Improving Timeliness of Insulin Administration by Using an Insulin Dose Calculator.

OBJECTIVES: Insulin is a high-risk medication, and its dosing depends on the individualized clinical and nutritional needs of each patient. Our hospital implemented an insulin dose calculator (IDC) imbedded in the electronic medical record with the goal of decreasing average wait times in inpatient insulin ordering and administration. In this study, we evaluated whether implementation of an IDC decreased the average wait time for insulin administration for hospitalized pediatric patients. METHODS: This pre- and postintervention cohort study measured wait times between point-of-care glucose testing and insulin administration. Patients admitted to the inpatient pediatric services who were treated with subcutaneous insulin during the study period were included. Additionally, nurses completed satisfaction surveys on the insulin administration process at our hospital pre- and post-IDC implementation. Descriptive statistics, χ2, Fisher's exact test, and Student t tests were used to compare groups. Statistical process control charts were used to analyze data trends. RESULTS: The preintervention cohort included 79 insulin doses for admitted pediatric patients. The postimplementation cohort included 128 insulin doses ordered via the IDC. Post-IDC implementation, the average wait time between point-of-care glucose testing and insulin administration decreased from 37 to 25 minutes (P < .05). The statistical process control chart revealed a 5-month run below the established mean after implementation of the IDC. Before IDC implementation, 15.6% of nurses expressed satisfaction in the insulin-dosing process compared with 69.2% postimplementation (P < .05). CONCLUSIONS: Implementation of an IDC reduced the average wait time in ordering and administration of rapid-acting insulin and improved nursing satisfaction with the process.

Implementation of a Diabetes Transition of Care Program.

For adolescents with diabetes, ineffective health care transition to adult health services may result in suboptimal adherence to medical supervision, leading to poor glycemic control, increased diabetes complications, and hospitalization. Despite national recommendations, few youth receive the needed preparation to transition to adult health services. A data transition registry was created at a large Midwest urban academic medical center to identify patients 14 years and older with Type 1 diabetes. Thirty-nine patients with Type 1 diabetes were identified, and 33 were eligible to begin transition planning. Baseline Transition Readiness Assessment Questionnaires (TRAQs) were completed in 21 (64%) of the 33 identified patients, with a mean TRAQ skill score of 66.62 out of 100. There was no correlation between better TRAQ scores and hemoglobin A1c level. Participants had lower baseline TRAQ scores for appointment keeping and tracking health issues. Participants were confident managing daily activities, talking with providers, and managing medications.

Steroid profiling by tandem mass spectrometry improves the positive predictive value of newborn screening for congenital adrenal hyperplasia.

Congenital adrenal hyperplasia (CAH) is primarily caused by 21-hydroxylase deficiency and leads to an accumulation of 17-hydroxyprogesterone and reduced cortisol levels. Newborn screening for CAH is traditionally based on measuring 17-hydroxyprogesterone by different immunoassays. Despite attempts to adjust cutoff levels for birth weight, gestational age, and stress factors, the positive predictive value for CAH screening remains less than 1%. To improve this situation, we developed a method using liquid chromatography-tandem mass spectrometry to measure 17-hydroxyprogesterone, androstenedione, and cortisol simultaneously in blood spots. A total of 1222 leftover blood spots from six different screening programs using different immunoassays (fluorescent immunoassay and ELISA) were reanalyzed in a blinded fashion by liquid chromatography-tandem mass spectrometry. Thirty-one samples were from babies with CAH, 190 had yielded false-positive results by immunoassay, and the remaining 1001 samples were from babies with normal screening results. Steroid profiling allowed for an elimination of 169 (89%) of the false-positive results and for an improvement of the positive predictive value from the reported 0.5 to 4.7%. Although this method is not suitable for mass screening due to the length of the analysis (12 min), it can be used as a second-tier test of blood spots with positive results for CAH by the conventional methods. This would prevent unnecessary blood draws, medical evaluations, and stress to families.

Improved specificity of newborn screening for congenital adrenal hyperplasia by second-tier steroid profiling using tandem mass spectrometry.

BACKGROUND: Newborn screening for congenital adrenal hyperplasia (CAH) involves measurement of 17alpha-hydroxyprogesterone (17-OHP), usually by immunoassay. Because this testing has been characterized by high false-positive rates, we developed a steroid profiling method that uses liquid chromatography-tandem mass spectrometry (LC-MS/MS) to measure 17-OHP, androstenedione, and cortisol simultaneously in blood spots. METHODS: Whole blood was eluted from a 4.8-mm (3/16-inch) dried-blood spot by an aqueous solution containing the deuterium-labeled internal standard d(8)-17-OHP. 17-OHP, androstenedione, and cortisol were extracted into diethyl ether, which was subsequently evaporated and the residue dissolved in LC mobile phase. This extract was injected into a LC-MS/MS equipped with pneumatically assisted electrospray. The steroids were quantified in the selected-reaction monitoring mode by use of peak areas in reference to the stable-isotope-labeled internal standard. We analyzed 857 newborn blood spots, including 14 blood spots of confirmed CAH cases and 101 of false-positive cases by conventional screening. RESULTS: Intra- and interassay CVs for 17-OHP were 7.2-20% and 3.9-18%, respectively, at concentrations of 2, 30, and 50 microg/L. At a cutoff for 17-OHP of 12.5 microg/L and a cutoff of 3.75 for the sum of peak areas for 17-OHP and androstenedione divided by the peak area for cortisol, 86 of the 101 false-positive samples were within reference values by LC-MS/MS, whereas the 742 normal and 14 true-positive results obtained by conventional screening were correctly classified. CONCLUSION: Steroid profiling in blood spots can identify false-positive results obtained by conventional newborn screening for CAH.