A Prospective, Randomized, Open Label, Single-Centre Study for Assessment of Safety and Effectiveness of Recombinant Human Insulin 30/70 + Insulin Glulisine compared to Recombinant Human Insulin NPH + Regular in the Management of Type 2 Diabetes Mellitus Patients in the Philippines.
Leilani B. Mercado-Asis, Mary Jane Tanchee-Ngo, Erick S. Mendoza, Gaurav Puppalwar, Ashish Mane, Anand Vasam, Agam Shah, Rishi Jain
Apr 2019 DOI 10.35460/2546-1621.2019-0010

Introduction
a. The burden of Diabetes in the Philippines
Diabetes exerts a major health impact in developing Asian countries, particularly in the Philippines. According to the World Health Organization (WHO), the region is expected to have one of the highest numbers of newly diagnosed diabetes patients by 2025 [1]. This shift in burden is associated with lacunae in the delivery of care, where more than half of the people with diabetes are not being adequately controlled [2]. Besides imposing a health burden, diabetes is also a financial burden for the Philippines with cost estimates in 2007 being US$320 million, which is expected to increase to US$1.1 billion by 2025 [3]. Given these alarming trends in diabetes epidemiology in the Philippines, the healthcare system has a challenge to optimally manage the condition with economically favorable interventions.
b. Need Gap in Insulin Regimens in the Philippines
The reported approach to initiating insulin therapy in the Philippines is the use of a premixed insulin and mealtime short-acting insulin analog. Premixed insulin eliminates the need for manual mixing, reducing dosing errors with the potential to reduce the number of daily injections. However, the fixed ratio of basal-to-prandial insulin in premixed formulations limits the ability to adjust the basal and prandial insulin doses separately, thus restricting flexibility in diet and lifestyle. Numerous observational studies have demonstrated that improved control of postprandial glucose is statistically associated with significantly decreased risk of macrovascular and microvascular complications of diabetes [4-7]. In our view, it is possible to mimic physiologic insulin replacement through a provision of both basal and prandial insulin administration with each meal separately and in a timely fashion. This adds to the patients' ability to control their glycemic profile throughout the day, by dosing insulin at each meal and modifying it based on anticipated food intake or physical activity, leading to more effective management of mealtime glycemia. However, premixed insulin therapy requires high motivation and comprehensive training to the patient as well as prescriber.
c. Search for an Effective and Economical Alternative Insulin Regimen
The current economic scenario imposes an ongoing tryst of finding an economically viable alternative insulin regimen without compromising efficacy. With the advent of newer types of insulin, studies have investigated the best way to combine insulin therapy [8-10]. Basal-bolus insulin regimen consisting of basal and prandial insulin administered as separate multiple daily insulin injections is generally considered the "ideal" for physiologic insulin management [11]. There is a need for comparing premixed insulin regimen with a combination of basal insulin with prandial short-acting insulin in terms of glycemic control, considering the cost of different regimens, particularly for a country like the Philippines.
The present study compared the glycemic control associated with Recombinant Human Insulin 30/70 + Insulin Glulisine compared to NPH Insulin + Human Insulin Regular in the Filipino population using a pragmatic ‘treat-to-target’ study design. To the best of our knowledge, there are no such published head-to-head studies from real-world clinical practice settings comparing the former - the standard of care in the Philippines with the latter - an economical option, which we hypothesized in our study to be comparable.
Methodology
a. Study Design
This was a ‘proof-of-concept’, pragmatic, ‘treat-to-target’ comparative study. The design of study was a prospective, randomized, open label, single-center, 12-week study. We compared the efficacy and safety of Recombinant Human Insulin 30/70 + Insulin Glulisine to Recombinant Human NPH Insulin + Human Insulin Regular in 40 consecutive insulin-naïve Filipino participants (randomized as 20 in each arm) with T2DM inadequately controlled with oral antidiabetic drugs, who qualified for intensification of treatment. The study was conducted from October 2015 to June 2016.
The study was conducted in compliance with the Declaration of Helsinki and the International Conference on Harmonization Good Clinical Practice Guidelines. The institutional review board reviewed and approved the protocol before the start of the study and written informed consent was obtained from all patients before their participation in the study.
The primary endpoint was change in HbA1c level from baseline to end of study (12 weeks of treatment). The secondary endpoints were changes in Fasting Plasma Glucose (FPG), Postprandial Plasma Glucose (PPG) and insulin dose from baseline to 4 weeks and 12 weeks of treatment. Safety assessments included a proportion of patients with hypoglycemia, change in body weight, physical examination finding, any local allergic reactions or systemic allergic reactions or any other AE reported during the treatment.
b. Insulin Initiation and Titration
After an initial 2-week screening period, based on the randomization schedule, patients were assigned to treatment arm A [NPH Insulin and Regular Insulin (NPH Insulin was administered two times a day and Regular Insulin three times a day)] or arm B [Insulin 30/70 + Insulin glulisine (Insulin 30/70 was administered two times a day and Insulin Glulisine three times a day)]. The study medication was continued for 12 weeks. The change in the dose of insulin was at the discretion of the investigator as per the center’s clinical practice. All the subjects were advised for automatic snacking in which the subjects take snacks automatically two hours post-meal or post-injection of insulin. The patients continued with their ongoing metformin therapy. The clinical data management team and study statisticians were kept blinded to treatment allocation until the analysis of results.
HbA1c levels measurement was done by a central laboratory. All the AEs were recorded in terms of frequency and nature. Hypoglycemia was defined as a report of one or more signs or symptoms typically associated with hypoglycemia or plasma glucose (PG) ≤70 mg/dl [12]. Severe hypoglycemia was defined as any occurrence of neuroglycopenic symptoms requiring assistance from another person with either a PG <50 mg/dl or prompt recovery after oral carbohydrate, glucagon or intravenous glucose. Nocturnal hypoglycemia was defined as any hypoglycemic event occurring at nighttime during sleep.
There were three minor protocol deviations observed, which did not impact patient safety or data credibility and were notified to the ethics committee. One patient had to be discontinued from the study but was included in the final analysis as the intention-to-treat population.
c. Statistical Methods
Since the study was designed to provide ‘proof-of-concept’, a minimum sample size of 20 patients in each arm was arbitrarily decided by the investigator rather than using statistical tools. All analyses were performed on the intention-to-treat population who had at least one post-baseline assessment by the descriptive method. Demographic and other baseline data were subjected to descriptive analysis. The primary outcome (change in HbA1c from baseline to 12 weeks) was analyzed using the analysis of covariance (ANCOVA) model. The ANCOVA model included a change in HbA1c value as the dependent variable, treatment group as the factor and the baseline HbA1c value as the covariate. The hypothesis testing was performed at 5% Limit of Significance (LOS). Other continuous variables (FPG and PPG) were analyzed similarly using the ANCOVA model with corresponding baseline values as a covariate. The hypoglycemic rate was analyzed with a negative binomial model. The proportion of subjects with hypoglycemia and other drug-related AEs were compared between the two treatment groups using the Fisher’s exact test.
Results
A total of 20 patients were enrolled in each arm from October 2015 to June 2016, as a sample representative of the Filipino population. Table 1 shows the demographic parameters. At baseline, both the treatment groups were well-matched.
Parameter |
Treatment Arm A |
Treatment Arm B |
Age (Mean ± SD, Years) |
53.25 ± 12.17 |
56.00 ± 10.70 |
Gender Male [n(%)] Female [n(%)] |
6 (30%) 14 (70%) |
8 (40%) 12 (60%) |
Weight (Mean ± SD, kg) |
69.75 ± 11.95 |
61.88 ± 9.32 |
BMI |
27.92 ± 4.57 |
24.53 ± 4.17 |
HbA1C (%) |
11.10 |
10.99 |
Table 1. Baseline demographics
a. Primary Endpoint
Primary endpoint was the mean reduction in HbA1c values from baseline to 12 weeks. Significant reductions in HbA1c values were observed in both treatment arms from baseline to 12 weeks of treatment without any statistical difference between both arms (from 11.1 ± 1.28% to 8.2 ± 1.25% in treatment arm A vs. 10.99 ± 1.41% to 8.32 ± 1.32% in treatment arm B, P = 0.657), as seen in Figure 2.
b. Secondary Endpoints
FPG, PPG and CBS values also showed large reductions from baseline at 4 weeks (visit 3) and 12 weeks (visit 4) in both treatment arms, as shown in Figure 3. However, there was no statistical difference between the two arms in terms of size of reductions (FPG: 83.65 mg/dl vs. 39.89 mg/dl, P = 0.065 at visit 3; 65.94 mg/dl vs. 46.71 mg/dl, P = 0.57 at visit 4; PPG: 99.37 mg/dl vs. 65.75 mg/dl, P = 0.306 at visit 3; 76.49 mg/dl vs. 86.96 mg/dl, P = 0.271 at visit 4; CBS: 122.1 mg/dl vs. 127.2 mg/dl, P = 0.815 at visit 3; 115.15 mg/dl vs. 145.95 mg/dl, P =0.420 at visit 4; for treatment arm A and B, respectively).
In treatment arm A, the mean basal insulin dose remained almost the same with a slight decrease in mealtime bolus insulin dose over 12 weeks of treatment, indicating possibly better control of mealtime glycemia. Whereas in treatment arm B, the mean basal insulin dose showed a slight decline with marginal increase in mealtime bolus insulin dose over 12 weeks of treatment indicating possibly improved control of basal glycemia, as shown in Table 2.
Treatment |
Dose of Insulin |
Change in Insulin Dose |
||||
Mean |
SD |
Median |
Min |
Max |
||
Arm A |
NPH Insulin |
0.00 |
4.30 |
0.00 |
-8.00 |
8.00 |
Regular Insulin |
-1.00 |
6.24 |
0.00 |
-12.00 |
14.00 |
|
Arm B |
Insulin 30/70 |
-0.45 |
5.01 |
0.00 |
-8.00 |
14.00 |
Insulin Glulisine |
0.90 |
5.37 |
0.00 |
-6.00 |
14.00 |
Table 2. Change in insulin dose
Both treatment arms reported a gain in body weights with slightly higher weight gain in treatment arm A, as shown in Table 3.
Treatment |
Change |
n |
Mean |
SD |
Median |
CV |
Min |
Max |
Arm A |
Visit 2-Visit 1 |
20 |
0.19 |
0.84 |
0.00 |
444.60 |
-1.00 |
3.00 |
Visit 3-Visit 1 |
20 |
0.73 |
2.51 |
1.00 |
343.69 |
-4.00 |
4.50 |
|
Visit 4-Visit 1 |
20 |
1.92 |
2.20 |
1.75 |
114.72 |
-2.00 |
6.00 |
|
Arm B |
Visit 2-Visit 1 |
20 |
-0.02 |
1.15 |
0.00 |
-7687.69 |
-4.00 |
3.00 |
Visit 3-Visit 1 |
20 |
0.69 |
2.84 |
1.00 |
411.64 |
-6.50 |
6.50 |
|
Visit 4-Visit 1 |
20 |
1.22 |
3.50 |
1.50 |
286.62 |
-6.50 |
7.00 |
Table 3. Change in weight in both treatment groups
c. Safety Outcomes
Forty percent of the subjects in both the treatment groups experienced AE as shown in Table 4. Thirty-five percent subjects in treatment group A and 30% in treatment group B experienced hypoglycemia. None of the patients experienced any serious AE and both treatments were well tolerated by the subjects.
Mild hypoglycemia was the most frequently reported AE in both groups. There was no case of nocturnal or severe hypoglycemia reported.
Treatment |
No. of subjects experiencing AE |
No. of patients with hypoglycemia |
Arm A (n = 20) |
8 (40.00%) |
7 (35.00%) |
Arm B (n = 20) |
8 (40.00%) |
6 (30.00%) |
Table 4. Adverse effects
Discussion
Considerations While Prescribing Insulin
Diabetes has a lifelong course and it is imperative that treatment strategies take insulin efficacy, safety, and economics into consideration. The various insulin analogs and premixed insulin have gained importance over the past decade since they offer advantages over the traditional preparations in terms of glycemic variability, frequency of injections, patient satisfaction and life expectancy [13,14]. But the cost of insulin analogs is a major problem for many patients. For instance, Palmer et al. [15] have shown that switching from traditional preparations to biphasic insulin Aspart 30 would result in an additional $9000 of lifetime direct medical costs. This calls for a relook into efficacy and safety of well-established traditional preparations from the health-economic standpoint.
a. Primary Endpoint
This is a ‘proof-of-concept’ study investigating the safety and efficacy of Insulin NPH + Regular Insulin in Filipino T2DM patients. The widely prescribed standard of care insulin 30/70 + Insulin Glulisine served as the reference treatment. This approach was used to achieve and maintain the best possible glycemic control throughout the study period of 3 months. After 12 weeks, mean HbA1c was around 8.2% in Insulin 70/30 + Insulin Glulisine arm and 8.32% with Insulin NPH + Regular Insulin arm, respectively (P = 0.657), reflecting fairly good control even if recommended levels of HbA1c <7.0% [16] were not achieved. The values pertaining to ‘change in HbA1c’ did not differ significantly at 5% LOS, which implicates that a similar efficacy could be achieved at a lower cost. This also reflects the fact that optimal glycemic control of HbA1c <7.0% is very difficult to attain in a short time of 12 weeks, especially when the baseline values are high. Optimum utilization of NPH Insulin + Regular Insulin will be achieved as clinicians regain confidence in the traditional preparations with experience and become less afraid of hypoglycemia.
The importance of stringent glycemic control in impacting long-term metabolic complications cannot be underestimated. Weng et al. [17] evaluated the role of early intensive insulin therapy in 382 newly diagnosed type 2 diabetes Chinese patients in a multicenter, randomized, parallel-group trial. They concluded that early intensive insulin therapy to achieve glycemic targets has favorable outcomes on recovery and maintenance of β-cell function and protracted glycemic remission compared to treatment with oral hypoglycemic agents. It resulted in high remission rates of approximately 50% (defined by maintained optimal glycemic control for at least 12 months without medication) and improvements in β-cell function, as well as quicker achievement of glycemic control compared with OADs. Similarly, Chen et al. [18] established in a prospective study that newly diagnosed T2DM patients with severe hyperglycemia who were hospitalized and treated with intensive insulin injections for 10-14 days, could more effectively achieve adequate glycemic control and significant improvement of beta-cell function in new-onset type 2 diabetic patients with severe hyperglycemia after a 6-month course of insulin therapy compared with OAD treatment. Similarly, many other studies have elucidated the long-term benefits of stringent HbA1c control, in terms of restoration of first-phase insulin response, β-cell function and plasma lipid profiles [19-22]. These parameters amount to realization of economic savings both from a short-term (by utilizing a lower cost insulin) and long-term (by reducing the economic burden of complications) perspective.
b. Secondary Endpoints
We found FPG reduction of 46.71 mg/dl, with a low frequency of hypoglycemic episodes over treatment duration of 12 weeks. The PPG and CBS values showed a similar decline in both groups and the difference was not statistically significant. These results are in agreement with previous randomized controlled trial results suggesting that the complementary action of long-acting insulin and prandial insulin treatment strategies on background metformin therapy is both effective and well tolerated in that it is associated with a low rate of hypoglycemia and comes without much weight gain. Our results are similar to Davidson J A et al. [23] who compared the effect of NPH Insulin with regular insulin to NPH Insulin alone in 90 patients. They observed that in the ‘NPH Insulin + Regular Insulin’ arm, the magnitude of PPG excursion was reduced and fewer patients experienced hypoglycemic events.
Weight gain has an adverse impact on insulin sensitivity, blood pressure and lipid levels and thereby increases the risk of cardiovascular disease. It may have a negative effect on patients’ self-perception and act as a barrier for optimizing insulin [24]. Further, weight gain is also an AE of insulin therapy and is inversely correlated with a reduction in HbA1c [25]. Therefore, it is important to control the body weight associated with long-term insulin therapy. In our study, patients in both arms showed similar weight gain.
Safety
Complying by the U.S. Food and Drug Administration’s regulatory guidance, this treat-to-target study yielded similar HbA1c values at 12 weeks, which enabled direct safety comparisons [26]. When initiating basal insulin and add-on prandial insulin, one of the major concerns of both, patients and clinicians is hypoglycemia [27,28]. The barriers for physicians and patients regarding initiating insulin are lowered due to the reduced risk of hypoglycemia [29]. It is the most important finding of our study that NPH Insulin plus Regular Insulin offers similar glycemic control as Premixed Insulin 70/30 with Insulin Glulisine with low risk of hypoglycemia. Overall, both insulin regimens were well tolerated and no new safety signals were observed in Filipino T2DM patients.
c. Economic Consideration
Diabetes has a significant economic impact on health care systems [30,31]. Considering the growing burden to diabetes, cost optimization strategies are warranted including the traditional yet economical preparations like Regular Insulin and NPH Insulin. We know that insulin analogs and premixed insulin are relatively more expensive to the payer, but this study proves that using the economic alternative Insulin NPH + Regular Insulin may be able to achieve similar efficacy and reduce treatment expenditures without increasing the hypoglycemia–related costs.
d. Study Limitations
The open-label study design of this study is a drawback. It is possible that a greater caution in the adjustment of doses might have been exercised in the comparator arm. Our study reported a mean HbA1c of 11.1% and 10.9% at baseline. The HbA1c at baseline was high, due to which the relative contribution of FPG versus PPG to HbA1c may be increased, thereby favoring insulin’s action. Most of the other studies evaluating the efficacy of insulin have 52 weeks duration and the 1-week duration of our study is a limitation. It is possible that the shorter duration of 12 weeks may have led to an underestimation of the potential benefits of Insulin NPH + Regular Insulin. Lastly, the small sample size reduced the power of statistical comparisons.
Conclusion
Our study results indicate that when compared to Insulin 30/70 + Insulin Glulisine, Insulin NPH + Insulin Regular provides comparable efficacy with similar safety. Further, the study observed no new safety signals in the Filipino population. Hence, the study proposes a concept that Insulin NPH + Insulin Regular can be an economical alternative to costly premixed insulin or insulin analogs in patients requiring insulin therapy.
Disclosure and Conflict of Interest
Authors Gaurav Puppalwar, Ashish Mane, Anand Vasam, Agam Shah and Rishi Jain are salaried employees of Wockhardt Ltd., India. Rest of the authors have no financial interests to disclose.
Acknowledgment
The study was funded by a research grant from Wockhardt Ltd., India. The medical writing support was provided by Dr. Pratishtha Banga. The medical writing support was funded by Wockhardt Ltd., India.
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Figure Legends
Figure 1: Flow chart of the recruitment process
Figure 2: The mean reduction in HbA1c values from baseline to visit 4 (after 12 weeks), was similar in insulin regimen NPH Insulin + Regular Insulin (Arm A) compared to Insulin 30/70 + Insulin Glulisine (Arm B)
Figure 3: The average change in FPG, PPG and CBS values from baseline to visit 3 and 4 (12 weeks) was similar in insulin regimen NPH Insulin + Regular Insulin (Arm A) compared to Insulin 30/70 + Insulin Glulisine (Arm B). (Abbreviations FPG: Fasting Plasma Glucose, PPG: Post Prandial Glucose, CBS: Capillary Blood Sugar)
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