Perioperative Glucose Monitoring and Treatment to Reduce Risk of Surgical Site Infections and Complications

Not Applicable

• Conditions: Surgical Site Infections; Stress Hyperglycemia
• Interventions: Drug: Insulin Lispro Injection; Diagnostic Test: glucose testing

• Registration Number: NCT06765655
• Lead Sponsor: St. Peter's Hospital, Albany, NY

Brief Summary

This study is to determine if glucose monitoring and treatment in surgical procedures over 2 hours help to decrease the surgical site infection risk and reduce postoperative complications. The study uses a preoperative HgBA1C to place patient into a sliding scale insulin category to be used only if the patient has a blood sugar over 150mg/dL during surgery. This is consistent with the CDC recommendation to keep perioperative glucose below 200 mg/dL in surgical patients. The protocol continues for at least 48 hours to treat stress hyperglycemia in non-diabetic patients, and to closely monitor \& treat glucose levels in diabetic patients.

Detailed Description

Background

Diabetes and variations in glucose control are comorbidities that increase complications in the surgical patient (Harris, 2018). Insulin signaling is impaired during surgery and transient insulin resistance develops. Decreased circulating insulin levels lead to a physiological hyperglycemic response that lasts 24 to 48 hours after surgery. Surgeries involving the chest and abdomen have a longer and more pronounced degree of hyperglycemia reaction in the body (Peacock, 2019). The prevalence of surgical site infections (SSIs) in surgical patients across the United States has gained significant attention as preventable healthcare infections from the Centers for Disease Control and Prevention (CDC) in recent years. A stratified list supporting this evidence was published by the CDC in 1999 titled Prevention of Surgical Site Infection and is the accepted practice guideline for preventing SSIs (Berrios-Torres et al., 2017). The CDC directs surgical specialties to reduce perioperative glycemic control protocol targets to less than 200 mg/dl for all surgical patients to reduce SSIs (Sermkasemskin et al., 2022). Similar evidence-based guidelines were published by the World Health Organization (WHO) and the American College of Surgeons (ACS) (Camperlengo et al., 2023). Nearly six years after these strong guidelines were published, there is still limited evidence that SSI prevention activities are being followed (Camperlengo et al., 2023).

Perioperative stress hyperglycemia is underestimated because of its presumed lower incidence rate compared to diabetes. The rise in patients presenting to surgical facilities with impaired fasting glucose and/or insulin resistance varies from 23 to 60%.

Stress hyperglycemia is summarized as increased glycogenolysis, insulin resistance, and excessive gluconeogenesis in response to neuroendocrine triggers of stress stimulated by the hypothalamic-pituitary-adrenal axis, sympathoadrenal system receptors, and proinflammatory cytokines. The cytokines are tumor necrosis factor-α, interleukin (IL)-1, and IL-6 (Sermkasemsin et al., 2022). Risk factors for stress hyperglycemia include unknown diabetes, a high American Society of Anesthesiologists (ASA) risk score, long surgical duration, blood transfusion, and intraoperative hypotension (Sermkasemskin et al., 2022).

Purpose

The purpose of this DNP project is to focus on reducing postoperative complications by expanding the intraoperative glucose monitoring and treatment protocol to include all surgical patients with procedures lasting over two (2) hours at risk for stress hyperglycemia. The hypothesis is there will be a statistically significant decrease in postoperative complications directly related to longer surgical cases (Peacock, 2019).

Aims and Objectives

Perioperative Glucose Monitoring (POGM) will take place during surgeries that last over two (2) hours St. Peter's Health Partners. The implementation of POGM will occur directly in the operating rooms based on the developed protocol. The review of perioperative data will occur remotely in the outpatient surgical setting through chart reviews by the principal investigator. The objectives of the study are reproducible across all surgical specialties. They include:

1. Obtaining Hemoglobin A1C and blood glucose in enrolled surgical patients preoperatively regardless of diabetes status.

2. Assess blood glucose every two (2) hours perioperatively due to peak action of rapid-release insulin.

3. Institute a standard hyperglycemia treatment protocol via sliding scale rapid acting insulin for any patient with perioperative blood glucose elevations \>150 mg/dL.

4. Monitor for postoperative infections, morbidity, and mortality for the sample of enrolled surgical patients for 30 days after surgical intervention. This includes postoperative office visits and phone calls checking on status.

The goal of this study is to lay the groundwork for adapting practice guidelines to meet the modern health needs of our diverse patient population.

Setting

IOGM will occur within the surgical departments of St. Peter's Health Partners (Albany, NY). The implementation of POGM will occur directly in the OR suites based on the developed protocol.

Sample

The pilot study will consist of recruiting adult surgical patients of a participating surgeon. Informed consent is for the collection of patient-related surgical data through medical record review to determine surgical outcomes with POGM. The patient is required to be scheduled for a surgical procedure expected to last 2 hours (120 minutes) at minimum. A power analysis of sample size was made by reviewing random operative cases at SPH in January 2023 through a meta-analysis for this project. The goal is to establish a statistically significant sample size based on probability to avoid a Family-Wise Error Rate that results from incorrect statistical significance related to a sample size that is too large (Thomas \& Campbell, 2021). Using a 95% confidence interval and an estimate within 10% of the true proportion of patients that would have intraoperative hyperglycemia, an estimated 76 study participants would be needed.

Target Population

There is currently an inequitable perioperative monitoring of patients based on the Medical Model of Disability. Glucose monitoring perioperatively typically only occurs when there is a known diagnosis of diabetes (DM) per hospital policy. However, the evidence that stress hyperglycemia exists in surgical patients not identified as diabetics contributes to the noted increase in postoperative complications in this population.

Design

The quantitative quasi-experimental research study design yields a high level of descriptive statistical data collected at a ratio/interval level, including the presence of postoperative complications, HgbA1C, and glucose readings. The well-established method of glucose POCT will determine if a patient becomes hyperglycemic during the surgical procedure and can reliably indicate if treatment is needed per hospital protocol. This POCT has strong predictive validity, reflects existing theories, and has strong test/retest reliability (Thomas \& Campbell, 2021). From pre-surgery to the end of data collection, the anticipated time to assess the initial impact of the POGM protocol is expected to be approximately 8-12 weeks. This would include initial surgical consultation, an informed consent process, and implementing POGM for each surgical case. Each patient will be monitored for 30 days after surgery for postop complications. The complexity of postop complications is calculated using the Comprehensive Complication Index (CCI) (Hyer et al., 2019)

Data Collection

Quantitative data will be collected during the three (3) perioperative phases via point-of-care (POCT) glucose testing. This monitoring will begin as a pilot test in a select group of surgical patients based on voluntary surgeon enrollment.

Comparison data will be obtained through retrospective analysis of medical records from patients who had surgical procedures \>2 hours and occurred before the quality improvement program implementation. A retrospective review of pre- and postoperative POCT glucose levels on the surgical cases of participating surgeons for 2 months prior to implementation of POGM will be performed. Any glucose elevations that may have triggered insulin administration per sliding scale protocol will be noted along with any documented postop SSI occurrence or complication.

Study Timeline

• Study Start: 2024-04-09
• Status Verified: 2024-09
• Study First Submitted: 2025-01-03
• Study First Submitted QC: 2025-01-03
• Last Update Submitted: 2025-01-03
• Study First Posted: 2025-01-09
• Last Update Posted: 2025-01-09
• Primary Completion: 2025-01-31
• Study Completion: 2025-01-31

Recruitment & Eligibility

• Status: ENROLLING_BY_INVITATION
• Sex: All
• Target Recruitment: 266

Inclusion Criteria

Any adult surgical patient who undergoes a procedure expecting to last 2 or more hours regardless of age, gender, race, sex, religion, nation of origin, or other identifiable demographics -

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Exclusion Criteria

Type 1 Diabetes or other patients with strick endocrinology orders

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Study & Design

• Study Type: INTERVENTIONAL
• Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
POGM	Insulin Lispro Injection	Patients will have preoperative Hemoglobin A1C and monitoring of blood glucose every 2 hours during their surgery. If the blood glucose rises over 150 mg/dL, insulin lispro will be administered per sliding scale protocol based on their A1C. Monitoring continues for 48 hours with treatment per protocol as needed.
POGM	glucose testing	Patients will have preoperative Hemoglobin A1C and monitoring of blood glucose every 2 hours during their surgery. If the blood glucose rises over 150 mg/dL, insulin lispro will be administered per sliding scale protocol based on their A1C. Monitoring continues for 48 hours with treatment per protocol as needed.

Primary Outcome Measures

Name	Time	Method
Surgical Site Infections	From date of surgery to the end of 30 day postop timeframe	Assess for the development of superficial, deep, or organ space infections within 30 days of surgery

Secondary Outcome Measures

Name	Time	Method
Postoperative Complications	From date of surgery to the end of 30 day postop timeframe	Assess for the development and severity of other postoperative complications. Categories include sepsis, cardiac, respiratory, GI, hematologic, Urinary, readmission/reoperation and death.

Trial Locations

Locations (1)

St. Peter's Hospital; 🇺🇸 Albany, New York, United States