A clinical study of preoperative carbohydrate administration to improve insulin resistance in patients with multiple injuries
Introduction
Patients clinically present with insulin resistance (IR) for many reasons. IR is characterized by the destruction of glucose transporter 2 (GLUT2) and glucose transporter 4 (GLUT4) in muscle and adipose tissue under stressed states, such as trauma, infection, and surgery (1). Decreased sensitivity of peripheral tissue to insulin reduces its effect on the body, compared with the effect produced by normal physiological levels (2), and in turn reduces the body’s glucose use. To maintain relative blood glucose stability, excessive insulin is secreted in compensation, leading to hyperinsulinemia. In recent years, it has been found that IR is related to the postoperative development of type 2 diabetes mellitus. This may be related to pre-surgery fasting and the stressed state of tissues post-surgery. IR is also related to trauma, inflammation, hormones, and intestinal flora, among other factors.
Surgery is often accompanied by anesthesia. A series of functional changes occur during anesthesia, including the relaxation of gastrointestinal sphincters, the weakening of gastrointestinal peristalsis, airway obstruction, and the weakening of the pharyngeal reflex. These changes frequently produce vomiting and aspiration during surgery.
Aspiration is a serious surgical complication that was initially thought to be related to anesthesia and the failure to correctly fast pre-surgery. It is characterized by immune inflammation, direct lung injury, and fibrous hyperplasia. Symptoms of aspiration include acute airway obstruction, aspiration atelectasis, Mendelson’s syndrome, and aspiration pneumonia. As such, a sizeable amount of research has explored methods to reduce the incidence of aspiration.
In 1946, Mendelson proposed routine fasting for 8–12 hours before surgery. Up to now, however, most elective surgery in China has involved fasting for only 4 hours prior to surgery. Recent studies have focused on reducing aspiration risk in the perioperative period, particularly after general anesthesia. These studies have investigated surgical positioning, different medications, the use of ultrasound technology, and the use of gastric tubing.
In a further study, it was considered as high-risk factors that aspiration pneumonia was associated with, defining a gastric juice volume of 25 mL and a pH of 2.5 pre-surgery. Ingesting water dilutes gastric juice concentration, which reduces the degree of chemical damage to the lungs after aspiration. Theoretically, therefore, it is feasible to prevent the serious consequence of aspiration by reducing the pre-surgery fasting time. The amount and timing of liquid ingested that can dilute gastric juices and increase the rate of gastric emptying are vital in reducing the incidence of aspiration.
Early in the 21st century, a Danish surgeon named Klaette described the term fast-track surgery (FTS). This involves promoting rehabilitation in surgical patients and aims to reduce stress damage in these patients to accelerate their recovery (3). Søreide et al. found that patients who followed a traditional fasting schedule pre-surgery had a gastric juice volume of 19–22 mL and a stomach pH of 1.9–2.0, and patients who ingested 400 mL of water 2 hours prior to surgery had a gastric juice volume of 17–20 mL and a pH of 1.9. This indicates that the volume of fluid and pH in the stomach are primarily determined by stomach secretions (4). Nygren et al. found in the 1990s that the administration of preoperative carbohydrates could improve postoperative IR more effectively than ordinary liquids (5). Onalan et al. showed that preoperative oral carbohydrates improved postoperative IR of patients receiving laparoscopic cholecystectomy (LC) (6).
The purpose of the present study was to improve and standardize the use of preoperative oral carbohydrates in patients with surgery.
We present the following article in accordance with the CONSORT reporting checklist (available at http://dx.doi.org/10.21037/apm-20-1424).
Methods
Participants
One hundred and twenty-five patients with multiple injuries that presented to the Emergency Surgery Department of the Affiliated Hospital of Nantong University between August, 2019, and February, 2020, were selected for this study. Of these 125 patients, 82 (39 males and 43 females) completed the trial and produced evaluable data. Participants’ ages ranged from 25–75 years old. The inclusion criteria were as follows: an injury severity score no greater than 16 and a body mass index (BMI) of 18.5–23.9 kg/m2.
The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013), and has been approved by the Ethics Committee of the Affiliated Hospital of Nantong University (Approval number: 2019-L002), and all the subjects and their families signed the informed consent documents.
Randomization
The patients were randomly divided into two groups, the carbohydrate group (CHO group) and the non-carbohydrate group (non-CHO group). Patients in the CHO group (n=51) were given 400 mL of oral carbohydrate after fasting for 12 hours and not ingesting fluids for 4 hours prior to surgery. Patients in the non-CHO group (n=50) fasted for 12 hours prior to surgery. All patients were operated on by the same surgeon and surgical team. The anesthesia received was the same across the two groups. The operative sites of the patients with multiple injuries were recorded. There was no significant difference between the two groups in intraoperative aspiration reflux, time of operation, intraoperative bleeding volume, and intraoperative fluid replacement volume (Table 1).
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Color Doppler ultrasound
Patients in the CHO group received 400 mL of carbohydrate solution orally 3 hours prior to surgery; ingestion was complete by 2 hours prior to surgery. Patients should not finish drinking carbohydrates for more than 20 minutes. Color Doppler ultrasounds were taken at patients’ bedsides to monitor gastric filling and emptying in real time (Figure 1).
Date collection
A visual analog scale (VAS) was used to evaluate the patients’ subjective comfort, including thirst, hunger, anxiety, and nausea. The 0–100 mm scale represented discomfort levels of thirst, hunger, anxiety, and nausea, with 0 being no discomfort and 100 being maximum discomfort. Both groups fasted at 8 pm before receiving surgery. Blood glucose and insulin were measured 3 hours before and immediately after surgery, and the IR index was calculated using the homeostatic model assessment (HOMA) formula: HOMA-IR = Fasting Plasma Glucose (FPG) × Fasting Insulin (FINS)/22.5.
Statistical analysis
SPSS Statistics 23.0 (SPSS Inc., Chicago, IL, USA) was used to analyze the data. The mean ± standard deviation was used to describe data with normal distribution, and the median (quartile) was used to describe data with skewed distribution. Chi-square tests were used for normally distributed data, and t-tests were used to determine statistical differences between the two groups.
Results
Patients
A flow chart of participant selection is presented in Figure 2. A total of 82 participants (39 males and 43 females) were ultimately recruited in this study. The individual characteristics of the patients are expressed in Tables 2,3. There were no significant differences between the two groups.
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Full table
Degree of comfort
There was no significant difference between the two groups in subjective comfort levels as measured by thirst, hunger, anxiety, and nausea 3 hours before surgery (P>0.05) (Table 4). Within the CHO group, there was no difference between thirst, anxiety, and nausea 3 hours before surgery and 1 hour before surgery. Within the non-CHO group, hunger was significantly increased 1 hour before surgery compared with 3 hours before surgery. The subjective feelings, such as thirst, hunger, and anxiety, were significantly higher 1 hour before surgery in the non-CHO group compared with the CHO group (Figure 3).
Full table
Blood glucose, insulin, and HOMA index
Table 5 shows that there were no significant differences between the two groups in fasting blood glucose concentration, fasting insulin concentration, and IR index 3 hours before surgery. The blood glucose concentration, insulin concentration, and IR index of the two groups immediately following surgery were significantly higher than those prior to surgery. The levels of blood glucose, insulin concentration and IR index in CHO group were lower than those in non-CHO group immediately after the operation (Figure 4).
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Complications
There was one case of restlessness, one case of dehiscence, and one case of urinary tract infection post-surgery in the CHO group. In the non-CHO group, there was one case of vomiting, two cases of diarrhea, and one case of incision infection. There was no significant difference between the two groups in post-surgical complications (Table 6).
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Length of hospital stay
Studies have shown that taking carbohydrates before surgery can reduce patients’ hospital stay and promote rapid recovery after surgery (7). In our study, the length of hospital stay was significantly reduced in the CHO group compared with the non-CHO group (CHO group: 11.29±2.77; non-CHO group: 13.04±4.00; P<0.05) (Figure 5).
Discussion
Reducing postoperative IR plays a central role in the rapid surgical rehabilitation of patients. Much research has been done, to determine different methods of facilitating IR reduction after surgery. Among these methods, the application of preoperative carbohydrates stands out. Many studies have studied the physiological mechanism of preoperative carbohydrate use in reducing postoperative IR (8,9). These mechanisms include reducing the level of stress hormones, changing the function of insulin receptors and changing the number of insulin receptors. However, most of these studies have focused on insulin resistance associated with gastrointestinal surgery, and patients with mild multiple injuries undergoing elective surgery have not been studied. The purpose of our study was to investigate whether preoperative carbohydrate administration had a similar effect on patients with multiple injuries as in patients undergoing gastrointestinal surgery. We found that preoperative administration of carbohydrate solution in patients with multiple injuries can reduce immediate insulin resistance after operation, shorten hospital stay, and thus contribute to rapid recovery. It also reduces the incidence of aspiration and improves the comfort of patients.
IR was present in the multiple injuries patients that participated in our study and was evaluated before and after the patients received surgery. However, hepatic glucose output cannot be completely inhibited by steady-state insulin concentrations in classic experiments, such as the glucose clamp test. This directly affects insulin sensitivity (10). HOMA-IR (FPG × FINS/22.5) has been used to evaluate the IR index in several studies on this subject and is determined by measuring fasting blood glucose and fasting insulin concentration. HOMA-IR was therefore used to determine the IR index in our study.
It (Table 7) shows the components of the carbohydrate solution given to the patient before operation, which, among other beneficial effects, avoids aspiration. Although osmotic pressure and viscosity were previously thought to be closely related, current studies have shown that gastric emptying time mainly depends on energy density. Electrolytes can also shorten the time of gastric emptying. Another important point is that carbohydrates are more palatable than glucose solutions (11,12). Therefore, the carbohydrate solution used in our study consists not only of glucose, but also potassium, sodium, chlorine and other electrolytes. The only substance that provides energy is glucose, and there is no fat or protein in the solution.
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Methods to reduce the incidence of aspiration were initially explored in fields such as obstetric anesthesia (13). As a result of this research, Mendelson proposed in the mid-20th century that patients fast preoperatively from midnight of the day of the surgery; this has been routine since. Due to the relatively long fasting time (fasting including no eating and no drinking), individual differences between patients in gastric emptying can be ignored. Some studies have shown that the volume and acidity of gastric contents is not reduced after a long time of fasting and drinking, and this routine has gradually been proved to be one-sided in subsequent experiments (14-16).
The most common methods for evaluating the subjective comfort of patients are the VAS and the numerical rating scale (NRS). These measures are both easy to use in a clinical setting. The VAS requires patients to mark their level of comfort on a visual scale, which may be difficult for some elderly people (17,18). NRS is used more frequently around the world, although some studies have shown that the correlation between VAS and NRS can be used to evaluate patients’ subjective comfort more accurately (19). In our study, VAS was used to evaluate the subjective feelings of patients with multiple injuries including thirst, hunger, anxiety, and nausea. No significant difference was found between the CHO group and the non-CHO group 3 hours prior to surgery. However, one hour before operation, the subjective levels of thirst, hunger and anxiety in the CHO group were significantly lower than those in the non-CHO group. Fasting from midnight can lead to water loss, lower blood sugar levels, depletion of extracellular fluid, and stimulation of hypothalamic osmotic receptors and thirst centers. In addition, fasting from midnight leads to less stimulation in the hypothalamic satiety center, while increased neuronal stimulation in the hypothalamic feeding center leads to thirst and hunger. The increase in the activity of the feeding center will reduce the activity of the satiety center, and this anxiety is related to the activity of the satiety center. Studies have found that taking carbohydrates before surgery can reduce the discharge frequency of satiety centers, thereby reducing anxiety (20).
The study showed that when anxious patients took 400 milliliters of oral carbohydrate solution three hours before surgery, stomach contents were emptied to safe residues in the same time as healthy people (20,21). The carbohydrate solution used in this experiment was nearly isotonic; it did not contain fat, protein, or other substances that prolong gastric emptying time. In theory, this makes the solution relatively safe. Our study found that no patients who took oral carbohydrate solution prior to surgery experienced aspiration. Additionally, they experienced no increase in clinical complications such as infection, agitation, vomiting, or diarrhea.
The body’s stress response is stimulated by stressors such as trauma, infection, blood loss, and hypothermia. Stress on metabolism is characterized by metabolic syndrome and inflammation. Metabolic syndrome is primarily a glucose metabolism disorder, but it includes other metabolic disorders, such as lipid metabolism disorder. The body produces greater amounts of stress hormones when under stress, which hinders sugar oxidation. At the same time, free fatty acids and amino acids antagonize glucose oxidation. A dominant characteristic of metabolic syndrome is IR. Type 2 diabetes mellitus is characterized by initial IR, followed by insufficient insulin secretion. Studies have shown that the development of type 2 diabetes is related to IR mediated by inflammatory factors, such as IL-1, IL-6, IL-8, IL-12, and TNF-α (22). Therefore, inflammation caused by stress is related to IR.
IR with hyperinsulinemia is a risk factor for cardiovascular diseases, such as hypertension, cardiomyopathy, coronary heart disease, arrhythmia, and heart failure by multiple pathways (23). Activation of the renin-angiotensin-aldosterone system (RAAS) by IR leads to vascular smooth muscle proliferation, hypertrophy, and arteriosclerosis (24).
The purpose of our study was to investigate the effect of carbohydrates on immediate postoperative IR in patients with multiple injuries who underwent selective surgery. Before surgery there were no significant differences between the CHO group and the non-CHO group in fasting blood glucose, fasting insulin concentration, or IR index, although the non-CHO group exhibited higher values than the CHO group. Immediately after surgery, the IR index was lower in the CHO group than in the non-CHO group. This suggests that preoperative fixed-time and quantitative carbohydrates can improve immediate IR in patients with multiple injuries. The specific mechanism was not investigated in our experiment.
Studies have shown that carbohydrates can be fermented and degraded by intestinal flora to produce short-chain fatty acids (SCFA), and butyrate can increase intestinal mucus production, the expression of zonulin, occludin, and tight junction proteins, as well as reduce intestinal permeability to maintain the intestinal barrier (25-27). Clostridium flexneri, Enterococcus, Bacteroides, and Escherichia coli levels in type 2 diabetes patients were higher than that present in healthy subjects. It is currently believed that the relative improvement of IR in the CHO group may be related to intestinal flora regulation by the carbohydrates administered prior to surgery, maintenance of the intestinal barrier, and reduction of the inflammatory response secondary to stress-induced intestinal flora displacement (28).
Studies have shown that ingesting carbohydrates prior to surgery can promote rapid recovery and reduce the length of hospital stay (7,29,30). Inconsistent findings across studies may be a result of inconsistent treatments administered to patients and differences between these surgical patients.
Conclusions
The administration of 400 mL of carbohydrate solution before surgery improved patients’ subjective comfort in terms of thirst, hunger, and anxiety, but there was no significant improvement in nausea. The incidence of post-surgical complications did not increase with carbohydrate administration. In addition to being safe and improving subjective comfort levels, carbohydrate administration before surgery also reduced immediate IR post-surgery, promoted rapid recovery in patients with multiple injuries, and reduced their length of hospital stay. Further exploration is required, however, to determine the mechanism by which IR is improved.
Acknowledgments
Funding: This study was supported by the National Natural Science Foundation of China (81801893) and the Nantong Clinical Medicine Research Center (HS2019005).
Footnote
Reporting Checklist: The authors have completed the CONSORT reporting checklist. Available at http://dx.doi.org/10.21037/apm-20-1424
Data Sharing Statement: Available at http://dx.doi.org/10.21037/apm-20-1424
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at http://dx.doi.org/10.21037/apm-20-1424). The authors have no conflicts of interest to declare.
Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013), and has been approved by the Ethics Committee of the Affiliated Hospital of Nantong University (Approval number: 2019-L002), and all the subjects and their families signed the informed consent documents.
Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.
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(English Language Editors: B. Madden and J. Reynolds)