Switching From Pre-mixed Insulin to Regimens with Insulin Glargine in Type 2 Diabetes: A Prospective, Observational Study of Data From Adriatic Countries

A total of 92 hospital-based physicians participated as investigators in this prospective, observational, post-marketing, multicenter study that took place between April 2013 and May 2015 in the following Adriatic countries: Bosnia and Herzegovina, Macedonia, Albania, and Slovenia. Investigators were expected to enroll adult patients with T2D who were previously inadequately controlled with pre-mixed insulin and switched to the insulin glargine regimen with or without (±) orally administered antidiabetic drugs (OADs) or ± prandial insulin. Patients with type 1 diabetes, those who were pregnant, those with a history of secondary diabetes, or those on temporary insulin treatment were excluded from the study.

The patient observation period lasted six months from the date of inclusion (i.e., 1–3 months from the time of the first insulin glargine administration). The medical assessment and outcome measurements were performed at the time of inclusion and at three and six months from inclusion (Fig. 1). Because of the noninterventional nature of the study, the decision to use a particular type of insulin glargine therapy regimen (± OADs or additional rapid insulin injections) was made by the physicians, who were also responsible for the documentation of all outcomes.

This study has been approved by the appropriate ethics committees: Ethics Committee, Ministry of Health, Republic of Macedonia; Republic of Slovenia National Medical Ethics Committee; National Committee of Medical Ethics, Albania; and the ethics committees of the institutions in which the study was conducted (e.g., ethics committees of Clinical Hospital Mostar, Clinical Hospital Zenica, General Hospital Trebinje, Health Center Tuzla) in Bosnia and Herzegovina. Informed consent was obtained prior to the conduct of any study-related data collection procedures. Data were collected in paper form and centrally collected at the site of the company sponsor.

The primary endpoint involved analyzing HbA1c and fasting blood glucose (FBG) levels at inclusion and subsequent follow-up visits (after three and six months) to determine the mean values and the proportion of patients who achieved HbA1c < 7% (< 53 mmol/mol) and FBG in the range of 3.9–7.2 mmol/L.

The secondary endpoints involved analyzing the patients’ weight gain, incidence of hypoglycemia, and satisfaction with the therapy. Weight gain was assessed by measuring body mass index (BMI) and waist circumference. Data on hypoglycemia frequency (symptomatic, confirmed, nocturnal, and severe) were collected at the baseline visit, retrospectively taking into account the three months prior to introduction of insulin glargine, and prospectively at the three- and six-month follow-up visits. These data came directly from the patients, who were advised to mark every event of hypoglycemia in their diaries. Patient satisfaction with the therapy was assessed based on their answers to the question “How satisfied are you with the treatment?” Possible answers corresponded to a five-point Likert scale of either “very dissatisfied,” “dissatisfied,” “neither satisfied nor dissatisfied,” “satisfied,” or “very satisfied.” All adverse events that took place from the time of signing the informed consent to the end of the study were recorded in the case report form.

Depending on the type and number of parameters examined, the χ² test, Mantel–Haenszel test, Student’s t test for independent or paired samples, Mann–Whitney U test, Wilcoxon signed-rank test, ANOVA and post-hoc analysis, and binary logistic regression were used. In all tests, a p value < 0.05 was considered statistically significant. Levene’s test was used to assess equality of variances. The normal distribution of each variable was checked with the Kolmogorov–Smirnov test. For the descriptive analysis, missing data were presented as valid calculated percentages. In other analyses, missing data were excluded. All patients meeting the inclusion/exclusion criteria were included in the full data set. For the subpopulation analyses, data were divided into three sets: (1) the basal + OADs set (patients previously treated with pre-mixed insulin who were switched to insulin glargine with concomitant OADs); (2) the basal plus set (patients previously treated with pre-mixed insulin who were switched to insulin glargine with one additional daily prandial injection of rapid-acting insulin); and (3) the basal bolus set (patients previously treated with pre-mixed insulin who were switched to insulin glargine with two or three additional prandial injections of rapid-acting insulin).

A total of 1041 (606 female) patients completed the study. The mean age was 61.80 ± 9.31 years, with most patients ranging from 55 to 65 years of age. Mean BMI was 29.7 ± 4.7 kg/m² and was significantly higher in females (30.5 ± 4.9 kg/m²) than in males (28.6 ± 4.0 kg/m²; p  < 0.01). Complications and/or comorbidities were reported in 855 (82.1%) patients; the most common complications were diabetic neuropathy (41.5% of the studied population) and diabetic retinopathy (35.4%). Patient characteristics at study entry are presented in Table 1.

In terms of concomitant medications, biguanides (836 patients, 80.3%) and sulfonylureas (783 patients, 75.2%) were the most commonly administered OADs prior to study entry. A total of 748 (71.8%) patients continued OAD therapy at the baseline visit; however, while biguanides remained frequently used after the switch to insulin glargine (639 patients, 61.4% at baseline), sulfonylureas were mostly discontinued by the time of the baseline visit. A total of 295 patients (28.3%) received no OADs at baseline, and the use of non-biguanide OADs was uncommon, ranging from 13 patients (1.2%) for sulfonylureas to 54 (5.4%) for sulfonylurea + biguanide combination. See the Electronic spplementary material (ESM) for more information on concomitant antidiabetic therapy at baseline and during the study period.

From the time of insulin glargine introduction, 461 (44.9%) patients were treated with the basal + OADs regimen, 125 (12.2%) patients with the basal plus regimen, and 441 (42.9%) patients with the basal bolus regimen. After three months, 44.6% of patients were on the basal + OADs regimen, 12.3% of patients were on the basal plus regimen, and 43.1% of patients were on the basal bolus regimen. After six months, 44.6% of patients were treated with the basal + OADs regimen, 12.2% with the basal plus regimen, and 43.1% with the basal bolus regimen. To determine whether switching to insulin glargine is beneficial for patients inadequately treated with pre-mixed insulin, we set strict therapeutic goals to assign efficacy. Overall, the primary goal of obtaining HbA1c < 7% was reached in 9.3% and 30.2% of patients at month three and month six of therapy, respectively. Similarly, the secondary goal of achieving HbA1c levels < 7% and FBG levels in the range 3.9–7.2 mmol/L was reached in 73 patients (7%) after three months and in 270 (25.9%) patients after six months of therapy. A significantly higher percentage of patients achieved this therapeutic goal at month six of observation compared to month three (p < 0.01). FBG levels within the targeted plasma concentration range (3.9–7.2 mmol/L) were noted in 34 (3.3%) patients at inclusion, in 298 (28.6%) at the three-month follow-up visit, and in 544 (52.3%) patients at the six-month follow-up visit, with the increase in prevalence being statistically significant (p < 0.01; Fig. 2). A similar statistically significant increase in the proportion of patients reaching both therapeutic goals from month three to month six of observation was observed among all three prescribed regimens (data not shown).

The mean value of HbA1c among the study population decreased significantly throughout the observation period—from 9.5 ± 1.6% at baseline to 8.3 ± 1.3% at three months, and to 7.5 ± 1.1% at the six-month follow-up visit. Similar positive outcomes were observed for FBG: its plasma concentration decreased from 12.1 ± 3.7 mmol/L at baseline to 8.7 ± 2.6 mmol/L at three months, and to 7.7 ± 2.1 mmol/L at the six-month follow-up visit.

No severe cases of hypoglycemia were observed throughout the study in patients who switched to the insulin glargine regimen. The reported serious adverse events included two cases of myocardial infarction and one case of trimalleolar fracture of the right ankle. The data on reported hypoglycemic events are shown in Table 2. Basal insulin glargine therapy was accompanied by a significant decrease in the number of hypoglycemia events reported by patients. Before switching to insulin glargine therapy, 45.9% of patients reported at least one event of hypoglycemia, whereas only 8.5% and 5.2% of patients reported these events at the three-month and six-month follow-up visit, respectively. Regarding the particular types of hypoglycemia, the most significant decrease in the number of hypoglycemic events was observed for nocturnal hypoglycemia: 2.4% vs. 0.8% between the three-month and six-month follow-up visits, respectively. The proportion of patients who experienced hypoglycemia was much higher in those receiving the basal bolus regimen compared to those receiving the basal + OADs or basal plus regimen (Table 3). This was somewhat expected, as the basal bolus regimen showed the lowest efficacy in terms of the composite endpoint.

In the full study population, body weight and waist circumference decreased significantly during the follow-up period (Table 4). Waist circumference was reduced in 566 (59.1%) patients and BMI in 587 (57.8%) patients over the study period. Conversely, increases in waist circumference and BMI were observed in 168 (17.6%) and 251 (24.9%) of the patients, respectively; 233 (23.3%) patients experienced no change in waist circumference and 176 (17.3%) experienced no change in BMI. It is worth noting that patients whose BMI decreased during the study had significantly higher starting BMI (30.7 kg/m²) than those whose BMI remained unchanged (28.7 kg/m²) or increased (28.3 kg/m²) (p  < 0.05 for both comparisons). In terms of concomitant OADs, patients whose waist circumference or BMI decreased during the study period were more likely to receive metformin and less likely to receive no OAD therapy than those whose waist circumference or BMI increased or remained unchanged (Table S3 in the ESM). We detected no association between non-metformin OAD use and waist circumference or BMI change, likely due to the small number of patients receiving OADs other than metformin.

The proportion of patients with any hypoglycemic episode was significantly higher among patients whose BMI increased than among those whose BMI decreased during the study period (13.0% vs 6.5% at the three-month visit, p < 0.05 and 9.9% vs 3.4% at the six-month visit, p < 0.01); a similar relationship was observed for waist circumference (13.7% vs 5.8% at the three-month visit, p < 0.01 and 10.7% vs 3.2% at the six-month visit, p < 0.01). There was a weak but statistically significant positive Spearman correlation between waist circumference increase and the incidence of any hypoglycemic episode, and between BMI increase and the incidence of any hypoglycemic episode (both p  < 0.01).