Once-Daily Insulin Glargine Versus 6-Hour Sliding Scale Regular Insulin for Control of Hyperglycemia after a Bariatric Surgical Procedure: A Randomized Clinical Trial

ObjectiveTo determine whether once-daily insulin glargine could provide better glycemic control after an abdominal surgical procedure than the traditional use of sliding scale regular insulin (SSRI).MethodsBecause 20% to 30% of patients undergoing gastric bypass have a history of overt diabetes and another 5% to 10% are estimated to have impaired glucose tolerance, we chose to study these patients. We treated 81 patients with postoperative blood glucose levels of more than 144 mg/dL after a Roux-en-Y gastric bypass surgical procedure. They were randomized to receive either SSRI or insulin glargine either directly or after initial intravenous insulin infusion in the intensive care unit (ICU).ResultsOverall, the mean blood glucose level after SSRI therapy was 154 ± 33 mg/dL, and the mean blood glucose value after insulin glargine treatment was 134 ± 30 mg/dL (P < 0.01). The mean blood glucose level for patients first treated with intravenous insulin infusion in the ICU was 125 mg/dL, in comparison with 145 mg/dL in the non-ICU patients whose treatment began directly with 0.3 U/kg of insulin glargine. Of 926 blood glucose measurements, only 3 were less than 60 mg/dL.ConclusionIn this study, control of postoperative hyperglycemia was significantly better with use of insulin glargine in comparison with SSRI therapy, and hypo-glycemia was very infrequent. (Endocr Pract. 2007;13: 225-231)     

Benchmarking Glycemic Control In U.S. Hospitals

ObjectiveReport data on glucose control from 635 U.S. hospitals.MethodsPoint-of-care blood glucose (POC-BG) test data from January through December 2012 from 635 facilities were extracted. Glucose control was evaluated using patient-day–weighted mean POC-BG values. We calculated hypoglycemia and hyperglycemia rates, stratified by presence or absence of intensive care unit (ICU) admission, and we evaluated the relationship between glycemic control and hospital characteristics.ResultsIn total, 51,375,764 POC-BG measurements (non-ICU, 39,197,762; ICU, 12,178,002) from 2,612,966 patients (non-ICU, 2,415,209; ICU, 575,084) were analyzed. The mean POC-BG was 167 mg/dL for non-ICU patients and 170 mg/dL for ICU patients. The prevalence of hyperglycemia (defined as glucose value > 180 mg/dL) was 32.3 and 28.2% in non-ICU and ICU patients, respectively. The prevalence of hypoglycemia (defined as glucose value < 70 mg/dL) was 6.1 and 5.6% in non-ICU and ICU patients, respectively. In non-ICU and ICU settings, the patient-day–weighted mean glucose was highest in the smallest hospitals, in rural hospitals, and in hospitals located in the Northeast (all P < .01). For non-ICU patients, we observed a significant difference in the percentage of patient days with hypoglycemia by geographic region only (P < .001). In ICU patients, the prevalence of hypoglycemia varied significantly by hospital type (P < .03) and geographic region (P < .01).ConclusionIn this largest POC-BG data set analysis conducted to date, glycemic control varied according to hospital characteristics. Our findings remain consistent with previous reports. Among other variables, national benchmarking of inpatient glucose data will need to consider differences in hospital characteristics. (Endocr Pract. 2014;20:876-883)     

Adapting to the new consensus guidelines for managing hyperglycemia during critical illness: the updated Yale insulin infusion protocol

ObjectiveTo report our preliminary experience with the revised, more conservative Yale insulin infusion protocol (IIP) that targets blood glucose concentrations of 120 to 160 mg/dL.MethodsWe prospectively tracked clinical responses to the new IIP in our medical intensive care unit (ICU) by recording data on the first 115 consecutive insulin infusions that were initiated. All blood glucose values; insulin doses; nutritional support including intravenous dextrose infusions; caloric values for enteral and parenteral nutrition; and use of vasopressors, corticosteroids, and hemodialysis or continuous venovenous hemodialysis were collected from the hospital record.ResultsThe IIP was used 115 times in 90 patients (mean age, 62 [± 14 years]; 51% male; 35% ethnic minorities; 66.1% with history of diabetes). The mean admission Acute Physiology and Chronic Health Evaluation II score was 24.4 (± 7.5). The median duration of insulin infusion was 59 hours. The mean baseline blood glucose concentration was 306.1 (± 89.8) mg/dL, with the blood glucose target achieved after a median of 7 hours. Once the target was reached, the mean IIP blood glucose concentration was 155.9 (± 22.9) mg/dL (median, 150 mg/dL). The median insulin infusion rate required to reach and maintain the target range was 3.5 units/h. Hypoglycemia was rare, with 0.3% of blood glucose values recorded being less than 70 mg/dL and only 0.02% being less than 40 mg/dL. In all cases, hypoglycemia was rapidly corrected using intravenous dextrose with no evident untoward outcomes.ConclusionsThe updated Yale IIP provides effective and safe targeted blood glucose control in critically ill patients, in compliance with recent national guidelines. It can be easily implemented by hospitals now using the original Yale IIP. (Endocr Pract. 2012;18:363-370)     

Update on Inpatient Glycemic Control in Hospitals in the United States

ObjectiveTo provide data on glucose control in hospitals in the United States, analyzing measurements from the largest number of facilities to date.MethodsPoint-of-care bedside glucose (POC-BG) test results were extracted from 575 hospitals from January 2009 to December 2009 by using a laboratory information management system. Glycemic control for patients in the intensive care unit (ICU) and non-ICU areas was assessed by calculating patient-day-weighted mean POC-BG values and rates of hypoglycemia and hyperglycemia. The relationship between POC-BG levels and hospital characteristics was determined.ResultsA total of 49,191,313 POC-BG measurements (12,176,299 ICU and 37,015,014 non-ICU values) were obtained from 3,484,795 inpatients (653,359 in the ICU and 2,831,436 in non-ICU areas). The mean POC-BG was 167 mg/dL for ICU patients and 166 mg/dL for nonICU patients. The prevalence of hyperglycemia (> 180 mg/ dL) was 32.2% of patient-days for ICU patients and 32.0% of patient-days for non-ICU patients. The prevalence of hypoglycemia (< 70 mg/dL) was 6.3% of patient-days for ICU patients and 5.7% of patient-days for non-ICU patients. Patient-day-weighted mean POC-BG levels varied on the basis of hospital size (P < .01), type (P < .01), and geographic location (P < .01) for ICU and non-ICU patients, with larger hospitals (≥ 400 beds), academic hospitals, and US hospitals in the West having the lowest mean POC-BG values. The percentage of patient-days in the ICU characterized by hypoglycemia was highest among larger and academic hospitals (P < .05) and least among hospitals in the Northeast (P < .001).ConclusionHyperglycemia is common in hospitals in the United States, and glycemic control may vary on the basis of hospital characteristics. Increased hospital participation in data collection may support a national benchmarking process for the development of optimal practices to manage inpatient hyperglycemia. (Endocr Pract. 2011;17:853-861)     

Safety and Efficacy of a Peri-Operative Protocol for Patients with Diabetes Treated with Continuous Subcutaneous Insulin Infusion who are Admitted for Same-Day Surgery

Objective: The number of people with diabetes using continuous subcutaneous insulin infusions (CSII) with an insulin pump has risen dramatically, creating new challenges when these patients are admitted to the hospital for surgical or other procedures. There is limited literature guiding CSII use during surgical procedures.Methods: The study was carried out in a large, urban, tertiary care hospital. We enrolled 49 patients using insulin pump therapy presenting for 57 elective surgeries. We developed a CSII peri-operative glycemic management protocol (PGMP) to standardize insulin pump management in patients admitted to a same-day surgery unit (SDSU). The purpose was evaluate the safety (% capillary blood glucose (CBG) <70 mg/dL and/or pump incidents) and efficacy (first postoperative CBG ≤200 mg/dL) of the CSII PGMP. We determine the contribution of admission CBG, type of anesthesia, surgery length, and peri-operative steroid use on postoperative glycemic control.Results: Overall, 63% of patients treated according to the CSII PGMP had a first postoperative CBG ≤200 mg/dL. There were no episodes of intra- or postoperative hypoglycemia. For patients treated with the CSII PGMP, the mean postoperative CBG was lower in patients with anticipated or actual surgical length ≤120 minutes (158.1 ± 53.9 vs. 216 ± 77.7 mg/dL, P<.01). No differences were observed with admission CBG, type of anesthesia, or steroid use.Conclusions: This study demonstrates that a CSII PGMP is both safe and effective for patients admitted for elective surgical procedures and provides an example of a standardized protocol for use in clinical practice.Abbreviations: A1C = glycated hemoglobin BG = blood glucose CBG = capillary blood glucose CSII = continuous subcutaneous insulin infusion DM = diabetes mellitus EMR = electronic medical record IV = intravenous PGMP = peri-operative glycemic management protocol SDS = same-day surgery SDSU = same-day surgery unit SQ = subcutaneous UC = usual care     

Comparison of 3 Algorithms for Basal Insulin in Transitioning from Intravenous to Subcutaneous Insulin in Stable Patients after Cardiothoracic Surgery

ObjectiveTo determine the effectiveness of an algorithm containing 1 of 3 initial subcutaneous doses of insulin detemir and flexible prandial and supplemental insulin aspart in stable patients who have undergone cardiac surgery and are being transitioned off intravenous insulin infusion.MethodsPatients were extubated, were not taking vasopressors, and were otherwise stable, requiring at least 1 unit per hour of intravenous insulin at least 48 hours after surgery. Patients were randomly assigned to once-daily insulin detemir at 50%, 65%, or 80% of intravenous basal insulin requirements and received insulin aspart according to carbohydrate intake. The dose of insulin detemir was adjusted daily over 72 hours.ResultsEighty-two patients were included. The percentages of patients with an initial morning glucose concentration of 80 to 130 mg/dL were 36%, 63%, and 56% of patients at the 50%, 65%, and 80% doses, respectively (P = .12). However, the mean overall glucose value at 24 and 72 hours was similar between groups, and 86%, 93%, and 92% of patients in each group, respectively, achieved a mean glucose concentration of 80 to 180 mg/dL at 72 hours (P = .60). Hypoglycemia (glucose < 65 mg/dL) only occurred in the 65% group (21%) and the 80% group (12%) over the first 72 hours (P = .02 in the 50% group compared with the 65% and 80% groups combined) with 1 event of a glucose concentration less than 40 mg/dL in the 80% group. There was no loss of glycemic control by the end of the once-daily dosing interval.ConclusionsGlycemic targets can be achieved without hypoglycemia by 72 hours in most patients who have undergone cardiac surgery and require intravenous insulin with a regimen consisting of an initial insulin detemir dose of 50% of basal intravenous insulin requirements and prandial and supplemental insulin. (Endocr Pract. 2011; 17:753-758)     

Standardized Glycemic Management and Perioperative Glycemic Outcomes in Patients with Diabetes Mellitus who Undergo Same-Day Surgery

ObjectiveTo assess the safety and effectiveness of a standardized glycemic management protocol in patients with diabetes mellitus who undergo same-day surgery.MethodsThe perioperative glycemic management protocol consisted of preoperative instructions and perioperative order sets for management of subcutaneous and intravenous insulin. Patients with known diabetes admitted to same-day surgery during a 10-month period were observed. Patient demographic information and all capillary blood glucose (CBG) values obtained during the sameday surgery visit were collected. Hyperglycemia, defined as a CBG concentration of 200 mg/dL or greater, prompted notification of the attending anesthesiologist. While use of the perioperative order sets was encouraged, the attending anesthesiologist retained the prerogative to treat according to these order sets or their usual care. Physician compliance with the standardized order sets was determined by chart review in the patients who had a documented blood glucose value of 200 mg/dL or greater.ResultsPatients managed with the standardized order sets had greater reductions in CBG values (percentage change, 35 ± 20.5% vs 18 ± 24%, P < .001) and lower postoperative CBG values (186 ± 53 mg/dL vs 208 ± 63 mg/dL, P < .05) than patients who received usual care. No cases of intraoperative or postoperative hypoglycemia (CBG < 70 mg/dL) were observed in either group.ConclusionsA systematic approach to glycemic management that includes instructions for preoperative adjustments to home diabetic medications and order sets for treatment of perioperative hyperglycemia is safe and can be more effective than usual care for ambulatory surgery patients with diabetes. (Endocr Pract. 2011;17:404-411)     

A Comparison of Twice-Daily Biphasic Insulin Aspart 70/30 and Once-Daily Insulin Glargine in Persons With Type 2 Diabetes Mellitus Inadequately Controlled on Basal Insulin and Oral Therapy: A Randomized,Open-Label Study

ObjectiveTo compare efficacy and safety of biphasic insulin aspart 70/30 (BIAsp 30) with insulin (glargine) in type 2 diabetic patients who were not maintaining glycemic control on basal insulin and oral antidiabetic drugs.MethodsIn a 24-week, open-label, parallel-group trial, type 2 diabetic patients who were not maintaining glycemic control on basal insulin (glargine or neutral protamine Hagedorn) + oral antidiabetic drugs were randomly assigned to twice-daily BIAsp 30 + metformin or oncedaily glargine + metformin + secretagogues (secretagogues were discontinued in the BIAsp 30 arm).ResultsOne hundred thirty-seven patients were randomly assigned to the BIAsp 30 group and 143 patients were randomly assigned to the glargine group. Of 280 patients randomized, 229 (81.8%) completed the study. End-of-trial hemoglobin A_1c reductions were − 1.3% (BIAsp 30) vs − 1.2% (glargine) (treatment difference: 95% confidence interval, − 0.06 [− 0.32 to 0.20]; P = .657). Of patients taking BIAsp 30, 27.3% reached a hemoglobin A_1c level < 7.0% compared with 22.0% of patients taking glargine (treatment difference: P = .388). Glucose increment averaged over 3 meals was lower in the BIAsp 30 arm (treatment difference: − 17.8 mg/dL, P = .001). Fasting plasma glucose reductions from baseline were − 13.8 mg/ dL (BIAsp 30) vs − 42.5 mg/dL (glargine) (P = .0002). Final minor hypoglycemia rate, insulin dose, and weight change were higher in the BIAsp 30 arm (6.5 vs 3.4 events/patient per year, P <.05; 1.19 vs 0.63 U/kg; and 3.1 vs 1.4 kg, P = .0004, respectively).ConclusionsDespite not receiving secretagogues, patients taking BIAsp 30 + metformin achieved similar hemoglobin A_1c levels and lower postprandial plasma glucose compared with those receiving glargine + metformin + secretagogues. The large improvement in the glargine group suggests the patients were not true basal failures at randomization. While switching to BIAsp 30 improves glycemic control in this patient population, remaining on basal insulin and optimizing the dose may be equally effective in the short term. (Endocr Pract. 2011;17:41-50)     

Chromium Infusion In Hospitalized Patients with Severe Insulin Resistance: A Retrospective Analysis

ObjectiveTo investigate the effects of intravenous chromium on serum glucose and insulin infusion rates in hospitalized patients with severe insulin resistance.MethodsIn this retrospective study, we reviewed hospital records from January 1, 2008, to December 1, 2008, to identify patients for whom intravenous chromium was ordered at our academic medical center. To be included, patients were required to demonstrate profound insulin resistance and uncontrolled hyperglycemia (defined as the inability to achieve a blood glucose value less than 200 mg/ dL during the 12 hours before chromium was given despite administration of continuous insulin infusion at a rate of 20 or more units/h) and to have received a continuous infusion of chromium chloride at 20 mcg/h for 10 to 15 hours for a total dose of 200 to 240 mcg.ResultsFourteen patients met our inclusion criteria. Over the hour preceding intravenous chromium infusion, the mean ± standard deviation rate of insulin infusion was 31 ± 15 units/h, and blood glucose was 326 ± 86 mg/dL. Twelve hours after the initiation of chromium, these values were 16 ± 16 units/h and 162 ± 76 mg/dL, respectively (P = .011 for difference in mean insulin rate from baseline, P <.001 for difference in mean blood glucose from baseline) and 24 hours after, these values were 12 ± 15 units/h and 144 ± 48 mg/dL, respectively (P <.001 for both).ConclusionsIntravenous chromium decreases insulin needs and improves glucose control at 12 and 24 hours compared with baseline values. Chromium appears to improve hyperglycemia and insulin resistance in acutely ill patients and represents a potential new therapy. Future prospective randomized controlled trials are needed to confirm these results. (Endocr Pract. 2012;18:394-398)     

Inpatient Hypoglycemic Events in a Comparative Effectiveness Trial for Glycemic Control in a High-Risk Population

Objective: Inpatient hypoglycemia (glucose ≤70 mg/dL) is a limitation of intensive control with insulin. Causes of hypoglycemia were evaluated in a randomized controlled trial examining intensive glycemic control (IG, target 140 mg/dL) versus moderate glycemic control (MG, target 180 mg/dL) on post–liver transplant outcomes.Methods: Hypoglycemic episodes were reviewed by a multidisciplinary team to calculate and identify contributing pathophysiologic and operational factors. A subsequent subgroup case control (1:1) analysis (with/without) hypoglycemia was completed to further delineate factors. A total of 164 participants were enrolled, and 155 patients were examined in depth.Results: Overall, insulin-related hypoglycemia was experienced in 24 of 82 patients in IG (episodes: 20 drip, 36 subcutaneous [SQ]) and 4 of 82 in MG (episodes: 2 drip, 2 SQ). Most episodes occurred at night (41 of 60), with high insulin amounts (44 of 60), and during a protocol deviation (51 of 60). Compared to those without hypoglycemia (n = 127 vs. n = 28), hypoglycemic patients had significantly longer hospital stays (13.6 ± 12.6 days vs. 7.4 ± 6.1 days; P = .002), higher peak insulin drip rates (17.4 ± 10.3 U/h vs. 13.1 ± 9.9 U/h; P = .044), and higher peak insulin glargine doses (36.8 ± 21.4 U vs. 26.2 ± 24.3 U; P = .035). In the case-matched analysis (24 cases, 24 controls), those with insulin-related hypoglycemia had higher median peak insulin drip rates (17 U/h vs. 11 U/h; P = .04) and protocol deviations (92% vs. 50%; P = .004).Conclusion: Peak insulin requirements and protocol deviations were correlated with hypoglycemia.Abbreviations:DM = diabetes mellitusICU = intensive care unitIG = intensive glycemic controlMELD = Model for End-stage Liver DiseaseMG = moderate glycemic controlSQ = subcutaneous     

Eating and Glycemic Control Among Critically Ill Patients Receiving Continuous Intravenous Insulin

Objective: Consensus guidelines recommend that intensive care unit (ICU) patients with blood glucose (BG) levels >180 mg/dL receive continuous intravenous insulin (CII). The effectiveness of CII at controlling BG levels among patients who are eating relative to those who are eating nothing by mouth (nil per os; NPO) has not been described.Methods: We conducted a retrospective cohort study of 260 adult patients (156 eating, 104 NPO) admitted to an ICU between January 1, 2014, and December 31, 2014, who received CII. Patients were excluded for a diagnosis of diabetic ketoacidosis or hyperglycemic hyperosmolar nonketotic syndrome, admission to an obstetrics service, or receiving continuous enteral or parenteral nutrition.Results: Among 22 baseline characteristics, the proportion of patients receiving glucocorticoid treatment (GCTx) (17.3% eating, 37.5% NPO; P<.001) and APACHE II score (15.0 ± 7.5 eating, 17.9 ± 7.9 NPO; P = .004) were significantly different between eating and NPO patients. There was no significant difference in the primary outcome of patient-day weighted mean BG overall (153 ± 8 mg/dL eating, 156 ± 7 mg/dL NPO; P = .73), or day-by-day BG (P = .37) adjusted for GCTx and APACHE score. Surprisingly, there was a significant difference in the distribution of BG values, with eating patients having a higher percentage of BG readings in the recommended range of 140 to 180 mg/dL. However, eating patients showed greater glucose variability (coefficient of variation 23.1 ± 1.0 eating, 21.2 ± 1.0 NPO; P = .034).Conclusion: Eating may not adversely affect BG levels of ICU patients receiving CII. Whether or not prandial insulin improves glycemic control in this setting should be studied.Abbreviations: BG = blood glucose; CII = continuous insulin infusion; CV = coefficient of variation; HbA1c = hemoglobin A1c; ICU = intensive care unit; NPO = nil per os; PDWMBG = patient day weighted mean blood glucose     

Characterizing Glucose Changes Antecedent to Hypoglycemic Events in the Intensive Care Unit

ObjectiveTo determine whether patterns of glucose changes before hypoglycemia vary according to the severity of the event.MethodsIn this retrospective analysis, point-ofcare blood glucose (POC-BG) data were obtained from the intensive care units (ICUs) of a convenience sample of hospitals that responded to a survey on inpatient diabetes management quality improvement initiatives. To evaluate POC-BG levels before hypoglycemic events, data from patients who experienced hypoglycemia during their time in the ICU were examined, and their glucose changes were assessed against a comparison group of patients who achieved a glycemic range of 80 to 110 mg/dL without ever experiencing hypoglycemia. Absolute glucose decrease, glucose rate of change, and glucose variability before hypoglycemic events (< 40, 40-49, 50-59, and 60-69 mg/ dL) were calculated.ResultsA total of 128 419 POC-BG measurements from 2942 patients in 89 ICUs were analyzed. Patients who experienced the most severe hypoglycemic episodes had the largest absolute drop in their glucose levels before the event (P < .001). The glucose rate of change before a hypoglycemic event increased with worsening hypoglycemia: mean (± standard deviation) glucose rate of change was-1.69 (± 2.98) mg/dL per min before an episode with glucose values less than 40 mg/dL, -0.56 (± 2.65) mg/dL per min before an episode with glucose values 60 to 69 mg/dL, but only -0.39 (± 0.70) for patients who attained a glucose range of 80 to 110 mg/dL without hypoglycemia (P < .001). Glucose variability before an event progressively increased with worsening biochemical hypoglycemia and was least among patients achieving glucose concentrations in the 80 to 110-mg/dL range without hypoglycemia (P < .001).ConclusionsAntecedent glucose change and variability were greater for patients who experienced hypoglycemia. If monitored, these patterns could potentially alert clinicians and help them take preventive measures. Further examination of how these parameters interact with other predisposing risk factors for hypoglycemia is warranted. (Endocr Pract. 2012;18:317-324)     

Computerized Physician Order Entry- Based Hyperglycemia Inpatient Protocol and Glycemic Outcomes: The CPOE-HIP Study

ObjectiveTo evaluate the impact of implementing a computerized physician order entry (CPOE)-based hyperglycemia inpatient protocol (HIP) on glycemic outcomes.MethodsThis retrospective, cross-sectional study compared blood glucose values, hemoglobin A_1c values, diabetes medication profiles, and demographic data of diabetic patients admitted to medicine services between March 15, 2006, and April 11, 2006 (before CPOE-HIP protocol was adopted), with data of diabetic patients admitted between October 3, 2007, and October 30, 2007 (1 year after CPOE-HIP protocol was implemented).ResultsA total of 241 diabetic patients comprised the pre-CPOE-HIP group and 197 patients comprised the post-CPOE-HIP group. After the protocol was adopted, there was a decrease of 10.8 mg/dL in the mean glucose concentration per patient-day (175.5 ± 81.2 mg/dL vs 164.7 ± 82 mg/dL, P < .001). Additional glycemic control improvements included a 5% increase in patient-days with serum glucose concentrations between 70 and 150 mg/ dL (41.1% vs 46.1%, P = .008) and a 3.1% decrease in patient-days with glucose concentrations above 299 mg/dL (16.9% vs 13.8%, P = .023). The percentage of patientdays with glucose concentrations less than or equal to 50 mg/dL was not significantly different (0.95% vs 1.27%, P = .15). Compliance with the American Diabetes Association recommendation for hemoglobin A_1c inpatient testing frequency increased from 37.3% to 64.5% (P < .001). The length of stay did not differ between the groups.ConclusionsImplementation of a hospital-wide, CPOE-based, hyperglycemia management protocol had a favorable impact onglucose targets, decreasing excessively high glucose levels without increasing clinically meaningful hypoglycemic events. Compliance with hemoglobin A_1c testing recommendations also improved. (Endocr Pract. 2010;16:389-397)     

Examination of Implementation of Intravenous and Subcutaneous Insulin Protocols and Glycemic Control in Heart Transplant Patients

ObjectivePerioperative glycemic management is particularly challenging in heart transplant (HT) patients who are on high-dose steroids and subject to surgical stress. The objective of the study was to examine the efficacy and safety of perioperative insulin administration in HT patients with and without diabetes.MethodsMedical records of 71 HT patients from June 1, 2005 to July 31, 2009 whose hyperglycemia was managed by our Glucose Management Service (GMS) were analyzed for up to 1 year after HT. Their daily blood glucose (BG) averages on intravenous (IV) insulin drips and subcutaneous (SQ) insulin, hypoglycemia rates, reasons for hypoglycemia, and deviations from insulin protocols were analyzed.ResultsDaily BG averages between diabetic (DM) and nondiabetic (nonDM) patients were not significantly different while on the drip but were significantly different for first 5 days on SQ (P < .05). The daily insulin glargine doses were similar. No patients developed severe hypoglycemia (BG ≤ 40 mg/dL) while on drip, and only 2.8% experienced hypoglycemia on SQ. Among 40 episodes of moderate hypoglycemia while on drip, 15 had nurse deviations from protocol prior to the episode. Posttransition day fasting glucose was at goal (mean 124.7 ± 35.4 mg/dL); however 39.4% (28/71) of patients received a transition insulin glargine dose that was different from the amount indicated by protocol. The likelihood of developing moderate hypoglycemia on SQ was associated with the glargine dose used at the time of transition (odds ratio [OR] 1.03, P = .034).ConclusionInpatient insulin protocols implemented by a GMS are successful in obtaining glycemic control with minimal side effects in patients with and without diabetes, even when they are on a high-dose steroid regimen. (Endocr Pract. 2014;20:527-535)     

Safe and Simple Emergency Department Discharge Therapy for Patients with Type 2 Diabetes Mellitus and Severe Hyperglycemia

ObjectiveTo investigate the safety and effectiveness of 2 simple discharge regimens for use in patients with type 2 diabetes mellitus (DM2) and severe hyperglycemia, who present to the emergency department (ED) and do not need to be admitted.MethodsWe conducted an 8-week, open-label, randomized controlled trial in 77 adult patients with DM2 and blood glucose levels of 300 to 700 mg/dL seen in a public hospital ED. Patients were randomly assigned to receive glipizide XL, 10 mg orally daily (G group), versus glipizide XL, 10 mg orally daily, plus insulin glargine, 10 U daily (G + G group). The primary outcome was to maintain safe fasting glucose and random glucose levels of < 350 and < 500 mg/dL up to 4 weeks and < 300 and < 400 mg/ dL, respectively, thereafter and to have no return ED visits (responders).ResultsBaseline characteristics were similar between the 2 treatment groups. The primary outcome was achieved in 87% of patients in both treatment groups. The enrollment mean blood glucose values of 440 and 467 mg/dL in the G and G + G groups, respectively, declined by the end of week 1 to 298 and 289 mg/dL and by week 8 to 140 and 135 mg/dL, respectively. Homeostasis model assessment of b-cell function and early insulin response improved 7-fold and 4-fold, respectively, in responders at the end of the 8-week study.ConclusionSulfonylurea with and without use of a small dose of insulin glargine rapidly improved blood glucose levels and b-cell function in patients with DM2. Use of sulfonylurea alone once daily can be considered a safe discharge regimen for such patients and an effective bridge between ED intervention and subsequent follow-up. (Endocr Pract. 2009;15:696-704)     

Inpatient Management of Diabets Mellitus Among Noncritically Ill Patients at the University Hospital of Puerto Rico

ObjectiveTo describe the state of glycemic control in noncritically ill diabetic patients admitted to the Puerto Rico University Hospital and adherence to current standard of care guidelines for the treatment of diabetes.MethodsThis was a retrospective study of patients admitted to a general medicine ward with diabetes mellitus as a secondary diagnosis. Clinical data for the first 5 days and the last 24 hours of hospitalization were analyzed.ResultsA total of 147 noncritically ill diabetic patients were evaluated. The rates of hyperglycemia (blood glucose ≥ 180 mg/dL) and hypoglycemia (blood glucose < 70 mg/dL) were 56.7 and 2.8%, respectively. Nearly 60% of patients were hyperglycemic during the first 24 hours of hospitalization (mean random blood glucose, 226.5 mg/dL), and 54.2% were hyperglycemic during the last 24 hours of hospitalization (mean random blood glucose, 196.51 mg/dL). The mean random last glucose value before discharge was 189.6 mg/dL. Most patients were treated with subcutaneous insulin, with basal insulin alone (60%) used as the most common regimen. The proportion of patients classified as uncontrolled receiving basal-bolus therapy increased from 54.3% on day 1 to 60% on day 5, with 40% continuing to receive only basal insulin. Most of the uncontrolled patients had their insulin dose increased (70.1%); however, a substantial proportion had no change (23.7%) or even a decrease (6.2%) in their insulin dose.ConclusionThe management of hospitalized diabetic patients is suboptimal, probably due to clinical inertia, manifested by absence of appropriate modification of insulin regimen and intensification of dose in uncontrolled diabetic patients. A comprehensive educational diabetes management program, along with standardized insulin orders, should be implemented to improve the care of these patients. (Endocr Pract. 2014;20:452-460)     

Long-Acting Subcutaneously Administered Insulin for Glycemic Control Immediately After Cardiac Surgery

ObjectiveTo test the hypothesis that subcutaneous administration of basal insulin begun immediately after cardiac surgery can decrease the need for insulin infusion in patients without diabetes and save nursing time.MethodsAfter cardiac surgery, 36 adult patients without diabetes were randomly assigned to receive either standard treatment (control group) or insulin glargine once daily in addition to standard treatment (basal insulin group). Standard treatment included blood glucose measurements every 1 to 4 hours and intermittent insulin infusion to maintain blood glucose levels between 100 and 150 mg/dL. The study period lasted up to 72 hours.ResultsThere were no differences in demographics or baseline laboratory characteristics of the 2 study groups. Mean daily blood glucose levels were lower in the basal insulin group in comparison with the control group, but the difference was not statistically significant (129.3 ± 9.4 mg/ dL versus 132.6 ± 7.3 mg/dL; P = .25). The mean duration of insulin infusion was significantly shorter in the basal insulin group than in the control group (16.3 ± 10.7 hours versus 26.6 ± 17.3 hours; P = .04). Nurses tested blood glucose a mean of 8.3 ± 3.5 times per patient per day in the basal insulin group and 12.0 ± 4.7 times per patient per day in the control group (P = .01). There was no occurrence of hypoglycemia (blood glucose level < 60 mg/dL) in either group.ConclusionOnce-daily insulin glargine is safe and may decrease the duration of insulin infusion and reduce nursing time in patients without diabetes who have hyperglycemia after cardiac surgery. (Endocr Pract. 2011;17: 558-562)     

Contribution of the Dawn Phenomenon to the Fasting and Postbreakfast Hyperglycemia In Type 1 Diabetes Treated With Once-Nightly Insulin Glargine

ObjectiveTo observe the effect of the dawn phenomenon on basal glucose and postbreakfast hyperglycemia in patients with type 1 diabetes treated with once-nightly insulin glargine and premeal insulin lispro.MethodsIn 49 study subjects consuming a fixed isocaloric (50% carbohydrate) diet of usual food, the insulin glargine dose was titrated from daily continuous glucose monitoring downloads to achieve a basal glucose goal of < 130 mg/dL 4 hours after meals and during serial meal omissions but with fewer than 10% of readings at < 70 mg/ dL during 24 hours. Patients also performed self-monitoring of plasma glucose 7 times a day (before and 2 hours after each meal or omitted meal and at bedtime).ResultsThe target mean basal glucose level was achieved only during the non-dawn phenomenon period (1400 hours to 0400 hours). During the dawn phenomenon, the mean (standard deviation) basal glucose level increased from 118 (57) mg/dL at 0400 hours to 156 (67) mg/dL before the breakfast meal, a 32% increase (P = .00149). The mean self-monitored plasma glucose level with meal omission was 63.8% of that increase with a breakfast meal.ConclusionThe fasting morning glucose concentration is considerably elevated because of the dawn phenomenon. Targeting insulin titration to this glucose level may result in excessive basal insulin dosing for the non-dawn phenomenon periods of the day. The dawn phenomenon is a large component of the postbreakfast hyperglycemia. Rather than increasing the morning premeal insulin bolus, consideration should be given to pretreating the earlier dawn phenomenon with an insulin pump with use of a variable basal insulin rate. (Endocr Pract. 2012;18:558-562)     

Glycemic Control and Outcomes of Hospitalization in Noncritically Ill Patients With Type 2 Diabetes Admitted With Cardiac Problems or Infections

ObjectiveAlthough the importance of glycemic control is well established for patients with diabetes hospitalized for surgical problems, it has not been supported by clinical studies for patients with diabetes hospitalized on the medical floors.MethodsWe conducted a retrospective study of 378 patients with type 2 diabetes admitted for cardiac or infectious disease (ID) diagnosis between September 1, 2011, and August 1, 2012. Exclusion criteria included type 1 diabetes, admission to the intensive care unit (ICU), hospital stay shorter than 3 days, and daily glucocorticoid dose > 20 mg of methylprednisolone. The primary composite outcome included death during hospitalization, ICU transfer, initiation of enteral or parenteral nutrition, line infection, deep vein thrombosis, pulmonary embolism, rise in plasma creatinine by 1 or > 2 mg/dL, new infection, an infection lasting for more than 20 days, and readmission within 30 days and between 1 and 10 months after discharge.ResultsPatients were stratified by mean blood glucose (BG) level: group 1 had mean BG of < 180 mg/dL (n = 286; mean BG, 142 ± 23 mg/dL), whereas group 2 had mean BG levels > 181 mg/dL (n = 92; mean BG, 218 ± 34 mg/dL; P < .0001). Group 2 had a 46% higher occurrence of the primary outcome (P < .0004). The rate of unfavorable events was greater in cardiac and ID patients with worse glycemic control (group 2).ConclusionOur data strongly support a positive influence of better glycemic control (average glycemia < 180 mg/dL or 10 mmol/L) on outcomes of hospitaliza-tion in patients with type 2 diabetes. (Endocr Pract. 2014; 20:1303-1308)     

Overcoming Clinical Inertia in the Management of Postoperative Patients with Diabetes

ObjectiveTo assess the impact of an intervention designed to increase basal-bolus insulin therapy administration in postoperative patients with diabetes mellitus.MethodsEducational sessions and direct support for surgical services were provided by a nurse practitioner (NP). Outcome data from the intervention were compared to data from a historical (control) period. Changes in basalbolus insulin use were assessed according to hyperglycemia severity as defined by the percentage of glucose measurements > 180 mg/dL.ResultsPatient characteristics were comparable for the control and intervention periods (all P ≥ .15). Overall, administration of basal-bolus insulin occurred in 9% (8/93) of control and in 32% (94/293) of intervention cases (P < .01). During the control period, administration of basal-bolus insulin did not increase with more frequent hyperglycemia (P = .22). During the intervention period, administration increased from 8% (8/96) in patients with the fewest number of hyperglycemic measurements to 60% (57/95) in those with the highest frequency of hyperglycemia (P < .01). The mean glucose level was lower during the intervention period compared to the control period (149 mg/dL vs. 163 mg/dL, P < .01). The proportion of glucose values > 180 mg/dL was lower during the intervention period than in the control period (21% vs. 31% of measurements, respectively, P < .01), whereas the hypoglycemia (glucose < 70 mg/dL) frequencies were comparable (P = .21).ConclusionAn intervention to overcome clinical inertia in the management of postoperative patients with diabetes led to greater utilization of basal-bolus insulin therapy and improved glucose control without increasing hypoglycemia. These efforts are ongoing to ensure the delivery of effective inpatient diabetes care by all surgical services. (Endocr Pract. 2014;20:320-328)