components of the lipid panel are affected, one study reported improvement in all components of the lipid profile of patients before and after surgery, another reported a reduction only in triglyceride and LDL levels, but no statistically significant changes were observed in HDL and total cholesterol components of the lipid profile (20-23).
2. Objectives
So far, several studies have been conducted in order to assess the effects of bariatric surgery on lipid profile, which have yielded diverse results, especially on the improvement of lipid profile components. Thus, the aim of the present study was to assess the effects of two different bariatric surgical interventions, namely laparoscopic sleeve gastrectomy and Roux-en-Y gastric bypass, on lipid profile before and three months after the operation.
3. Methods
This prospective study was performed at Mostafa Khomeini General Hospital affiliated to Shahed Medical University in Tehran, Iran from April to September of 2012.
3.1. Sample Size and Population
The study was carried out among patients referred to the surgical clinic of Mostafa Khomeini General Hospital seeking treatment for their overweight or obesity (either with or without comorbidities) from April to September 2012. Thirty-six patients previously diagnosed with either morbid or severe obesity were chosen based on simple random sampling technique out of all surgical candidates.
3.2. Participants and Inclusion Criteria
The inclusion criteria comprised having undergone pre-surgical workup, being aged 20 - 62 years, not being pregnant (for female participants), not having been previously diagnosed with hypercholesterolemia and/or hypertriglyceridemia, and not being under treatment for high cholesterol or triglyceride levels prior to being chosen as a surgical candidates. Each patient underwent evaluations including routine blood tests, upper-endoscopy (evaluating the presence of gastroesophageal reflux disease, hiatal hernia, gastritis, and H. pylori infection status), ultrasonographic assessment of the whole abdomen with particular focus on the liver and the gallbladder (mainly for the presence or absence of cholelithiasis).
3.3. Intervention
All the patients underwent either sleeve gastrectomy (SG) or Roux-en-Y gastric bypass surgery. The method of surgery was chosen by the team of bariatric surgeons (independent from our study) for each patient based on thorough pre-surgical consultation, interviews and clinical assessments.
3.4. Exclusion Criteria
The exclusion criteria included age below 20 or above 62 years, unwillingness to participate, previous history of another form of bariatric surgery, lack of compliance with follow up visits three months after undergoing the surgery, refusal to adhere to post-surgical instructions, endocrine comorbidities other than hypertriglyceridemia and/or hypercholesterolemia (e.g., hyper and hypothyroidism, Cushing’s syndrome and hyperprolactinemia) and underlying hepatic diseases marked by elevated liver transaminase in blood test or hepatomegaly defined in abdominal ultrasonography report.
3.5. Ethics Committee
Institutional approval of ethics committee was obtained and all the patients received detailed information regarding the research and counseling prior to the surgery. Signed consent forms were also obtained from all the participants before their enrolment in the study.
3.6. Data Collection
The interview was performed and the questionnaire was compiled by a medical student after having received appropriate training. Demographic information such as age and sex were recorded. Anthropometric specifications including weight (within 100-gram accuracy) and height (within 0.5-centimeter accuracy) were evaluated by minimal clothing, without shoes, using a digital scale and a standard meter, followed by the calculation of BMI as the gold standard for the diagnosis of obesity.
Serum levels of total cholesterol, triglyceride, LDL and HDL were measured directly by enzymatic methods and all the tests were performed in one laboratory (Shafagh Pathobiology Laboratory, ELISA).
Three months after surgery, interviews were conducted again and each patient’s BMI three months after the surgery was calculated. Total cholesterol, triglyceride, HDL and LDL levels of serum were assessed again.
3.7. Statistical Analysis
Data was analyzed using SPSS software (V. 22, SPSS Inc., Chicago, USA). To express the quantitative measurements, mean and standard deviation (SD) were used. For nominal variables, relative frequencies were reported. Also, univariate statistical analysis and Spearman test were applied. Two-tailed P value of less than 0.05 was considered significant.
4. Results
In this study, 36 patients were enrolled, all of whom completed the study. The mean age of the patients was 35.39 ± 10.32 years (age range: 20 - 62 years old); 91.7% of the subjects were female and 8.3% were male. The mean BMI prior to the surgery was 46.74 ± 6.71 kg/m2 (range: 38.54 - 65.79 kg/m2) and the mean BMI post-operatively was 38.24 ± 5.31 kg/m2 (range: 31.99 - 57.02 kg/m2). Further characteristics of the participants are shown in Table 1.
Clinical and Anthropometric Characteristics of the Participants Before (Pre-op) and After (Post-op) Surgical Intervention
| Mean ± SD | Min | Max | |
|---|---|---|---|
| Age | |||
| Pre/Post-op | 35.39 ± 10.32 | 20.00 | 62.00 |
| Weight, kg | |||
| Pre-op | 121.19 ±10.36 | 94.00 | 173.00 |
| Post-op | 99.19 ± 15.48 | 77.00 | 132.00 |
| Weight difference, kg | |||
| Post-op | -22.00 ± 9.91 | -53.00 | -6.00 |
| BMI, kg/m2 | |||
| Pre-op | 46.74 ± 6.71 | 38.54 | 65.79 |
| Post-op | 38.24 ± 5.31 | 31.99 | 57.02 |
| BMI changes, kg/m2 | |||
| Post-op | -8.50 ± 3.71 | -21.23 | -2.31 |
| Serum total cholesterol, mg/dL | |||
| Pre-op | 195.14 ± 32.83 | 128.00 | 283.00 |
| Post-op | 190.17 ± 38.37 | 119.00 | 311.00 |
| Serum total cholesterol changes, mg/dL | |||
| Post-op | -4.97 ± 33.62 | -75.00 | 92.00 |
| Serum triglyceride, mg/dL | |||
| Pre-op | 157.53 ± 66.34 | 58.00 | 296.00 |
| Post-op | 107.81 ± 48.11 | 45.00 | 267.00 |
| Serum triglyceride changes, mg/dL | |||
| Post-op | -49.72 ± 53.53 | -198.00 | 28.00 |
| Serum LDL, mg/dL | |||
| Pre-op | 117.25 ± 22.21 | 81.00 | 181.00 |
| Post-op | 114.86 ± 31.59 | 55.00 | 218.00 |
| Serum LDL changes, mg/dL | |||
| Post-op | -2.39 ± 30.59 | -67.00 | 90.00 |
| Serum HDL, mg/dL | |||
| Pre-op | 47.69 ± 12.03 | 24.00 | 75.00 |
| Post-op | 52.72 ± 11.71 | 31.00 | 83.00 |
| Serum HDL changes, mg/dL | |||
| Post-op | 5.03 ± 12.65 | -23.00 | 26.00 |
Univariate comparisons showed significant differences in serum levels of HDL and triglyceride before and after surgery (P < 0.023 and P < 0.001, respectively), but no significant differences in the serum levels of cholesterol and LDL were noted (P < 0.381 and P < 0.642, respectively).
Investigations showed no correlation between BMI changes and changes in serum levels of total cholesterol, triglyceride and HDL (P = 0.149, P = 0.103 and P = 0.107, respectively), but change in serum LDL was positively correlated with change in BMI (P = 0.037, r = 0.35). Table 2 summarizes the results of other univariate comparisons of the study variables.
Univariate Comparison of Study Variables
| Age | BMI Changes | |
|---|---|---|
| Changes of serum level of cholesterol | r = 0.058 | r = 0.246 |
| Changes of serum level of triglyceride | r =0.202 | r = 0.276 |
| Changes of serum level of HDL | r = 0.297 | r = 0.273 |
| Change of serum LDL | r = -0.034 | r = 0.350a |
| BMI changes, kg/m2 | r = 0.108 | - |
5. Discussion
We evaluated the effect of two different bariatric surgical methods on lipid profile changes. Our findings showed significant differences in the serum levels of HDL and triglyceride before and after surgery, but no significant difference was found in the serum levels of total cholesterol and LDL before and after the surgery. Furthermore, investigations showed a positive correlation between changes in serum LDL and BMI.
Toolabi et al. showed significant improvement in all components of lipid profile one year after surgery (20). Golpaie et al. reported significant reduction in LDL and triglycerides levels six weeks post-surgery (21). Corradini et al. also reported significant changes and improvements in all the components of lipid profile in a three-year period (24). The results of all the mentioned studies were consistent with each other.
In another study, hyperlipidemia improved in 80% - 100% (n = 400) of the obese patients who underwent gastric bypass surgery (25). Another study reported that 72.3% of patients previously diagnosed with hypertriglyceridemia had been normalized within 18 months after undergoing gastric banding (26).
The most important differences among the results of the aforementioned studies compared to each other and to the present study are pertained to the type of bariatric surgery, duration of the study and type of improved components of lipid profile. The discrepancy in results could also be attributed to follow up duration. In long-term follow-ups (2 years and more), assessments showed improvement in all components of lipid profile (24); thus, examining the effect of bariatric surgery on all components of lipid profile requires a longer course of follow-up visits post-operatively.
Possible mechanisms that may influence components of lipid profile in bariatric surgery are caloric restriction, weight loss (8), endocrine changes (27) and malabsorption (23). Each bariatric surgery leads to some extent of weight loss (28), and it seems that patients undergoing gastric bypass surgery experience more weight reduction (17). The correlation between weight loss and lipid level changes is a matter of debate, with some studies showing a positive correlation (29, 30) and some demonstrating no correlation (31-33). Our study demonstrated a positive correlation between change in serum LDL and change in BMI. Another possible mechanism is endocrine changes. It has been documented (34) that there is an increase in serum level of adiponectin in patients having undergone gastric bypass surgery. In this study, however, adiponectin level was not evaluated.
This study had some limitations that should be recounted here. First, the two types of surgery (sleeve gastrectomy and gastric bypass) were not randomly assigned. Second, low percentage of male patients may have influenced our results. Third, some confounding factors affecting serum lipid profile such as physical activity, dietary habits, alcohol consumption, or smoking status were not considered in this study due to difficulties regarding obtaining credible data (e.g., patients’ lack of cooperation regarding self-reports of physical activity or tobacco and alcohol consumption). Nevertheless, it should be noted that this surgery is especially noticeable when other treatment modalities with different mechanisms have already failed to yield proper weight management, especially in patients diagnosed with grade 2 obesity (BMI score of +35 kg/m2) whose weight problem withholds them from being properly able to exercise in order to lose weight (20-22). Finally, three-month follow-up period was rather short.
In conclusion, our findings showed a significant improvement in the serum levels of HDL and triglyceride before and after the surgical intervention. Furthermore, investigations demonstrated a positive correlation between changes in serum LDL and changes in BMI. In addition to the weight loss achieved by bariatric surgery, the associated risk factors such as dyslipidaemia are also expected to improve. It appears that triglyceride and HDL normalize faster.
Acknowledgements
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