Affiliations
Diabetes Center, Washington University in St. Louis Medical School, St. Louis, Missouri
Given name(s)
Eli N.
Family name
Deal
Degrees
PharmD, BCPS

Hyperkalemia Treatment and Hypoglycemia

Article Type
Changed
Mon, 01/02/2017 - 19:34
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Weight‐based insulin dosing for acute hyperkalemia results in less hypoglycemia

Hyperkalemia occurs in as many as 10% of all hospitalized patients,[1] leading to potentially fatal arrhythmias or cardiac arrest that results from ionic imbalance within the resting membrane potential of myocardial tissue.[2] Acute instances may be stabilized with insulin to stimulate intracellular uptake of potassium, but this increases the risk of hypoglycemia.[2] Centers for Medicare and Medicaid Services quality measures require hospitals to minimize hypoglycemic events, particularly serious events with blood glucose (BG) <40 mg/dL,[3] due to an association with an increase in mortality in the hospital setting.[4] Previous research at our tertiary care hospital found that 8.7% of patients had suffered a hypoglycemic event following insulin administration pursuant to acute hyperkalemia treatment, and that patients with a lower body weight are at increased risk of hypoglycemia, particularly severe hypoglycemia (BG <40 mg/dL).[5] Increasing the total dose of dextrose provided around the time of insulin administration is suggested to reduce this concern.[5]

Patients at our institution receive 50 g of dextrose in conjunction with intravenous (IV) insulin for hyperkalemia treatment. To further reduce the potential for hypoglycemia, our institution amended the acute hyperkalemia order set to provide prescribers an alternative dosing strategy to the standard 10 U of IV insulin traditionally used for this purpose. Beginning November 10, 2013, our computer prescriber order entry (CPOE) system automatically prepopulated a dose of 0.1 U/kg of body weight for any patients weighing <95 kg (doses rounded to the nearest whole unit) when the acute hyperkalemia order set was utilized. The maximum dose allowed continued to be 10 U. The revised order set also changed nursing orders to require BG monitoring as frequently as every hour following the administration of insulin and dextrose for the treatment of hyperkalemia.

The purpose of this study is to investigate whether weight‐based insulin dosing (0.1 U/kg) for patients weighing <95 kg, rather than a standard 10‐U insulin dose, resulted in fewer hypoglycemic episodes and patients affected. Secondarily, this study sought to determine the impact of weight‐based insulin dosing on potassium‐lowering effects of therapy and to detect any risk factors for development of hypoglycemia among this patient population.

METHODS

This institutional review boardapproved, single‐center, retrospective chart review examined patients for whom the physician order entry set for hyperkalemia therapy was utilized, including patients who weighed less than 95 kg and received regular insulin via weight‐based dosing (0.1 U/kg of body weight up to a maximum of 10 U) during the period November 10, 2013 to May 31, 2014, versus those who received fixed insulin dosing (10 U regardless of body weight) during the period May 1, 2013 to November 9, 2013. During each of these periods, the CPOE system autopopulated the recommended insulin dose, with the possibility for physician manual dose entry. Data collection was limited to the first use of insulin for hyperkalemia treatment per patient in each period.

Patients weighing <95 kg were the focus of this study because they received <10 U of insulin under the weight‐based dosing strategy. Patients were excluded from the study if they had a body weight >95 kg or no weight recorded, were not administered insulin as ordered, received greater than the CPOE‐specified insulin dose, or had no BG readings recorded within 24 hours of insulin administration. The first 66 patients within each group meeting all inclusion and exclusion criteria were randomly selected for analysis. This recruitment target was developed to provide enough patients for a meaningful analysis of hypoglycemia events based on previous reports from our institution.[5]

Hypoglycemia was defined as a recorded BG level <70 mg/dL within 24 hours after insulin administration; severe hypoglycemia was defined as a recorded BG <40 mg/dL within 24 hours. Individual episodes of hypoglycemia and severe hypoglycemia were recorded for each instance of such event separated by at least 1 hour from the time of the first recorded event. In addition, episodes of hypoglycemia or severe hypoglycemia and number of patients affected were assessed at within 6 hours, 6 to 12 hours, and 12 to 24 hours after insulin administration as separate subsets for statistical analysis.

For the purpose of assessing the potassium‐lowering efficacy of weight‐based versus traditional dosing of insulin, maximum serum potassium levels were examined in the 12‐hour interval before the hyperkalemia order set was implemented and compared with minimum potassium levels in the 12 hours after insulin was administered. A comparison of the treatment groups assessed differences between the mean decrease in serum potassium from baseline, the mean minimum potassium achieved, the number of patients achieving minimum potassium below 5.0 mEq/L, and the number of patients who subsequently received repeat treatment for hyperkalemia within 24 hours of treatment with insulin.

Statistical analysis was conducted utilizing 2 and Fisher exact tests for nominal data and Student t test for continuous data to detect statistically significant differences between the groups. Binomial logistic multivariable analysis using a backward stepwise approach was used to determine factors for development of hypoglycemia, analyzed on a per‐patient basis to prevent characteristics from being over‐represented when events occurred multiple times to a single patient. All analyses were completed by using SPSS version 18 (SPSS Inc., Chicago, IL).

RESULTS

In total, 1734 entries were available for the acute hyperkalemia order set with insulin during the 2 periods investigated. Only 464 patients were eligible for manual chart review once weight‐based exclusions were identified by electronic database, with additional exclusion criteria later extracted from patient charts. Patients in both treatment groups were fairly well balanced, with a slightly lower body weight in the 10‐U insulin group recorded (Table 1). Patients in the weight‐based dosing group received between 4 and 9 U of insulin, depending on body weight.

Baseline Characteristics
Characteristics 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as mean (standard deviation) or number (%).

Weight, kg 69.9 (14.2) 74.2 (12.6) 0.07
Age, y 55.7 (15.7) 61.9 (17.6) 0.36
Male gender 37 (56.1%) 41 (62.1%) 0.60
Caucasian race 40 (60.6%) 37 (56.1%) 0.55
Serum creatinine, mg/dL 3.16 (4.38) 3.04 (4.61) 0.9
Creatinine clearance <30 mL/min 41 (62.1%) 41 (62.1%) 0.6
Dialysis 20 (30.3%) 16 (24.2%) 0.56
Baseline blood glucose, mg/dL 166.0 (71.7) 147.3 (48.0) 0.08
Received other insulin within 24 hours of hyperkalemia treatment 30 (45.4%) 25 (37.9%) 0.48
Received K+ supplement within 24 hours of hyperkalemia treatment 9 (13.6%) 11 (16.7%) 0.81
Baseline serum K+, mmol/L 6.1 (0.5) 6.1 (0.7) 0.76
Baseline serum K+ >6.0 mmol/L 41 (62.1%) 33 (50%) 0.22
No. of additional treatments for hyperkalemia in addition to insulin/dextrose 1.5 (0.8) 1.4 (0.9) 0.49

A reduction in the number of hypoglycemic episodes was detected in the weight‐based dosing group of 56% within 24 hours, from 18 to 8 events (P = 0.05) (Table 2). The number of hypoglycemic events in every subset of time intervals was likewise reduced by at least 50% using weight‐based dosing (from 7 to 3 events within 6 hours, from 5 to 2 events in 612 hours, from 6 to 3 events in 1224 hours). The number of patients who experienced hypoglycemia within 24 hours after receiving insulin also was reduced in the weight‐based dosing group by 46% (P = 0.22).

Hypoglycemia Outcomes and Impact on Potassium Values
Outcomes 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as number (%) unless indicated otherwise. Abbreviations: SD, standard deviation.

Hypoglycemia, <70 mg/dL
No. of patients 13 (19.7%) 7 (10.6%) 0.22
No. of events total 18 (27.3%) 8 (12.1%) 0.05
No. of events 06 hours 7 (10.6%) 3 (4.5%) 0.32
No. of events 612 hours 5 (7.6%) 2 (3.0%) 0.44
No. of events 1224 hours 6 (9.1%) 3 (4.5%) 0.49
Severe hypoglycemia
No. of patients 2 (3.0%) 1 (1.5%) >0.99
No. of events total 2 (3%) 1 (1.5%) >0.99
Potassium‐lowering effects
Minimum K+ after therapy, mmol/L (SD) 4.9 (0.7) 4.8 (0.7) 0.84
Minimum serum K+ < 5.0 mmol/L (%) 37 (56.1%) 35 (53.0%) 0.32
Average K+ decrease, mmol/L (SD) 1.35 (0.97) 1.34 (0.94) 0.94
Repeat treatment given (%) 24 (36.4%) 24 (36.4%) >0.99

Potassium lowering was comparable across both dosing strategies in every measure assessed (Table 2). Multivariate analysis revealed that baseline BG <140 mg/dL (adjusted odds ratio: 4.3, 95% confidence interval [CI]: 1.4‐13.7, P = 0.01) and female gender (adjusted odds ratio: 3.2, 95% CI: 1.1‐9.1, P = 0.03) were associated with an increased risk of hypoglycemia. Other factors, including administration of insulin beyond that for hyperkalemia treatment and use of additional hypoglycemic agents, were not associated with the development of hypoglycemia, which is consistent with previous reports.[6]

CONCLUSIONS

Our findings indicate that using a weight‐based approach to insulin dosing when treating hyperkalemia may lead to a reduction in hypoglycemia without sacrificing the efficacy of potassium lowering. Females and patients with glucose values <140 mg/dL were at increased risk of hypoglycemia in this cohort. Based on the results of this research, a weight‐based dosing strategy of 0.1 U/kg IV insulin up to a maximum of 10 U should be considered, with further research desirable to validate these results.

This study was strengthened by the inclusion of all patients regardless of baseline glucose, baseline potassium, administration of other insulins, level of renal impairment, or symptomatic display of hypoglycemia or cardiac dysfunction, thus providing a broad representation of patients treated for acute hyperkalemia. This pilot study was limited in its scope by data collection for only 66 randomized patients per group rather than the entire patient population. In addition, the study utilized patient information from a single site, with few ethnicities represented. Validation of this research using a larger sample size should include greater variation in the patients served. Our inclusion of a hypoglycemia definition up to 24 hours after treatment may also be criticized. However, this is similar to previous reports and allows for a liberal time period for follow‐up glucose monitoring to be recorded.[7]

Because of its small sample size and the low event rate, this study was unable to draw conclusions about the ability of weight‐based insulin dosing to affect severe hypoglycemic events (<40 mg/dL). A study of more than 400 patients would be necessary to find statistically significant differences in the risk of severe hypoglycemia. Furthermore, because we did not examine the results from all patients in this cohort, we cannot conclusively determine the impact of treatment. The retrospective nature of this study limited our ability to capture hypoglycemic episodes during periods in which BG levels were not recorded. Additionally, changes to the post‐treatment glucose monitoring protocol may have also affected the incidence of hypoglycemia in 2 potential ways. First, early and unrecorded interventions may have occurred in patients with a trend toward hypoglycemia. Second, the longer time to follow‐up in the nonweight‐based group may have led to additional hypoglycemic episodes being missed. A prospective trial design could provide more comprehensive information about patient response to weight‐based versus traditional dosing of IV insulin for hyperkalemia. Further investigations on reducing adverse effects of insulin when treating hyperkalemia should focus on female patients and those with lower baseline BG values. Additionally, as newer agents to treat hyperkalemia are developed and tested, the approach to management should be revisited.[8, 9, 10]

Disclosures: Garry S. Tobin, MD, lectures or is on the speakers bureau for Eli Lilly, Jansen, Boehringher Ingelheim, and Novo Nordisk, and performs data safety monitoring for Novo Nordisk. The authors report no other potential conflicts of interest.

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References
  1. Acker CG, Johnson JP, Palvelsky P, Greenberg A. Hyperkalemia in hospitalized patients: causes, adequacy of treatment, and results of an attempt to improve physician compliance with published therapy guidelines. Arch Intern Med. 1998;158:917924.
  2. 2010 American Heart Association guidelines for cardiopulmonary resuscitation and emergency cardiovascular care. Part 12.6: cardiac arrest associated with life‐threatening electrolyte disturbances. Circulation. 2010;122:S829S861.
  3. Centers for Medicare 29(2):101107.
  4. Schafers S, Naunheim R, Vijayan A, Tobin G. Incidence of hypoglycemia following insulin‐based acute stabilization of hyperkalemia treatment. J Hosp Med. 2012;7(3):239242.
  5. Apel J, Reutrakul S, Baldwin D. Hypoglycemia in the treatment of hyperkalemia with insulin in patients with end‐stage renal disease. Clin Kidney J. 2014;7(3):248250.
  6. Elliott MB, Schafers S, McGill J, Tobin G. Prediction and prevention of treatment‐related inpatient hypoglycemia. J Diabetes Sci Technol. 2012;6(2):302309.
  7. Kosiborod M, Rasmussen HS, Lavin P, et al. Effect of sodium zirconium cyclosilicate on potassium lowering for 28 days among outpatients with hyperkalemia: the HARMONIZE randomized clinical trial. JAMA. 2014;312(21):22232233.
  8. Packham DK, Rasmussen HS, Lavin PT, et al. Zirconium cyclosilicate in hyperkalemia. N Engl J Med. 2015;372:222231.
  9. Weir MR, Bakris GL, Bushinsky DA, et al. Patiromer in patients with kidney disease and hyperkalemia receiving RAAS inhibitors. N Engl J Med. 2015;372:211221.
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Hyperkalemia occurs in as many as 10% of all hospitalized patients,[1] leading to potentially fatal arrhythmias or cardiac arrest that results from ionic imbalance within the resting membrane potential of myocardial tissue.[2] Acute instances may be stabilized with insulin to stimulate intracellular uptake of potassium, but this increases the risk of hypoglycemia.[2] Centers for Medicare and Medicaid Services quality measures require hospitals to minimize hypoglycemic events, particularly serious events with blood glucose (BG) <40 mg/dL,[3] due to an association with an increase in mortality in the hospital setting.[4] Previous research at our tertiary care hospital found that 8.7% of patients had suffered a hypoglycemic event following insulin administration pursuant to acute hyperkalemia treatment, and that patients with a lower body weight are at increased risk of hypoglycemia, particularly severe hypoglycemia (BG <40 mg/dL).[5] Increasing the total dose of dextrose provided around the time of insulin administration is suggested to reduce this concern.[5]

Patients at our institution receive 50 g of dextrose in conjunction with intravenous (IV) insulin for hyperkalemia treatment. To further reduce the potential for hypoglycemia, our institution amended the acute hyperkalemia order set to provide prescribers an alternative dosing strategy to the standard 10 U of IV insulin traditionally used for this purpose. Beginning November 10, 2013, our computer prescriber order entry (CPOE) system automatically prepopulated a dose of 0.1 U/kg of body weight for any patients weighing <95 kg (doses rounded to the nearest whole unit) when the acute hyperkalemia order set was utilized. The maximum dose allowed continued to be 10 U. The revised order set also changed nursing orders to require BG monitoring as frequently as every hour following the administration of insulin and dextrose for the treatment of hyperkalemia.

The purpose of this study is to investigate whether weight‐based insulin dosing (0.1 U/kg) for patients weighing <95 kg, rather than a standard 10‐U insulin dose, resulted in fewer hypoglycemic episodes and patients affected. Secondarily, this study sought to determine the impact of weight‐based insulin dosing on potassium‐lowering effects of therapy and to detect any risk factors for development of hypoglycemia among this patient population.

METHODS

This institutional review boardapproved, single‐center, retrospective chart review examined patients for whom the physician order entry set for hyperkalemia therapy was utilized, including patients who weighed less than 95 kg and received regular insulin via weight‐based dosing (0.1 U/kg of body weight up to a maximum of 10 U) during the period November 10, 2013 to May 31, 2014, versus those who received fixed insulin dosing (10 U regardless of body weight) during the period May 1, 2013 to November 9, 2013. During each of these periods, the CPOE system autopopulated the recommended insulin dose, with the possibility for physician manual dose entry. Data collection was limited to the first use of insulin for hyperkalemia treatment per patient in each period.

Patients weighing <95 kg were the focus of this study because they received <10 U of insulin under the weight‐based dosing strategy. Patients were excluded from the study if they had a body weight >95 kg or no weight recorded, were not administered insulin as ordered, received greater than the CPOE‐specified insulin dose, or had no BG readings recorded within 24 hours of insulin administration. The first 66 patients within each group meeting all inclusion and exclusion criteria were randomly selected for analysis. This recruitment target was developed to provide enough patients for a meaningful analysis of hypoglycemia events based on previous reports from our institution.[5]

Hypoglycemia was defined as a recorded BG level <70 mg/dL within 24 hours after insulin administration; severe hypoglycemia was defined as a recorded BG <40 mg/dL within 24 hours. Individual episodes of hypoglycemia and severe hypoglycemia were recorded for each instance of such event separated by at least 1 hour from the time of the first recorded event. In addition, episodes of hypoglycemia or severe hypoglycemia and number of patients affected were assessed at within 6 hours, 6 to 12 hours, and 12 to 24 hours after insulin administration as separate subsets for statistical analysis.

For the purpose of assessing the potassium‐lowering efficacy of weight‐based versus traditional dosing of insulin, maximum serum potassium levels were examined in the 12‐hour interval before the hyperkalemia order set was implemented and compared with minimum potassium levels in the 12 hours after insulin was administered. A comparison of the treatment groups assessed differences between the mean decrease in serum potassium from baseline, the mean minimum potassium achieved, the number of patients achieving minimum potassium below 5.0 mEq/L, and the number of patients who subsequently received repeat treatment for hyperkalemia within 24 hours of treatment with insulin.

Statistical analysis was conducted utilizing 2 and Fisher exact tests for nominal data and Student t test for continuous data to detect statistically significant differences between the groups. Binomial logistic multivariable analysis using a backward stepwise approach was used to determine factors for development of hypoglycemia, analyzed on a per‐patient basis to prevent characteristics from being over‐represented when events occurred multiple times to a single patient. All analyses were completed by using SPSS version 18 (SPSS Inc., Chicago, IL).

RESULTS

In total, 1734 entries were available for the acute hyperkalemia order set with insulin during the 2 periods investigated. Only 464 patients were eligible for manual chart review once weight‐based exclusions were identified by electronic database, with additional exclusion criteria later extracted from patient charts. Patients in both treatment groups were fairly well balanced, with a slightly lower body weight in the 10‐U insulin group recorded (Table 1). Patients in the weight‐based dosing group received between 4 and 9 U of insulin, depending on body weight.

Baseline Characteristics
Characteristics 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as mean (standard deviation) or number (%).

Weight, kg 69.9 (14.2) 74.2 (12.6) 0.07
Age, y 55.7 (15.7) 61.9 (17.6) 0.36
Male gender 37 (56.1%) 41 (62.1%) 0.60
Caucasian race 40 (60.6%) 37 (56.1%) 0.55
Serum creatinine, mg/dL 3.16 (4.38) 3.04 (4.61) 0.9
Creatinine clearance <30 mL/min 41 (62.1%) 41 (62.1%) 0.6
Dialysis 20 (30.3%) 16 (24.2%) 0.56
Baseline blood glucose, mg/dL 166.0 (71.7) 147.3 (48.0) 0.08
Received other insulin within 24 hours of hyperkalemia treatment 30 (45.4%) 25 (37.9%) 0.48
Received K+ supplement within 24 hours of hyperkalemia treatment 9 (13.6%) 11 (16.7%) 0.81
Baseline serum K+, mmol/L 6.1 (0.5) 6.1 (0.7) 0.76
Baseline serum K+ >6.0 mmol/L 41 (62.1%) 33 (50%) 0.22
No. of additional treatments for hyperkalemia in addition to insulin/dextrose 1.5 (0.8) 1.4 (0.9) 0.49

A reduction in the number of hypoglycemic episodes was detected in the weight‐based dosing group of 56% within 24 hours, from 18 to 8 events (P = 0.05) (Table 2). The number of hypoglycemic events in every subset of time intervals was likewise reduced by at least 50% using weight‐based dosing (from 7 to 3 events within 6 hours, from 5 to 2 events in 612 hours, from 6 to 3 events in 1224 hours). The number of patients who experienced hypoglycemia within 24 hours after receiving insulin also was reduced in the weight‐based dosing group by 46% (P = 0.22).

Hypoglycemia Outcomes and Impact on Potassium Values
Outcomes 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as number (%) unless indicated otherwise. Abbreviations: SD, standard deviation.

Hypoglycemia, <70 mg/dL
No. of patients 13 (19.7%) 7 (10.6%) 0.22
No. of events total 18 (27.3%) 8 (12.1%) 0.05
No. of events 06 hours 7 (10.6%) 3 (4.5%) 0.32
No. of events 612 hours 5 (7.6%) 2 (3.0%) 0.44
No. of events 1224 hours 6 (9.1%) 3 (4.5%) 0.49
Severe hypoglycemia
No. of patients 2 (3.0%) 1 (1.5%) >0.99
No. of events total 2 (3%) 1 (1.5%) >0.99
Potassium‐lowering effects
Minimum K+ after therapy, mmol/L (SD) 4.9 (0.7) 4.8 (0.7) 0.84
Minimum serum K+ < 5.0 mmol/L (%) 37 (56.1%) 35 (53.0%) 0.32
Average K+ decrease, mmol/L (SD) 1.35 (0.97) 1.34 (0.94) 0.94
Repeat treatment given (%) 24 (36.4%) 24 (36.4%) >0.99

Potassium lowering was comparable across both dosing strategies in every measure assessed (Table 2). Multivariate analysis revealed that baseline BG <140 mg/dL (adjusted odds ratio: 4.3, 95% confidence interval [CI]: 1.4‐13.7, P = 0.01) and female gender (adjusted odds ratio: 3.2, 95% CI: 1.1‐9.1, P = 0.03) were associated with an increased risk of hypoglycemia. Other factors, including administration of insulin beyond that for hyperkalemia treatment and use of additional hypoglycemic agents, were not associated with the development of hypoglycemia, which is consistent with previous reports.[6]

CONCLUSIONS

Our findings indicate that using a weight‐based approach to insulin dosing when treating hyperkalemia may lead to a reduction in hypoglycemia without sacrificing the efficacy of potassium lowering. Females and patients with glucose values <140 mg/dL were at increased risk of hypoglycemia in this cohort. Based on the results of this research, a weight‐based dosing strategy of 0.1 U/kg IV insulin up to a maximum of 10 U should be considered, with further research desirable to validate these results.

This study was strengthened by the inclusion of all patients regardless of baseline glucose, baseline potassium, administration of other insulins, level of renal impairment, or symptomatic display of hypoglycemia or cardiac dysfunction, thus providing a broad representation of patients treated for acute hyperkalemia. This pilot study was limited in its scope by data collection for only 66 randomized patients per group rather than the entire patient population. In addition, the study utilized patient information from a single site, with few ethnicities represented. Validation of this research using a larger sample size should include greater variation in the patients served. Our inclusion of a hypoglycemia definition up to 24 hours after treatment may also be criticized. However, this is similar to previous reports and allows for a liberal time period for follow‐up glucose monitoring to be recorded.[7]

Because of its small sample size and the low event rate, this study was unable to draw conclusions about the ability of weight‐based insulin dosing to affect severe hypoglycemic events (<40 mg/dL). A study of more than 400 patients would be necessary to find statistically significant differences in the risk of severe hypoglycemia. Furthermore, because we did not examine the results from all patients in this cohort, we cannot conclusively determine the impact of treatment. The retrospective nature of this study limited our ability to capture hypoglycemic episodes during periods in which BG levels were not recorded. Additionally, changes to the post‐treatment glucose monitoring protocol may have also affected the incidence of hypoglycemia in 2 potential ways. First, early and unrecorded interventions may have occurred in patients with a trend toward hypoglycemia. Second, the longer time to follow‐up in the nonweight‐based group may have led to additional hypoglycemic episodes being missed. A prospective trial design could provide more comprehensive information about patient response to weight‐based versus traditional dosing of IV insulin for hyperkalemia. Further investigations on reducing adverse effects of insulin when treating hyperkalemia should focus on female patients and those with lower baseline BG values. Additionally, as newer agents to treat hyperkalemia are developed and tested, the approach to management should be revisited.[8, 9, 10]

Disclosures: Garry S. Tobin, MD, lectures or is on the speakers bureau for Eli Lilly, Jansen, Boehringher Ingelheim, and Novo Nordisk, and performs data safety monitoring for Novo Nordisk. The authors report no other potential conflicts of interest.

Hyperkalemia occurs in as many as 10% of all hospitalized patients,[1] leading to potentially fatal arrhythmias or cardiac arrest that results from ionic imbalance within the resting membrane potential of myocardial tissue.[2] Acute instances may be stabilized with insulin to stimulate intracellular uptake of potassium, but this increases the risk of hypoglycemia.[2] Centers for Medicare and Medicaid Services quality measures require hospitals to minimize hypoglycemic events, particularly serious events with blood glucose (BG) <40 mg/dL,[3] due to an association with an increase in mortality in the hospital setting.[4] Previous research at our tertiary care hospital found that 8.7% of patients had suffered a hypoglycemic event following insulin administration pursuant to acute hyperkalemia treatment, and that patients with a lower body weight are at increased risk of hypoglycemia, particularly severe hypoglycemia (BG <40 mg/dL).[5] Increasing the total dose of dextrose provided around the time of insulin administration is suggested to reduce this concern.[5]

Patients at our institution receive 50 g of dextrose in conjunction with intravenous (IV) insulin for hyperkalemia treatment. To further reduce the potential for hypoglycemia, our institution amended the acute hyperkalemia order set to provide prescribers an alternative dosing strategy to the standard 10 U of IV insulin traditionally used for this purpose. Beginning November 10, 2013, our computer prescriber order entry (CPOE) system automatically prepopulated a dose of 0.1 U/kg of body weight for any patients weighing <95 kg (doses rounded to the nearest whole unit) when the acute hyperkalemia order set was utilized. The maximum dose allowed continued to be 10 U. The revised order set also changed nursing orders to require BG monitoring as frequently as every hour following the administration of insulin and dextrose for the treatment of hyperkalemia.

The purpose of this study is to investigate whether weight‐based insulin dosing (0.1 U/kg) for patients weighing <95 kg, rather than a standard 10‐U insulin dose, resulted in fewer hypoglycemic episodes and patients affected. Secondarily, this study sought to determine the impact of weight‐based insulin dosing on potassium‐lowering effects of therapy and to detect any risk factors for development of hypoglycemia among this patient population.

METHODS

This institutional review boardapproved, single‐center, retrospective chart review examined patients for whom the physician order entry set for hyperkalemia therapy was utilized, including patients who weighed less than 95 kg and received regular insulin via weight‐based dosing (0.1 U/kg of body weight up to a maximum of 10 U) during the period November 10, 2013 to May 31, 2014, versus those who received fixed insulin dosing (10 U regardless of body weight) during the period May 1, 2013 to November 9, 2013. During each of these periods, the CPOE system autopopulated the recommended insulin dose, with the possibility for physician manual dose entry. Data collection was limited to the first use of insulin for hyperkalemia treatment per patient in each period.

Patients weighing <95 kg were the focus of this study because they received <10 U of insulin under the weight‐based dosing strategy. Patients were excluded from the study if they had a body weight >95 kg or no weight recorded, were not administered insulin as ordered, received greater than the CPOE‐specified insulin dose, or had no BG readings recorded within 24 hours of insulin administration. The first 66 patients within each group meeting all inclusion and exclusion criteria were randomly selected for analysis. This recruitment target was developed to provide enough patients for a meaningful analysis of hypoglycemia events based on previous reports from our institution.[5]

Hypoglycemia was defined as a recorded BG level <70 mg/dL within 24 hours after insulin administration; severe hypoglycemia was defined as a recorded BG <40 mg/dL within 24 hours. Individual episodes of hypoglycemia and severe hypoglycemia were recorded for each instance of such event separated by at least 1 hour from the time of the first recorded event. In addition, episodes of hypoglycemia or severe hypoglycemia and number of patients affected were assessed at within 6 hours, 6 to 12 hours, and 12 to 24 hours after insulin administration as separate subsets for statistical analysis.

For the purpose of assessing the potassium‐lowering efficacy of weight‐based versus traditional dosing of insulin, maximum serum potassium levels were examined in the 12‐hour interval before the hyperkalemia order set was implemented and compared with minimum potassium levels in the 12 hours after insulin was administered. A comparison of the treatment groups assessed differences between the mean decrease in serum potassium from baseline, the mean minimum potassium achieved, the number of patients achieving minimum potassium below 5.0 mEq/L, and the number of patients who subsequently received repeat treatment for hyperkalemia within 24 hours of treatment with insulin.

Statistical analysis was conducted utilizing 2 and Fisher exact tests for nominal data and Student t test for continuous data to detect statistically significant differences between the groups. Binomial logistic multivariable analysis using a backward stepwise approach was used to determine factors for development of hypoglycemia, analyzed on a per‐patient basis to prevent characteristics from being over‐represented when events occurred multiple times to a single patient. All analyses were completed by using SPSS version 18 (SPSS Inc., Chicago, IL).

RESULTS

In total, 1734 entries were available for the acute hyperkalemia order set with insulin during the 2 periods investigated. Only 464 patients were eligible for manual chart review once weight‐based exclusions were identified by electronic database, with additional exclusion criteria later extracted from patient charts. Patients in both treatment groups were fairly well balanced, with a slightly lower body weight in the 10‐U insulin group recorded (Table 1). Patients in the weight‐based dosing group received between 4 and 9 U of insulin, depending on body weight.

Baseline Characteristics
Characteristics 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as mean (standard deviation) or number (%).

Weight, kg 69.9 (14.2) 74.2 (12.6) 0.07
Age, y 55.7 (15.7) 61.9 (17.6) 0.36
Male gender 37 (56.1%) 41 (62.1%) 0.60
Caucasian race 40 (60.6%) 37 (56.1%) 0.55
Serum creatinine, mg/dL 3.16 (4.38) 3.04 (4.61) 0.9
Creatinine clearance <30 mL/min 41 (62.1%) 41 (62.1%) 0.6
Dialysis 20 (30.3%) 16 (24.2%) 0.56
Baseline blood glucose, mg/dL 166.0 (71.7) 147.3 (48.0) 0.08
Received other insulin within 24 hours of hyperkalemia treatment 30 (45.4%) 25 (37.9%) 0.48
Received K+ supplement within 24 hours of hyperkalemia treatment 9 (13.6%) 11 (16.7%) 0.81
Baseline serum K+, mmol/L 6.1 (0.5) 6.1 (0.7) 0.76
Baseline serum K+ >6.0 mmol/L 41 (62.1%) 33 (50%) 0.22
No. of additional treatments for hyperkalemia in addition to insulin/dextrose 1.5 (0.8) 1.4 (0.9) 0.49

A reduction in the number of hypoglycemic episodes was detected in the weight‐based dosing group of 56% within 24 hours, from 18 to 8 events (P = 0.05) (Table 2). The number of hypoglycemic events in every subset of time intervals was likewise reduced by at least 50% using weight‐based dosing (from 7 to 3 events within 6 hours, from 5 to 2 events in 612 hours, from 6 to 3 events in 1224 hours). The number of patients who experienced hypoglycemia within 24 hours after receiving insulin also was reduced in the weight‐based dosing group by 46% (P = 0.22).

Hypoglycemia Outcomes and Impact on Potassium Values
Outcomes 10 U Insulin, n = 66 0.1 U/kg Insulin, n = 66 P Value (2‐Sided)
  • NOTE: Values are expressed as number (%) unless indicated otherwise. Abbreviations: SD, standard deviation.

Hypoglycemia, <70 mg/dL
No. of patients 13 (19.7%) 7 (10.6%) 0.22
No. of events total 18 (27.3%) 8 (12.1%) 0.05
No. of events 06 hours 7 (10.6%) 3 (4.5%) 0.32
No. of events 612 hours 5 (7.6%) 2 (3.0%) 0.44
No. of events 1224 hours 6 (9.1%) 3 (4.5%) 0.49
Severe hypoglycemia
No. of patients 2 (3.0%) 1 (1.5%) >0.99
No. of events total 2 (3%) 1 (1.5%) >0.99
Potassium‐lowering effects
Minimum K+ after therapy, mmol/L (SD) 4.9 (0.7) 4.8 (0.7) 0.84
Minimum serum K+ < 5.0 mmol/L (%) 37 (56.1%) 35 (53.0%) 0.32
Average K+ decrease, mmol/L (SD) 1.35 (0.97) 1.34 (0.94) 0.94
Repeat treatment given (%) 24 (36.4%) 24 (36.4%) >0.99

Potassium lowering was comparable across both dosing strategies in every measure assessed (Table 2). Multivariate analysis revealed that baseline BG <140 mg/dL (adjusted odds ratio: 4.3, 95% confidence interval [CI]: 1.4‐13.7, P = 0.01) and female gender (adjusted odds ratio: 3.2, 95% CI: 1.1‐9.1, P = 0.03) were associated with an increased risk of hypoglycemia. Other factors, including administration of insulin beyond that for hyperkalemia treatment and use of additional hypoglycemic agents, were not associated with the development of hypoglycemia, which is consistent with previous reports.[6]

CONCLUSIONS

Our findings indicate that using a weight‐based approach to insulin dosing when treating hyperkalemia may lead to a reduction in hypoglycemia without sacrificing the efficacy of potassium lowering. Females and patients with glucose values <140 mg/dL were at increased risk of hypoglycemia in this cohort. Based on the results of this research, a weight‐based dosing strategy of 0.1 U/kg IV insulin up to a maximum of 10 U should be considered, with further research desirable to validate these results.

This study was strengthened by the inclusion of all patients regardless of baseline glucose, baseline potassium, administration of other insulins, level of renal impairment, or symptomatic display of hypoglycemia or cardiac dysfunction, thus providing a broad representation of patients treated for acute hyperkalemia. This pilot study was limited in its scope by data collection for only 66 randomized patients per group rather than the entire patient population. In addition, the study utilized patient information from a single site, with few ethnicities represented. Validation of this research using a larger sample size should include greater variation in the patients served. Our inclusion of a hypoglycemia definition up to 24 hours after treatment may also be criticized. However, this is similar to previous reports and allows for a liberal time period for follow‐up glucose monitoring to be recorded.[7]

Because of its small sample size and the low event rate, this study was unable to draw conclusions about the ability of weight‐based insulin dosing to affect severe hypoglycemic events (<40 mg/dL). A study of more than 400 patients would be necessary to find statistically significant differences in the risk of severe hypoglycemia. Furthermore, because we did not examine the results from all patients in this cohort, we cannot conclusively determine the impact of treatment. The retrospective nature of this study limited our ability to capture hypoglycemic episodes during periods in which BG levels were not recorded. Additionally, changes to the post‐treatment glucose monitoring protocol may have also affected the incidence of hypoglycemia in 2 potential ways. First, early and unrecorded interventions may have occurred in patients with a trend toward hypoglycemia. Second, the longer time to follow‐up in the nonweight‐based group may have led to additional hypoglycemic episodes being missed. A prospective trial design could provide more comprehensive information about patient response to weight‐based versus traditional dosing of IV insulin for hyperkalemia. Further investigations on reducing adverse effects of insulin when treating hyperkalemia should focus on female patients and those with lower baseline BG values. Additionally, as newer agents to treat hyperkalemia are developed and tested, the approach to management should be revisited.[8, 9, 10]

Disclosures: Garry S. Tobin, MD, lectures or is on the speakers bureau for Eli Lilly, Jansen, Boehringher Ingelheim, and Novo Nordisk, and performs data safety monitoring for Novo Nordisk. The authors report no other potential conflicts of interest.

References
  1. Acker CG, Johnson JP, Palvelsky P, Greenberg A. Hyperkalemia in hospitalized patients: causes, adequacy of treatment, and results of an attempt to improve physician compliance with published therapy guidelines. Arch Intern Med. 1998;158:917924.
  2. 2010 American Heart Association guidelines for cardiopulmonary resuscitation and emergency cardiovascular care. Part 12.6: cardiac arrest associated with life‐threatening electrolyte disturbances. Circulation. 2010;122:S829S861.
  3. Centers for Medicare 29(2):101107.
  4. Schafers S, Naunheim R, Vijayan A, Tobin G. Incidence of hypoglycemia following insulin‐based acute stabilization of hyperkalemia treatment. J Hosp Med. 2012;7(3):239242.
  5. Apel J, Reutrakul S, Baldwin D. Hypoglycemia in the treatment of hyperkalemia with insulin in patients with end‐stage renal disease. Clin Kidney J. 2014;7(3):248250.
  6. Elliott MB, Schafers S, McGill J, Tobin G. Prediction and prevention of treatment‐related inpatient hypoglycemia. J Diabetes Sci Technol. 2012;6(2):302309.
  7. Kosiborod M, Rasmussen HS, Lavin P, et al. Effect of sodium zirconium cyclosilicate on potassium lowering for 28 days among outpatients with hyperkalemia: the HARMONIZE randomized clinical trial. JAMA. 2014;312(21):22232233.
  8. Packham DK, Rasmussen HS, Lavin PT, et al. Zirconium cyclosilicate in hyperkalemia. N Engl J Med. 2015;372:222231.
  9. Weir MR, Bakris GL, Bushinsky DA, et al. Patiromer in patients with kidney disease and hyperkalemia receiving RAAS inhibitors. N Engl J Med. 2015;372:211221.
References
  1. Acker CG, Johnson JP, Palvelsky P, Greenberg A. Hyperkalemia in hospitalized patients: causes, adequacy of treatment, and results of an attempt to improve physician compliance with published therapy guidelines. Arch Intern Med. 1998;158:917924.
  2. 2010 American Heart Association guidelines for cardiopulmonary resuscitation and emergency cardiovascular care. Part 12.6: cardiac arrest associated with life‐threatening electrolyte disturbances. Circulation. 2010;122:S829S861.
  3. Centers for Medicare 29(2):101107.
  4. Schafers S, Naunheim R, Vijayan A, Tobin G. Incidence of hypoglycemia following insulin‐based acute stabilization of hyperkalemia treatment. J Hosp Med. 2012;7(3):239242.
  5. Apel J, Reutrakul S, Baldwin D. Hypoglycemia in the treatment of hyperkalemia with insulin in patients with end‐stage renal disease. Clin Kidney J. 2014;7(3):248250.
  6. Elliott MB, Schafers S, McGill J, Tobin G. Prediction and prevention of treatment‐related inpatient hypoglycemia. J Diabetes Sci Technol. 2012;6(2):302309.
  7. Kosiborod M, Rasmussen HS, Lavin P, et al. Effect of sodium zirconium cyclosilicate on potassium lowering for 28 days among outpatients with hyperkalemia: the HARMONIZE randomized clinical trial. JAMA. 2014;312(21):22232233.
  8. Packham DK, Rasmussen HS, Lavin PT, et al. Zirconium cyclosilicate in hyperkalemia. N Engl J Med. 2015;372:222231.
  9. Weir MR, Bakris GL, Bushinsky DA, et al. Patiromer in patients with kidney disease and hyperkalemia receiving RAAS inhibitors. N Engl J Med. 2015;372:211221.
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Address for correspondence and reprint requests: Eli N. Deal, PharmD, Department of Pharmacy, Barnes‐Jewish Hospital, 216 S. Kingshighway Blvd., Mailstop: 90‐52‐411, St. Louis, MO 63110; Telephone: 314‐362‐5407; Fax: 314‐362‐5407; E‐mail: [email protected]
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Insulin Administration Errors

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Inpatient insulin orders: Are patients getting what is prescribed?

Diabetes care in the inpatient setting requires coordination between multiple service providers. Breakdowns in this process occur at all levels leading to potential serious harm.1 Error rates focusing on multiple areas related to diabetes care, including the inpatient provision of insulin, have been described as high as 19.5% in 14,000 patients surveyed in the United Kingdom.2 Missteps are important, as insulin prescribing errors are more commonly associated with patient harm.3 In the United States, medication errors related to provision of care to critically ill patients has been documented, but, to our knowledge, no such reports regarding general medical or surgical wards exist.4

Insulin errors can result from a wide range of possible reasons including: incorrect medication reconciliation, prescribing errors, dispensing errors, administration errors, suboptimal meal timing, or errors in communication for discharge plans regarding diabetes care. Examining each of these areas as a whole could be a daunting task. As such, we sought to examine 1 portion of insulin provision as an initial focus for performance improvement at our institution. Our purpose was to describe the rates of errors associated with insulin administration at our single academic medical center on general medicine and surgical wards.

Methods

Study patients for this observational, prospective snapshot were identified by electronic medical records in 4 consecutive weeks in April 2009 at Barnes‐Jewish Hospital (St Louis, MO), a 1200 bed academic medical center. This study was approved by the Washington University in St Louis School of Medicine Human Studies Committee, and the requirement for informed consent was waived.

On day 1 of each snapshot period, all patients on the identified wards were examined to determine if insulin was currently active as part of the inpatient medication orders. If active, this patient was enrolled into the evaluation data set. No patients were excluded if insulin was currently ordered. Four inpatient areas were selected to provide a representation of the non‐critically ill patient population at our institution. The 4 areas selected were: a cardiac care ward (typical census = 24), a general medicine ward (typical census = 24), an abdominal transplant ward (typical census = 18), and a general surgery ward (typical census = 22). Taken together, these areas represent about 20% of the total non‐critically ill patient population at our hospital. The transplant area was chosen because it represents a high‐risk population with medication (corticosteroid)‐induced diabetes. Nursing and physician care are typically exclusive in these areas, and very little crossover among these healthcare providers would have occurred among the units surveyed during the study period.

Each patient included on day 1 of each audit period was followed for a total of up to 7 days. Patients were only enrolled on day 1 of each audit period. Four survey periods were conducted, providing an evaluation of 28 days of insulin therapy in the studied units. Four periods were selected to pick up more patients on day 1 of each audit period. Electronic records of medication administration and evaluation of paper chart orders provided the information for insulin administration error rates. Additionally, physician notes regarding patients' histories and home insulin use were reviewed for background information for our patient population. Prospective daily assessments of insulin orders, doses charted, nursing notes, and blood glucose values were conducted for potential errors in insulin administration.

All definitions of insulin administration errors were defined prior to data collection. The investigators reviewed available literature involving insulin errors, and found no standardized definitions or previously published assessments at the time of inception of our study. As such, we examined our own clinical practice for areas of potential concern related to insulin administration. The following error categories were identified: transcription errors (eg, insulin glargine 10 units qpm written, but order transcribed and carried out as 20 units qpm); greater than 1 hour between obtained point‐of‐care blood glucose value and provision of correctional (sliding‐scale) insulin; insulin held without a physician order present in the medical records; missing documentation of insulin doses (glucose value of 150 mg/dL present, but no documented correctional dose corresponding to this value present in medical record); premeal and correctional insulin given at separate times; and no documentation of physician notification for hypoglycemia. Other reasons for potential insulin administration errors were collected if deemed pertinent by the individual auditors.

At the time of our survey, a standardized subcutaneous insulin administration order set was utilized in all of the surveyed units. As computerized physician order entry was not yet available at our institution, all orders were transcribed electronically from paper orders. This insulin order set has been in place for 5 years. Once initiated, all portions of the order set are initiated, including communication to nurses regarding glucose measuring times, requirement for documentation of hypoglycemia, and proposed glucose goals. A survey of insulin orders during the audit time revealed that >97% of all insulin orders were initiated from this standardized order set. These order sets encouraged the provision of physiological insulin (basal‐bolus) using insulin glargine and insulin aspart in eligible individuals. Although no systematic, standardized goal for glucose attainment was promoted, a fasting blood glucose of 90‐130 mg/dL and post‐prandial value of <180 mg/dL was encouraged. The order sets had a stated requirement of physician contact for all blood glucose values <70 mg/dL. Although lack of documentation of hypoglycemia may not be directly considered an error associated with administration of insulin, the research group decided to include this provision in the definition of administration errors, given the ability of this parameter to provide a sense of overall completeness of insulin orders and as a marker of collaborative practice in the management of inpatient hyperglycemia.

Nurses documented glucose values and responses in electronic medical administration records as a matter of routine. Point‐of‐care glucose values were obtained by either patient care technicians or nurses on each individual ward. As an academic medical institution, physicians were frequently paged by other members of the healthcare team.

Each auditor (E.N.D., A.L., L.L.W., K.A.H.) reviewed 1 consistent unit during the audit period. All data for insulin administration errors were tabulated, and descriptive rates of errors were used on a per‐patient or per‐stay basis

Results

A total of 116 patient‐audit periods were identified during the 28‐day study period (Table 1). Sixty‐five patients were on surgical services, and 51 were on medicine services, representing 378 inpatient days. Median length of stay was 3.5 days. Home insulin use was evident in 49% of the surveyed population. Patients' mean A1C (data available within 3 months prior to admission) was 8.1% (n = 41). Inpatient insulin regimens on day 1 included correctional insulin only (51.7% of cases). Regimens containing neutral protamine Hagedorn (NPH) or glargine also included correctional insulin in 95% of cases, and premeal insulin in 35%. Regimens including both premeal insulin and correctional insulin occurred in 25% of the patients. Diet status indicated that 83% of the population was taking an oral diet on day 1, and 13% were nil per os (nothing by mouth [NPO]).

Baseline Demographics
Characteristic Result
  • Abbreviations: A1C, glycated hemoglobin; DM1, diabetes mellitus type 1; DM2, diabetes mellitus type 2; NPH, neutral protamine Hagedorn; NPO, nil per os (nothing by mouth); TPN, total parenteral nutrition.

Mean age, years 59
Mean body mass index 30.9
Male 58%
Reason for admission
Diabetes‐related 7 (6%)
Cardiovascular 23 (19.8%)
Infection/sepsis 12 (10.3%)
Transplant 10 (8.6%)
Vascular surgery 10 (8.6%)
Transplant complication 8 (6.9%)
Other 46 (39.6%)
History of diabetes
DM1 7 (6%)
DM2 77 (67%)
Steroid‐induced 8 (7%)
No history of diabetes 24 (20%)
Most recent A1C (n = 41) (mean) 8.1%
Home insulin use 57 (49%)
Hospital NPH, day 1 14 (12.0%)
Hospital glargine, day 1 33 (28.4%)
Hospital correctional insulin only, day 1 60 (51.7%)
Day 1 diet
Prudent diabetic 58 (50%)
NPO 15 (13%)
Other 38 (32.7%)
Tube feeds 3 (2.6%)
TPN 2 (1.7%)

A total of 199 administration errors occurred at a rate of 1.72 errors/patient‐period and 0.53 errors/patient day (Table 2). Missing documentation of doses (15.5% of all patients) and insulin being held without an order (25% of patients) were the most frequently occurring events. Errors classified as other were found in 13.1% of the defined events. These other errors consisted of not carrying out correctional dose insulin orders appropriately (eg, blood sugar value of 149 mg/dL should have resulted in a correctional dose of 2 units, but 3 units were documented as given instead), timing errors related to provision of mealtime insulin apart from documented provision of a meal, or not following the required documentation for insulin pumps.

Insulin Administration Error Results
Category No. of events (% Out of 199 Total Errors)
Transcription error 15 (7.5)
Greater than 1 hr between blood sugar evaluation and insulin administration 20 (10.1)
Insulin held without a physician order 36 (18.1)
Missing documentation of insulin doses 58 (29.1)
Premeal and correctional insulin given at separate time 19 (9.5)
No documentation of physician notification of hypoglycemia 25 (12.6)
Other 26 (13.1)

Forty‐two patients (36%) experienced no errors in insulin administration, 18 patients experienced 1 error, 21 patients had 2 errors, and 11 patients had 3 errors. The remainder of the patients (n = 23; 19.9%) had 4 or more errors during their observation period. Were similar across the units surveyed. Frequency of errors remained consistent regardless of reason for admission, history of diabetes or insulin use at home, or length of stay. Most errors occurred on days 1 and 2 of the hospital stay. Error rates and types were consistent across all units surveyed.

Discussion/Conclusion

We found that insulin administration errors were common in our inpatient snapshot of non‐critically ill patients. In our observational evaluation, 64% of patients had at least 1 error related to insulin administration. Errors related to missing documentation of scheduled doses, or doses held without a prescriber order, were the most common. Implications of missed or held doses could range from unclear approaches for dose adjustment due to missing information, incorrect titration due to incomplete information, or hypoglycemia and hyperglycemia.

This observed rate of error is much higher than the described error rate of 19.5% reported in the United Kingdom.2 This difference in error rates most likely reflects a difference in focus, as investigators in that national effort focused on prescriber error, aberrations in blood glucose values, and readmission rates. Our evaluation in assessing error rates regarding insulin administration supports the use of personnel keenly aware of the processes related to insulin administration, and provides insight into the importance of evaluating small portions of insulin provision (administration vs prescribing, etc) in assessing grounds for improvement in care. It is important to note that our findings may be exaggerated and are not entirely comparable to a study with a different scope and size.

Our snapshot tool and baseline evaluation is a simple method that could be undertaken at many institutions. As such, this methodology and error estimate serves as a gauge for future comparisons and areas for intervention. Limitations of our assessment include the small portion of patients audited during our evaluation versus using a snapshot of our entire hospital, utilizing nonstandardized criteria for determination of insulin errors, and the lack of correlation of clinical significance (aberrations in glucose values) with errors observed. Also, this single‐institution review may not be generalizable to all institutions. Additionally, we only examined errors related to administration of insulin. Other areas that would complete the picture, related to diabetic therapies and outcomes, would need to include prescribing errors or dispensing errors and relate these to glycemic outcomes. Assessment of these additional errors may have revealed more clinically important events that were not revealed in this small snapshot. Lastly, clinical endpoints such as intensive care unit (ICU) transfers, mortality, or readmissions were not assessed in this small study.

We are fortunate that many of these errors were apparently clinically silent, but in a subset of patients, the risk is real and life‐threatening. Risk occurs at both ends of the glucose spectrum, with the low end receiving the greatest attention. Severe hypoglycemia with harm and inpatient diabetic ketoacidosis have been qualified as newer events by Medicare. Hypoglycemia in the ICU population (<40 mg/dL) is an independent marker of mortality.5 Hypoglycemia (<50 mg/dL) has been associated with heart attacks, strokes, and death in the outpatient setting.6

The ability to safely control blood sugar in the hospital requires that medications are administered on time, and that communication occurs between the prescribing provider and the nursing staff providing care. Along with the case‐by‐case implications regarding the need for accurate administration of insulin for subsequent titration and determination of discharge prescriptions for patients with diabetes, there are many implications regarding the assessment of inpatient provision of insulin on determining institutional practices based on previous performance. If insulin administration is not accurately provided or documented, institutions will find it difficult to correctly make changes to insulin protocols for targeting future improvements. Our evaluation indicates an obvious need for quality improvement with 18.1% of the errors reflecting holding insulin without an order, and 12.6% of the errors showing no documentation for the physician being notified of hypoglycemia requiring treatment. The need to foster structured nurse‐physician communication will play a critical role in any process improvement. Communication is key for the optimal provision of insulin in the inpatient setting. Computerized order entry and bar‐code guided administration of doses of insulin may fix some types of the errors (transcription and missed documentation, respectively). That said, one of the largest impacts of this survey may reveal that these errors may not be fixed by technology, but may require more targeted and difficult interventions, such as continuing education and holding clinicians accountable. This study provides insight into the complicated issues regarding inpatient insulin administration and, due to its systematic approach, has given direction for process and system improvements.

Files
References
  1. Hellman R.Patient safety and inpatient glycemic control: translating concepts into action.Endocr Pract.2006;12:4955.
  2. Lamont T,Cousins D,Hillson R,Bischler A,Terblanche M.Safer administration of insulin: summary of a safety report from the National Patient Safety Agency.BMJ.341:883.
  3. Calabrese AD,Erstad BL,Brandl K,Barletta JF,Kane SL,Sherman DS.Medication administration errors in adult patients in the ICU.Intensive Care Med.2001;27(10):15921598.
  4. United States Pharmacopeia. MEDMARX 5th anniversary data report. A chartbook of 2003 findings and trends 1999–2003. Available at: http://www.usp.org/products/medMarx/index.html?USP_Print. Accessed December 1,2010.
  5. Van den Berghe G,Wilmer A,Hermans G, et al.Intensive insulin therapy in the medical ICU.N Engl J Med.2006;354:449461.
  6. The ADVANCE Trial Collaborative Group.Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes.N Engl J Med.2008;358:25602572.
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Diabetes care in the inpatient setting requires coordination between multiple service providers. Breakdowns in this process occur at all levels leading to potential serious harm.1 Error rates focusing on multiple areas related to diabetes care, including the inpatient provision of insulin, have been described as high as 19.5% in 14,000 patients surveyed in the United Kingdom.2 Missteps are important, as insulin prescribing errors are more commonly associated with patient harm.3 In the United States, medication errors related to provision of care to critically ill patients has been documented, but, to our knowledge, no such reports regarding general medical or surgical wards exist.4

Insulin errors can result from a wide range of possible reasons including: incorrect medication reconciliation, prescribing errors, dispensing errors, administration errors, suboptimal meal timing, or errors in communication for discharge plans regarding diabetes care. Examining each of these areas as a whole could be a daunting task. As such, we sought to examine 1 portion of insulin provision as an initial focus for performance improvement at our institution. Our purpose was to describe the rates of errors associated with insulin administration at our single academic medical center on general medicine and surgical wards.

Methods

Study patients for this observational, prospective snapshot were identified by electronic medical records in 4 consecutive weeks in April 2009 at Barnes‐Jewish Hospital (St Louis, MO), a 1200 bed academic medical center. This study was approved by the Washington University in St Louis School of Medicine Human Studies Committee, and the requirement for informed consent was waived.

On day 1 of each snapshot period, all patients on the identified wards were examined to determine if insulin was currently active as part of the inpatient medication orders. If active, this patient was enrolled into the evaluation data set. No patients were excluded if insulin was currently ordered. Four inpatient areas were selected to provide a representation of the non‐critically ill patient population at our institution. The 4 areas selected were: a cardiac care ward (typical census = 24), a general medicine ward (typical census = 24), an abdominal transplant ward (typical census = 18), and a general surgery ward (typical census = 22). Taken together, these areas represent about 20% of the total non‐critically ill patient population at our hospital. The transplant area was chosen because it represents a high‐risk population with medication (corticosteroid)‐induced diabetes. Nursing and physician care are typically exclusive in these areas, and very little crossover among these healthcare providers would have occurred among the units surveyed during the study period.

Each patient included on day 1 of each audit period was followed for a total of up to 7 days. Patients were only enrolled on day 1 of each audit period. Four survey periods were conducted, providing an evaluation of 28 days of insulin therapy in the studied units. Four periods were selected to pick up more patients on day 1 of each audit period. Electronic records of medication administration and evaluation of paper chart orders provided the information for insulin administration error rates. Additionally, physician notes regarding patients' histories and home insulin use were reviewed for background information for our patient population. Prospective daily assessments of insulin orders, doses charted, nursing notes, and blood glucose values were conducted for potential errors in insulin administration.

All definitions of insulin administration errors were defined prior to data collection. The investigators reviewed available literature involving insulin errors, and found no standardized definitions or previously published assessments at the time of inception of our study. As such, we examined our own clinical practice for areas of potential concern related to insulin administration. The following error categories were identified: transcription errors (eg, insulin glargine 10 units qpm written, but order transcribed and carried out as 20 units qpm); greater than 1 hour between obtained point‐of‐care blood glucose value and provision of correctional (sliding‐scale) insulin; insulin held without a physician order present in the medical records; missing documentation of insulin doses (glucose value of 150 mg/dL present, but no documented correctional dose corresponding to this value present in medical record); premeal and correctional insulin given at separate times; and no documentation of physician notification for hypoglycemia. Other reasons for potential insulin administration errors were collected if deemed pertinent by the individual auditors.

At the time of our survey, a standardized subcutaneous insulin administration order set was utilized in all of the surveyed units. As computerized physician order entry was not yet available at our institution, all orders were transcribed electronically from paper orders. This insulin order set has been in place for 5 years. Once initiated, all portions of the order set are initiated, including communication to nurses regarding glucose measuring times, requirement for documentation of hypoglycemia, and proposed glucose goals. A survey of insulin orders during the audit time revealed that >97% of all insulin orders were initiated from this standardized order set. These order sets encouraged the provision of physiological insulin (basal‐bolus) using insulin glargine and insulin aspart in eligible individuals. Although no systematic, standardized goal for glucose attainment was promoted, a fasting blood glucose of 90‐130 mg/dL and post‐prandial value of <180 mg/dL was encouraged. The order sets had a stated requirement of physician contact for all blood glucose values <70 mg/dL. Although lack of documentation of hypoglycemia may not be directly considered an error associated with administration of insulin, the research group decided to include this provision in the definition of administration errors, given the ability of this parameter to provide a sense of overall completeness of insulin orders and as a marker of collaborative practice in the management of inpatient hyperglycemia.

Nurses documented glucose values and responses in electronic medical administration records as a matter of routine. Point‐of‐care glucose values were obtained by either patient care technicians or nurses on each individual ward. As an academic medical institution, physicians were frequently paged by other members of the healthcare team.

Each auditor (E.N.D., A.L., L.L.W., K.A.H.) reviewed 1 consistent unit during the audit period. All data for insulin administration errors were tabulated, and descriptive rates of errors were used on a per‐patient or per‐stay basis

Results

A total of 116 patient‐audit periods were identified during the 28‐day study period (Table 1). Sixty‐five patients were on surgical services, and 51 were on medicine services, representing 378 inpatient days. Median length of stay was 3.5 days. Home insulin use was evident in 49% of the surveyed population. Patients' mean A1C (data available within 3 months prior to admission) was 8.1% (n = 41). Inpatient insulin regimens on day 1 included correctional insulin only (51.7% of cases). Regimens containing neutral protamine Hagedorn (NPH) or glargine also included correctional insulin in 95% of cases, and premeal insulin in 35%. Regimens including both premeal insulin and correctional insulin occurred in 25% of the patients. Diet status indicated that 83% of the population was taking an oral diet on day 1, and 13% were nil per os (nothing by mouth [NPO]).

Baseline Demographics
Characteristic Result
  • Abbreviations: A1C, glycated hemoglobin; DM1, diabetes mellitus type 1; DM2, diabetes mellitus type 2; NPH, neutral protamine Hagedorn; NPO, nil per os (nothing by mouth); TPN, total parenteral nutrition.

Mean age, years 59
Mean body mass index 30.9
Male 58%
Reason for admission
Diabetes‐related 7 (6%)
Cardiovascular 23 (19.8%)
Infection/sepsis 12 (10.3%)
Transplant 10 (8.6%)
Vascular surgery 10 (8.6%)
Transplant complication 8 (6.9%)
Other 46 (39.6%)
History of diabetes
DM1 7 (6%)
DM2 77 (67%)
Steroid‐induced 8 (7%)
No history of diabetes 24 (20%)
Most recent A1C (n = 41) (mean) 8.1%
Home insulin use 57 (49%)
Hospital NPH, day 1 14 (12.0%)
Hospital glargine, day 1 33 (28.4%)
Hospital correctional insulin only, day 1 60 (51.7%)
Day 1 diet
Prudent diabetic 58 (50%)
NPO 15 (13%)
Other 38 (32.7%)
Tube feeds 3 (2.6%)
TPN 2 (1.7%)

A total of 199 administration errors occurred at a rate of 1.72 errors/patient‐period and 0.53 errors/patient day (Table 2). Missing documentation of doses (15.5% of all patients) and insulin being held without an order (25% of patients) were the most frequently occurring events. Errors classified as other were found in 13.1% of the defined events. These other errors consisted of not carrying out correctional dose insulin orders appropriately (eg, blood sugar value of 149 mg/dL should have resulted in a correctional dose of 2 units, but 3 units were documented as given instead), timing errors related to provision of mealtime insulin apart from documented provision of a meal, or not following the required documentation for insulin pumps.

Insulin Administration Error Results
Category No. of events (% Out of 199 Total Errors)
Transcription error 15 (7.5)
Greater than 1 hr between blood sugar evaluation and insulin administration 20 (10.1)
Insulin held without a physician order 36 (18.1)
Missing documentation of insulin doses 58 (29.1)
Premeal and correctional insulin given at separate time 19 (9.5)
No documentation of physician notification of hypoglycemia 25 (12.6)
Other 26 (13.1)

Forty‐two patients (36%) experienced no errors in insulin administration, 18 patients experienced 1 error, 21 patients had 2 errors, and 11 patients had 3 errors. The remainder of the patients (n = 23; 19.9%) had 4 or more errors during their observation period. Were similar across the units surveyed. Frequency of errors remained consistent regardless of reason for admission, history of diabetes or insulin use at home, or length of stay. Most errors occurred on days 1 and 2 of the hospital stay. Error rates and types were consistent across all units surveyed.

Discussion/Conclusion

We found that insulin administration errors were common in our inpatient snapshot of non‐critically ill patients. In our observational evaluation, 64% of patients had at least 1 error related to insulin administration. Errors related to missing documentation of scheduled doses, or doses held without a prescriber order, were the most common. Implications of missed or held doses could range from unclear approaches for dose adjustment due to missing information, incorrect titration due to incomplete information, or hypoglycemia and hyperglycemia.

This observed rate of error is much higher than the described error rate of 19.5% reported in the United Kingdom.2 This difference in error rates most likely reflects a difference in focus, as investigators in that national effort focused on prescriber error, aberrations in blood glucose values, and readmission rates. Our evaluation in assessing error rates regarding insulin administration supports the use of personnel keenly aware of the processes related to insulin administration, and provides insight into the importance of evaluating small portions of insulin provision (administration vs prescribing, etc) in assessing grounds for improvement in care. It is important to note that our findings may be exaggerated and are not entirely comparable to a study with a different scope and size.

Our snapshot tool and baseline evaluation is a simple method that could be undertaken at many institutions. As such, this methodology and error estimate serves as a gauge for future comparisons and areas for intervention. Limitations of our assessment include the small portion of patients audited during our evaluation versus using a snapshot of our entire hospital, utilizing nonstandardized criteria for determination of insulin errors, and the lack of correlation of clinical significance (aberrations in glucose values) with errors observed. Also, this single‐institution review may not be generalizable to all institutions. Additionally, we only examined errors related to administration of insulin. Other areas that would complete the picture, related to diabetic therapies and outcomes, would need to include prescribing errors or dispensing errors and relate these to glycemic outcomes. Assessment of these additional errors may have revealed more clinically important events that were not revealed in this small snapshot. Lastly, clinical endpoints such as intensive care unit (ICU) transfers, mortality, or readmissions were not assessed in this small study.

We are fortunate that many of these errors were apparently clinically silent, but in a subset of patients, the risk is real and life‐threatening. Risk occurs at both ends of the glucose spectrum, with the low end receiving the greatest attention. Severe hypoglycemia with harm and inpatient diabetic ketoacidosis have been qualified as newer events by Medicare. Hypoglycemia in the ICU population (<40 mg/dL) is an independent marker of mortality.5 Hypoglycemia (<50 mg/dL) has been associated with heart attacks, strokes, and death in the outpatient setting.6

The ability to safely control blood sugar in the hospital requires that medications are administered on time, and that communication occurs between the prescribing provider and the nursing staff providing care. Along with the case‐by‐case implications regarding the need for accurate administration of insulin for subsequent titration and determination of discharge prescriptions for patients with diabetes, there are many implications regarding the assessment of inpatient provision of insulin on determining institutional practices based on previous performance. If insulin administration is not accurately provided or documented, institutions will find it difficult to correctly make changes to insulin protocols for targeting future improvements. Our evaluation indicates an obvious need for quality improvement with 18.1% of the errors reflecting holding insulin without an order, and 12.6% of the errors showing no documentation for the physician being notified of hypoglycemia requiring treatment. The need to foster structured nurse‐physician communication will play a critical role in any process improvement. Communication is key for the optimal provision of insulin in the inpatient setting. Computerized order entry and bar‐code guided administration of doses of insulin may fix some types of the errors (transcription and missed documentation, respectively). That said, one of the largest impacts of this survey may reveal that these errors may not be fixed by technology, but may require more targeted and difficult interventions, such as continuing education and holding clinicians accountable. This study provides insight into the complicated issues regarding inpatient insulin administration and, due to its systematic approach, has given direction for process and system improvements.

Diabetes care in the inpatient setting requires coordination between multiple service providers. Breakdowns in this process occur at all levels leading to potential serious harm.1 Error rates focusing on multiple areas related to diabetes care, including the inpatient provision of insulin, have been described as high as 19.5% in 14,000 patients surveyed in the United Kingdom.2 Missteps are important, as insulin prescribing errors are more commonly associated with patient harm.3 In the United States, medication errors related to provision of care to critically ill patients has been documented, but, to our knowledge, no such reports regarding general medical or surgical wards exist.4

Insulin errors can result from a wide range of possible reasons including: incorrect medication reconciliation, prescribing errors, dispensing errors, administration errors, suboptimal meal timing, or errors in communication for discharge plans regarding diabetes care. Examining each of these areas as a whole could be a daunting task. As such, we sought to examine 1 portion of insulin provision as an initial focus for performance improvement at our institution. Our purpose was to describe the rates of errors associated with insulin administration at our single academic medical center on general medicine and surgical wards.

Methods

Study patients for this observational, prospective snapshot were identified by electronic medical records in 4 consecutive weeks in April 2009 at Barnes‐Jewish Hospital (St Louis, MO), a 1200 bed academic medical center. This study was approved by the Washington University in St Louis School of Medicine Human Studies Committee, and the requirement for informed consent was waived.

On day 1 of each snapshot period, all patients on the identified wards were examined to determine if insulin was currently active as part of the inpatient medication orders. If active, this patient was enrolled into the evaluation data set. No patients were excluded if insulin was currently ordered. Four inpatient areas were selected to provide a representation of the non‐critically ill patient population at our institution. The 4 areas selected were: a cardiac care ward (typical census = 24), a general medicine ward (typical census = 24), an abdominal transplant ward (typical census = 18), and a general surgery ward (typical census = 22). Taken together, these areas represent about 20% of the total non‐critically ill patient population at our hospital. The transplant area was chosen because it represents a high‐risk population with medication (corticosteroid)‐induced diabetes. Nursing and physician care are typically exclusive in these areas, and very little crossover among these healthcare providers would have occurred among the units surveyed during the study period.

Each patient included on day 1 of each audit period was followed for a total of up to 7 days. Patients were only enrolled on day 1 of each audit period. Four survey periods were conducted, providing an evaluation of 28 days of insulin therapy in the studied units. Four periods were selected to pick up more patients on day 1 of each audit period. Electronic records of medication administration and evaluation of paper chart orders provided the information for insulin administration error rates. Additionally, physician notes regarding patients' histories and home insulin use were reviewed for background information for our patient population. Prospective daily assessments of insulin orders, doses charted, nursing notes, and blood glucose values were conducted for potential errors in insulin administration.

All definitions of insulin administration errors were defined prior to data collection. The investigators reviewed available literature involving insulin errors, and found no standardized definitions or previously published assessments at the time of inception of our study. As such, we examined our own clinical practice for areas of potential concern related to insulin administration. The following error categories were identified: transcription errors (eg, insulin glargine 10 units qpm written, but order transcribed and carried out as 20 units qpm); greater than 1 hour between obtained point‐of‐care blood glucose value and provision of correctional (sliding‐scale) insulin; insulin held without a physician order present in the medical records; missing documentation of insulin doses (glucose value of 150 mg/dL present, but no documented correctional dose corresponding to this value present in medical record); premeal and correctional insulin given at separate times; and no documentation of physician notification for hypoglycemia. Other reasons for potential insulin administration errors were collected if deemed pertinent by the individual auditors.

At the time of our survey, a standardized subcutaneous insulin administration order set was utilized in all of the surveyed units. As computerized physician order entry was not yet available at our institution, all orders were transcribed electronically from paper orders. This insulin order set has been in place for 5 years. Once initiated, all portions of the order set are initiated, including communication to nurses regarding glucose measuring times, requirement for documentation of hypoglycemia, and proposed glucose goals. A survey of insulin orders during the audit time revealed that >97% of all insulin orders were initiated from this standardized order set. These order sets encouraged the provision of physiological insulin (basal‐bolus) using insulin glargine and insulin aspart in eligible individuals. Although no systematic, standardized goal for glucose attainment was promoted, a fasting blood glucose of 90‐130 mg/dL and post‐prandial value of <180 mg/dL was encouraged. The order sets had a stated requirement of physician contact for all blood glucose values <70 mg/dL. Although lack of documentation of hypoglycemia may not be directly considered an error associated with administration of insulin, the research group decided to include this provision in the definition of administration errors, given the ability of this parameter to provide a sense of overall completeness of insulin orders and as a marker of collaborative practice in the management of inpatient hyperglycemia.

Nurses documented glucose values and responses in electronic medical administration records as a matter of routine. Point‐of‐care glucose values were obtained by either patient care technicians or nurses on each individual ward. As an academic medical institution, physicians were frequently paged by other members of the healthcare team.

Each auditor (E.N.D., A.L., L.L.W., K.A.H.) reviewed 1 consistent unit during the audit period. All data for insulin administration errors were tabulated, and descriptive rates of errors were used on a per‐patient or per‐stay basis

Results

A total of 116 patient‐audit periods were identified during the 28‐day study period (Table 1). Sixty‐five patients were on surgical services, and 51 were on medicine services, representing 378 inpatient days. Median length of stay was 3.5 days. Home insulin use was evident in 49% of the surveyed population. Patients' mean A1C (data available within 3 months prior to admission) was 8.1% (n = 41). Inpatient insulin regimens on day 1 included correctional insulin only (51.7% of cases). Regimens containing neutral protamine Hagedorn (NPH) or glargine also included correctional insulin in 95% of cases, and premeal insulin in 35%. Regimens including both premeal insulin and correctional insulin occurred in 25% of the patients. Diet status indicated that 83% of the population was taking an oral diet on day 1, and 13% were nil per os (nothing by mouth [NPO]).

Baseline Demographics
Characteristic Result
  • Abbreviations: A1C, glycated hemoglobin; DM1, diabetes mellitus type 1; DM2, diabetes mellitus type 2; NPH, neutral protamine Hagedorn; NPO, nil per os (nothing by mouth); TPN, total parenteral nutrition.

Mean age, years 59
Mean body mass index 30.9
Male 58%
Reason for admission
Diabetes‐related 7 (6%)
Cardiovascular 23 (19.8%)
Infection/sepsis 12 (10.3%)
Transplant 10 (8.6%)
Vascular surgery 10 (8.6%)
Transplant complication 8 (6.9%)
Other 46 (39.6%)
History of diabetes
DM1 7 (6%)
DM2 77 (67%)
Steroid‐induced 8 (7%)
No history of diabetes 24 (20%)
Most recent A1C (n = 41) (mean) 8.1%
Home insulin use 57 (49%)
Hospital NPH, day 1 14 (12.0%)
Hospital glargine, day 1 33 (28.4%)
Hospital correctional insulin only, day 1 60 (51.7%)
Day 1 diet
Prudent diabetic 58 (50%)
NPO 15 (13%)
Other 38 (32.7%)
Tube feeds 3 (2.6%)
TPN 2 (1.7%)

A total of 199 administration errors occurred at a rate of 1.72 errors/patient‐period and 0.53 errors/patient day (Table 2). Missing documentation of doses (15.5% of all patients) and insulin being held without an order (25% of patients) were the most frequently occurring events. Errors classified as other were found in 13.1% of the defined events. These other errors consisted of not carrying out correctional dose insulin orders appropriately (eg, blood sugar value of 149 mg/dL should have resulted in a correctional dose of 2 units, but 3 units were documented as given instead), timing errors related to provision of mealtime insulin apart from documented provision of a meal, or not following the required documentation for insulin pumps.

Insulin Administration Error Results
Category No. of events (% Out of 199 Total Errors)
Transcription error 15 (7.5)
Greater than 1 hr between blood sugar evaluation and insulin administration 20 (10.1)
Insulin held without a physician order 36 (18.1)
Missing documentation of insulin doses 58 (29.1)
Premeal and correctional insulin given at separate time 19 (9.5)
No documentation of physician notification of hypoglycemia 25 (12.6)
Other 26 (13.1)

Forty‐two patients (36%) experienced no errors in insulin administration, 18 patients experienced 1 error, 21 patients had 2 errors, and 11 patients had 3 errors. The remainder of the patients (n = 23; 19.9%) had 4 or more errors during their observation period. Were similar across the units surveyed. Frequency of errors remained consistent regardless of reason for admission, history of diabetes or insulin use at home, or length of stay. Most errors occurred on days 1 and 2 of the hospital stay. Error rates and types were consistent across all units surveyed.

Discussion/Conclusion

We found that insulin administration errors were common in our inpatient snapshot of non‐critically ill patients. In our observational evaluation, 64% of patients had at least 1 error related to insulin administration. Errors related to missing documentation of scheduled doses, or doses held without a prescriber order, were the most common. Implications of missed or held doses could range from unclear approaches for dose adjustment due to missing information, incorrect titration due to incomplete information, or hypoglycemia and hyperglycemia.

This observed rate of error is much higher than the described error rate of 19.5% reported in the United Kingdom.2 This difference in error rates most likely reflects a difference in focus, as investigators in that national effort focused on prescriber error, aberrations in blood glucose values, and readmission rates. Our evaluation in assessing error rates regarding insulin administration supports the use of personnel keenly aware of the processes related to insulin administration, and provides insight into the importance of evaluating small portions of insulin provision (administration vs prescribing, etc) in assessing grounds for improvement in care. It is important to note that our findings may be exaggerated and are not entirely comparable to a study with a different scope and size.

Our snapshot tool and baseline evaluation is a simple method that could be undertaken at many institutions. As such, this methodology and error estimate serves as a gauge for future comparisons and areas for intervention. Limitations of our assessment include the small portion of patients audited during our evaluation versus using a snapshot of our entire hospital, utilizing nonstandardized criteria for determination of insulin errors, and the lack of correlation of clinical significance (aberrations in glucose values) with errors observed. Also, this single‐institution review may not be generalizable to all institutions. Additionally, we only examined errors related to administration of insulin. Other areas that would complete the picture, related to diabetic therapies and outcomes, would need to include prescribing errors or dispensing errors and relate these to glycemic outcomes. Assessment of these additional errors may have revealed more clinically important events that were not revealed in this small snapshot. Lastly, clinical endpoints such as intensive care unit (ICU) transfers, mortality, or readmissions were not assessed in this small study.

We are fortunate that many of these errors were apparently clinically silent, but in a subset of patients, the risk is real and life‐threatening. Risk occurs at both ends of the glucose spectrum, with the low end receiving the greatest attention. Severe hypoglycemia with harm and inpatient diabetic ketoacidosis have been qualified as newer events by Medicare. Hypoglycemia in the ICU population (<40 mg/dL) is an independent marker of mortality.5 Hypoglycemia (<50 mg/dL) has been associated with heart attacks, strokes, and death in the outpatient setting.6

The ability to safely control blood sugar in the hospital requires that medications are administered on time, and that communication occurs between the prescribing provider and the nursing staff providing care. Along with the case‐by‐case implications regarding the need for accurate administration of insulin for subsequent titration and determination of discharge prescriptions for patients with diabetes, there are many implications regarding the assessment of inpatient provision of insulin on determining institutional practices based on previous performance. If insulin administration is not accurately provided or documented, institutions will find it difficult to correctly make changes to insulin protocols for targeting future improvements. Our evaluation indicates an obvious need for quality improvement with 18.1% of the errors reflecting holding insulin without an order, and 12.6% of the errors showing no documentation for the physician being notified of hypoglycemia requiring treatment. The need to foster structured nurse‐physician communication will play a critical role in any process improvement. Communication is key for the optimal provision of insulin in the inpatient setting. Computerized order entry and bar‐code guided administration of doses of insulin may fix some types of the errors (transcription and missed documentation, respectively). That said, one of the largest impacts of this survey may reveal that these errors may not be fixed by technology, but may require more targeted and difficult interventions, such as continuing education and holding clinicians accountable. This study provides insight into the complicated issues regarding inpatient insulin administration and, due to its systematic approach, has given direction for process and system improvements.

References
  1. Hellman R.Patient safety and inpatient glycemic control: translating concepts into action.Endocr Pract.2006;12:4955.
  2. Lamont T,Cousins D,Hillson R,Bischler A,Terblanche M.Safer administration of insulin: summary of a safety report from the National Patient Safety Agency.BMJ.341:883.
  3. Calabrese AD,Erstad BL,Brandl K,Barletta JF,Kane SL,Sherman DS.Medication administration errors in adult patients in the ICU.Intensive Care Med.2001;27(10):15921598.
  4. United States Pharmacopeia. MEDMARX 5th anniversary data report. A chartbook of 2003 findings and trends 1999–2003. Available at: http://www.usp.org/products/medMarx/index.html?USP_Print. Accessed December 1,2010.
  5. Van den Berghe G,Wilmer A,Hermans G, et al.Intensive insulin therapy in the medical ICU.N Engl J Med.2006;354:449461.
  6. The ADVANCE Trial Collaborative Group.Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes.N Engl J Med.2008;358:25602572.
References
  1. Hellman R.Patient safety and inpatient glycemic control: translating concepts into action.Endocr Pract.2006;12:4955.
  2. Lamont T,Cousins D,Hillson R,Bischler A,Terblanche M.Safer administration of insulin: summary of a safety report from the National Patient Safety Agency.BMJ.341:883.
  3. Calabrese AD,Erstad BL,Brandl K,Barletta JF,Kane SL,Sherman DS.Medication administration errors in adult patients in the ICU.Intensive Care Med.2001;27(10):15921598.
  4. United States Pharmacopeia. MEDMARX 5th anniversary data report. A chartbook of 2003 findings and trends 1999–2003. Available at: http://www.usp.org/products/medMarx/index.html?USP_Print. Accessed December 1,2010.
  5. Van den Berghe G,Wilmer A,Hermans G, et al.Intensive insulin therapy in the medical ICU.N Engl J Med.2006;354:449461.
  6. The ADVANCE Trial Collaborative Group.Intensive blood glucose control and vascular outcomes in patients with type 2 diabetes.N Engl J Med.2008;358:25602572.
Issue
Journal of Hospital Medicine - 6(9)
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Journal of Hospital Medicine - 6(9)
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Inpatient insulin orders: Are patients getting what is prescribed?
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Inpatient insulin orders: Are patients getting what is prescribed?
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