Teneligliptin in management of type 2 diabetes mellitus.

Teneligliptin is a recently developed oral dipeptidyl peptidase 4 inhibitor indicated for the management of type 2 diabetes mellitus (T2DM) in adults along with diet and exercise. Teneligliptin has been recently available in Japan (Teneria(®)), Argentina (Teneglucon(®)), and India (Tenepure; Teneza) at relatively affordable price. This is a positive step toward the management of T2DM in developing countries, where the cost of medicine is out-of-pocket expenditure and is a limiting factor for health care. This review evaluates the efficacy and safety of teneligliptin in the management of T2DM. Teneligliptin has been systematically evaluated in T2DM as monotherapy with diet and exercise and in combination with metformin, glimepiride, pioglitazone, and insulin in short-term (12 weeks) and long-term (52 weeks) studies. These studies have reported a reduction in HbA1c of 0.8%-0.9% within 12 weeks of therapy. Two 52-week studies reported sustained improvement in glycemic control with teneligliptin. Teneligliptin has been found to be well tolerated, and the safety profile is similar to other dipeptidyl peptidase 4 inhibitors. Hypoglycemia and constipation are the main adverse events. Teneligliptin can be administered safely to patients with mild, moderate, or severe renal impairment or end-stage renal disease without dose adjustment. Similarly, it can be used in patients with mild-to-moderate hepatic impairment. Teneligliptin is effective and well tolerated and may have an important role in the management of T2DM.

Introduction

Diabetes is a common noncommunicable disease and has reached to epidemic stage in many countries. Globally, 415 million people are living with diabetes and it is a leading cause of death. This number is expected to rise to 642 million by 2040. A mortality burden of 5 million was noted with diabetes. The People’s Republic of China, India, the US, and the Russian Federation reported highest deaths due to diabetes.1

Diabetes affects many organs, and complications due to high blood glucose are an important cause of disability, reduced quality of life, and premature death.1 In 2015, globally, ~5 million people aged between 20 years and 79 years died due to diabetes; this accounts for one death every 6 seconds.1

Diabetes is a chronic disease that requires lifelong medical care and attention for multiple risk reduction and treatment approach beyond glycemic control.2 Treatment objective must be the prevention of short-term and long-term complications associated with diabetes.3 Additionally, patient education and support are important aspects.3 This will improve patient outcomes.2 A multidisciplinary approach is required for the management of diabetes.2,3

Considering the huge epidemic of type 2 diabetes mellitus (T2DM), newer therapies that improve efficacy, tolerability, and long-term compliance and prevent complications associated with T2DM are always required and preferred.4 Recently, a new and relatively economic dipeptidyl peptidase 4 (DPP-4) inhibitor, teneligliptin, has been made available in some countries such as Japan (Teneria®), Argentina (Teneglucon®), and India (Tenepure; Teneza).5–7 This review highlights the place of therapy of teneligliptin in the management of T2DM.

The economic costs of T2DM

There is a substantial economic impact of diabetes on individuals, society, health care system, employer, and even the country in terms of loss of productivity.8 Reported evidence suggests that there is a strong and direct economic impact of T2DM on the lives of people in lower income settings.8 In developing countries, where health care expenditure is many times out-of-pocket, an economic impact of T2DM is huge and may affect the long-term outcome of T2DM.8

There is wide variation in the indirect and direct costs incurred for diabetes in a studied year. In Mexico, direct cost including out-of-pocket expenditures was $242, while it was reported as $11,917 in the US.8 Similarly, indirect cost ranged from $45 in Pakistan to $16,914 in the Bahamas.8 It was also reported that in low- and middle-income countries, out-of-pocket expenditure on health care cost has a significant burden.8

This highlights that there should be affordable medical treatment available to all. The cost of medicine should not be a barrier for health care. In this scenario, availability of economical DPP-4 inhibitors such as teneligliptin is a positive step.

Management of T2DM

T2DM is a chronic progressive disease and involves multiple systems. Diet, exercise, education, pharmacotherapy, and blood glucose monitoring are important pillars for the management of T2DM.9 Published evidence suggests that even 1% reduction in HbA1c reported significant reduction in the risk of long-term complications associated with T2DM (Figure 1).10

Figure 1

Reduction in risk of long-term complications associated with 1% reduction in HbA1c.

Note: Data from a previous study.10

Various patient and disease factors affect HbA1c targets. Therefore, individualized glycemic goals are always preferred, and tailor-made antidiabetic therapy is recommended in routine clinical practice.9,11 Factors determining individual glycemic goal are presented in Table 1.9,11 There are various approaches for initiation and titration of antidiabetic therapy. The American Diabetes Association (ADA) position statement of Standards of Medical Care in Diabetes – 2016 has recommended evidence-based antidiabetic therapy (Table 2).12

Table 1

Factors determining individual glycemic goal

Glycemic goal

1. AACE: HbA1c ≤6.5%

2. ADA: HbA1c <7%

Factors determining HbA1c goal

1. Age of the patient

2. Hypoglycemia risk

3. Associated comorbidities

4. Duration of disease

5. Life expectancy

Note: Data from previous studies.9,11

Abbreviations: AACE, American Association of Clinical Endocrinologists; ADA, American Diabetes Association.

Table 2

ADA recommendations of antihyperglycemic therapy in T2DM

Life style modification: healthy diet, weight control, increased physical activity, diabetes education
Monotherapy	Metformin
If HbA1c target is not achieved after ~3 months of monotherapy, proceed to two-drug combinations as follows:
Dual therapya	Metformin + SU	Metformin + TZD	Metformin + DPP-4i	Metformin + SGLT2-i	Metformin + GLP-1RA	Metformin + basal insulin
If HbA1c target is not achieved after ~3 months of dual therapy, proceed to three-drug combinations as follows:
Triple therapy	Metformin + SU + TZD or DPP4-i orSGLT2-i or GLP-1RA or basal insulin	Metformin + TZD + SU or DPP4-i or SGLT2-i or GLP-1RA or basal insulin	Metformin + DPP-4i + SU or TZD or SGLT2-i or basal insulin	Metformin + SGLT2-i + SU or TZD or DPP-4 i or basal insulin	Metformin + GLP-1RA + SU or TZD or basal insulin	Metformin + basal insulin + TZD or DPP4-i or SGLT2-i or GLP-1RA
If HbA1c target is not achieved after ~3 months of triple therapy, and patient 1) on oral combination, move to injectables 2) on GLP-1RA, add basal insulin, or 3) on optimally titrated basal insulin, add GLP-1RA or mealtime insulin. In refractory patients, consider adding TZD or SGLT2-i
Combination injectable therapyb	Metformin + basal insulin + mealtime insulin or GLP-1 RA

Notes:

Consider starting at this stage when HbA1c is ≥9%.

Consider starting at this stage when blood glucose is ≥300–350 mg/dL and/or HbA1c is ≥10%–12%, especially if symptomatic or catabolic features are present, in which case insulin + mealtime is the preferred initial regimen. Basal insulin: NPH, glargine, detemir, degludec. Data from a previous study.12

Abbreviations: ADA, American Diabetes Association; DPP-4, dipeptidyl peptidase 4; DPP-4-i, DPP-4 inhibitor; GLP-1-RA, GLP-1 receptor agonist; SU, sulfonylurea; SGLT2-i, sodium-glucose cotransporter 2 inhibitor; T2DM, type 2 diabetes mellitus; TZD, thiazolidinedione.

Role of DPP-4 inhibitors in the management of T2DM

The first DPP-4 inhibitor, sitagliptin, was approved in 2006 for the treatment of T2DM concurrently with lifestyle changes.13 As mentioned in Table 2, DPP-4 inhibitors are recommended as monotherapy or in double and triple drug combination with other oral glucose-lowering agents such as metformin, sulfonylureas, thiazolidinediones, or even with insulin.12 As a class, DPP-4 inhibitors are considered as a cornerstone in the management of T2DM due to their efficacy, favorable tolerability profile such as low risk of hypoglycemia and weight gain, and compliance due to once-a-day dosage.14

Currently, eight DPP-4 inhibitors, namely, alogliptin, anagliptin, gemigliptin, linagliptin, saxagliptin, sitagliptin, teneligliptin, and vildagliptin, are available for the management of T2DM.15 All these DPP-4 inhibitors have a similar mechanism of action and safety profile. In spite of their similar mechanism of action, DPP-4 inhibitors differ in some important pharmacokinetic and pharmacodynamic parameters, which may have clinical significance in real-life scenario (Table 3).14

Table 3

Important differences among eight DPP-4 inhibitors

Pharmacokinetic differences	Oral bioavailability, elimination half-life, binding to plasma proteins, metabolic pathways, formation of active metabolite(s), main excretion routes, and potential drug–drug interactions
Pharmacodynamic differences	Potency, target selectivity, dosage adjustment for renal and liver insufficiency

Note: Data from a previous study.14

Abbreviation: DPP-4, dipeptidyl peptidase 4.

Adverse events like immune dysfunction, impaired healing and skin reactions are reported and may be due to off-target inhibition of selective DPP-4 enzymes.14 However, these toxicities are not clinically significant.

Are all DPP-4 inhibitors same?

As mentioned earlier, all DPP-4 inhibitors have the same mechanism of action and safety profile, but there are some important differences not only in the pharmacokinetic and pharmacodynamic properties but also in the potency of DPP-4 enzyme inhibition.14

Comparative studies have determined binding modes of DPP-4 inhibitors with the active site of DPP-4 enzyme.16,17 DPP-4 enzyme has five binding sites (subsites), namely, S1, S2, S1′, S2′, and S2 extensive (Figure 2).16,17 An interaction of DPP-4 inhibitors with S1 and S2 is considered to be the fundamental interaction that is required for DPP-4 inhibition.16 Additional interaction with S1′, S2′, and S2 extensive site may further increase the DPP-4 inhibition.16 DPP-4 inhibitors are classified according to their interactions with a DPP-4 enzyme (Table 4).16 Classification of DPP-4 inhibitors is based on their selectivity for enzyme and are Class 1, Class 2, and Class 3.16 Class 1 inhibitors (eg, vildagliptin and saxagliptin) bind with S1 and S2 and are considered as fundamental/basic inhibitors.16 Class 2 inhibitors (alogliptin and linagliptin) bind with additional sites of S1′ and S2′ and may produce more DPP-4 inhibition than Class 1.16 Class 3 inhibitors (sitagliptin and teneligliptin) bind additional site of S2 extensive and produce more extensive DPP-4 inhibition.16 Teneligliptin, a Class 3 inhibitor, reported fivefold higher activity than sitagliptin.16

Figure 2

DPP-4 enzyme-binding sites.

Note: Data from a previous study.16

Table 4

Summary of the interactions of various DPP-4 inhibitors with DPP-4 enzyme

Class	DPP-4 inhibitors	Binding at DPP-4	Interaction with DPP-4 at various sites	Details
1	Vildagliptin and saxagliptin	S1 and S2 subsites		• Most fundamental level of interaction• Cyanopyrrolidine moieties bind with S1• Hydroxy adamantly group binds with S2• Saxagliptin has fivefold higher activity than vildagliptin
2	Alogliptin and linagliptin	S1, S2, S1′, and S2′ subsites		• Additional binding to S1′ and S2′• Alogliptin binds to S1, S2, and S1′• Linagliptin binds to S1, S2, S1′, and S2′• Linagliptin had eightfold higher activity than alogliptin
3	Sitagliptin and teneligliptin	S1, S2, and S2 extensive subsites		• Binds S1, S2, and S2 extensive• Teneligliptin has fivefold higher activity than sitagliptin, because of:  • Teneligliptin has favorable (J-shaped) structure leading to small loss of energy during binding with DPP-4 • Teneligliptin forms hydrogen bond with DPP-4 • Teneligliptin has more extensive binding at “S2 extensive” site than sitagliptin

Note: Data from a previous study.16

Abbreviation: DPP-4, dipeptidyl peptidase 4.

Teneligliptin

Teneligliptin is a novel oral DPP-4 inhibitor developed by Mitsubishi Tanabe Pharma Co. and approved in Japan in September 2012 for the management of T2DM.5 Currently, teneligliptin is marketed in Japan (Teneria), Argentina (Teneglucon), and India (Tenepure; Teneza) (Table 5).5–7 Presently, teneligliptin is registered in South Korea and is in the preregistration phase in Indonesia. Additionally, teneligliptin is in phase II clinical trials in Europe, and phase I clinical trials in the US.18 Teneligliptin, which is classified as peptidomimetic, has a unique structure having five consecutive rings.16 Due to this unique structure, teneligliptin acts on S2 extensive subsite of DPP-4; this interaction enhances its potency and selectivity.5

Table 5

Approval status of teneligliptin

Phase of development	Indication	Country
Marketed	T2DM	Japan
Marketed	T2DM	Argentina
Marketed	T2DM	India

Note: Teneligliptin is marketed in Japan,5 Argentina,6 and India.7

Abbreviation: T2DM, type 2 diabetes mellitus.

Pharmacokinetics of teneligliptin

Reported evidence suggests that with teneligliptin 20 mg therapy, Tmax was 1 hour and t1/2 was 18.9 hours. Maximum (89.7%) inhibition in plasma DPP-4 activity was noted within 2 hours and maintained >60% at 24 hours. Compared to placebo, active plasma GLP-1 concentration was higher throughout the day and even at 24 hours after administration of teneligliptin 20 mg. Metabolism of teneligliptin was majorly mediated through CYP3A4, a cytochrome P450 isozyme, and flavin-containing monooxygenases (FMO1 and FMO3).5

A weak inhibitory activity of teneligliptin on CYP2D6, CYP3A4, and FMO was noted, while there was no inhibitory activity on CYP1A2, CYP2A6, CYP2B6, CYP2C8, CYP2C8/9, CYP2C19, and CYP2E1. There was no induction of expression of CYP1A2 or CYP3A4.5

Reported evidence suggests that teneligliptin is metabolized and eliminated via both renal and hepatic routes. Approximately 34% of teneligliptin is excreted unchanged via the renal route, while 66% is metabolized and eliminated via the hepatic and renal routes.5

Teneligliptin in renal impairment

Halabi et al studied the pharmacokinetics of a single oral dose of teneligliptin 20 mg, in subjects with renal impairment and end-stage renal disease (ESRD). Subjects participating in this study were allocated to six groups based on their renal function. Out of these six groups, four groups comprised subjects having mild, moderate, and severe renal impairment and ESRD, respectively, while two groups were having healthy subjects with a normal renal function. Eight subjects were included in each group to have at least six evaluable subjects in each group at the end. This study revealed that teneligliptin 20 mg single oral dose had no effect on maximum plasma concentration (Cmax) in patients with mild, moderate, and severe renal impairment. There was an increase in AUC0–∞ in subjects with renal impairment across the group compared to healthy subjects; however, this was unrelated to the degree of renal impairment. Teneligliptin was well tolerated by subjects with renal impairment or ESRD. Dialysis was not expected to affect the efficacy or safety of teneligliptin. This study concluded that dose adjustment may not be needed when teneligliptin is administered to subjects with mild, moderate, or severe renal impairment or ESRD.19

The efficacy and safety of teneligliptin in diabetic ESRD patients undergoing hemodialysis were studied through a bicenter, prospective, nonrandomized study. A total of 45 patients were enrolled in this study, which included 16 patients enrolled in the teneligliptin group (7 therapy-naïve and 9 switched from other medications) and 29 in the control group. Fourteen patients in the teneligliptin group (7 each as therapy-naïve and switched from other medications) and 29 in the control group completed 28-week study period. At 4 weeks, 36.7 mg/dL reduction in blood glucose was noted in the teneligliptin group (P<0.05). More prominent reduction of 3.1% in glycated albumin was noted in the teneligliptin group than the control group (P<0.05). Similarly, more reduction in HbA1c (difference −0.57%; P=0.057) was noted in the teneligliptin group compared to the control group. Reduction in these variables was also noted in patients who were switched to teneligliptin from voglibose 0.2 mg three times in a day (tid) or vildagliptin 50 mg once per day (qd). Interestingly, this study reported that teneligliptin 20 mg daily was more potent than voglibose 0.2 mg tid or vildagliptin 50 mg qd. However, a small number of patients were switched to teneligliptin from voglibose or vildagliptin, and no statistical analysis was performed. Teneligliptin was well tolerated without any episodes of hypoglycemia during the study period. The study concluded that in diabetic patients with ESRD, teneligliptin significantly improved glycemic control and was well tolerated. Teneligliptin appeared to be more potent than voglibose or vildagliptin based on its glucose-lowering effects.20

The efficacy and safety of linagliptin and teneligliptin on glycemic control in T2DM with chronic kidney disease (CKD) were assessed in a pilot study through continuous glucose monitoring. This was a randomized crossover study including 13 patients with T2DM with CKD having HbA1c <9% and estimated glomerular filtration rate <60 mL/min/1.73 m2. There were two groups receiving either teneligliptin or linagliptin for 6 days from hospital day 5 and followed by crossover to linagliptin or teneligliptin on hospital day 11 for the next 6 days. The primary outcome of changes in the mean amplitude of glucose excursions was similar in both the groups. Equivalent effects on 24-hour mean sensor glucose levels and area under the curve for sensor glucose levels were noted for both the groups. A similar incidence of hypoglycemia was noted. The study concluded that in patients with T2DM with CKD, teneligliptin and linagliptin have comparable effects on blood glucose and a similar safety profile.21

Teneligliptin in the management of T2DM: an evolving landscape

Effects of teneligliptin on 24-hour blood glucose control

A 4-week, randomized, double-blind, placebo-controlled, parallel-group study was conducted to analyze the pharmacokinetic and pharmacodynamic characteristics, effects on blood glucose control over 24 hours, and safety of once-daily teneligliptin in patients with T2DM inadequately controlled with diet and exercise. A total of 99 subjects, which included 32, 34, and 33 subjects in a placebo, teneligliptin 10 mg group, and teneligliptin 20 mg group, respectively, were randomized and analyzed. Plasma concentration of teneligliptin was maintained for 24 hours; similarly >50% inhibition of DPP-4 was noted at 24 hours of administration. Compared to the placebo group, significantly lower 2-hour postprandial glucose (2-hour PPG), 24-hour mean glucose, and fasting plasma glucose (FPG) were noted in teneligliptin 10/20 mg treated groups. Teneligliptin 10 mg reported more reduction in 2-hour PPG after each meal compared to placebo. Compared to placebo, a mean difference of −50.7 mg/dL, −34.8 mg/dL, and −37.5 mg/dL was noted (P<0.001 for all) in 2-hour PPG after breakfast, lunch, and dinner, respectively, in teneligliptin 10 mg group. Similarly, mean difference in reduction of 2-hour PPG after breakfast, lunch, and dinner was −38.1 mg/dL (P<0.001), −28.6 mg/dL (P<0.01), and −36.1 mg/dL (P<0.001), respectively, with teneligliptin 20 mg compared to placebo. Postprandial plasma active glucagon-like peptide-1 concentrations were also increased with teneligliptin 10/20 mg compared to placebo. A similar incidence of adverse events (AEs) was noted in all groups with no incidence of serious AE including hypoglycemia.22

Role of teneligliptin in patients with T2DM inadequately controlled with diet and exercise

Kadowaki et al evaluated the efficacy, safety, and dose–response relationship of teneligliptin in Japanese patients with T2DM and inadequately controlled with diet and exercise through a randomized, double-blind, placebo-controlled, parallel-group study for 12 weeks. A total of 324 Japanese T2DM patients with age 20–75 years, HbA1c 6.8%–9.8%, and not taking any oral antihyperglycemic agent for ≥8 weeks were randomized to receive teneligliptin 10 mg (n=84), 20 mg (n=79), 40 mg (n=81), and placebo (n=80) once daily for 12 weeks. Significantly greater reductions in HbA1c and FPG were reported in all teneligliptin groups compared to placebo group. AEs were similar in all groups. There was no significant difference in the incidence of hypoglycemia among the four groups.23 Thus, in patients with T2DM inadequately controlled with diet and exercise, treatment with teneligliptin reported a significant and clinically important reduction in glycemic parameters.

Addition of teneligliptin in patients with T2DM not controlled with metformin therapy

Efficacy and safety of the addition of teneligliptin in inadequately controlled T2DM patients with metformin monotherapy were evaluated in a randomized, double-blind, placebo-controlled, parallel-group, Phase III study. A total of 204 patients with T2DM with inadequate glycemic control (HbA1c 7.0%–10.0%) and receiving stable-dose metformin monotherapy (≥1,000 mg/d) for at least 8 weeks received teneligliptin 20 mg once daily or a placebo once daily for 16 weeks. All patients received background therapy of metformin. At the end of 16 weeks, the difference in HbA1c and FPG levels between teneligliptin and placebo groups was −0.78% and −22.42 mg/dL, respectively. Significantly higher percentage of patients achieved ADA goal (HbA1c <7%) in teneligliptin plus metformin group than placebo plus metformin group (64.71% vs 13.24%, respectively; P<0.001). Greater increases in β-cell function (HOMA-β; P=0.0008) and improvement in insulin resistance (HOMA-IR; P=0.1754) were noted in teneligliptin plus metformin group than placebo plus metformin group. A similar incidence of AE was noted in both the groups. Thus, the addition of teneligliptin to metformin treatment was effective in controlling blood glucose and well tolerated in patients with T2DM.24

Teneligliptin added to glimepiride in patients with T2DM

A multicentric, double-blind, placebo-controlled, parallel-group, Phase III, randomized control trial was conducted to evaluate the efficacy and safety of teneligliptin in combination with glimepiride. A total of 194 Japanese patients with T2DM receiving stable glimepiride (1–4 mg/d) monotherapy for ≥8 weeks and reporting inadequate glycemic control (HbA1c 7.3%–10.3%) were randomized to receive teneligliptin 20 mg or placebo once daily in addition to stable glimepiride therapy for 12 weeks. After 12 weeks of the randomized period, all patients followed an open-label period of 40 weeks. During open-label period, all patients received teneligliptin and glimepiride therapy (teneligliptin to teneligliptin and placebo to teneligliptin). At the end of 12 weeks, teneligliptin group reported 0.7% mean reduction in HbA1c and difference between placebo group was 1% (P<0.001). Similarly, mean reduction in FPG and PPG was 17.4 mg/dL and 43.1 mg/dL, respectively, in the teneligliptin group. The mean difference of FPG and PPG between teneligliptin and placebo groups was 27.1 mg/dL (P<0.001) and 49.1 mg/dL (P<0.001), respectively, at the end of 12 weeks. The reduction in HbA1c was maintained for 52 weeks, and HbA1c was significantly lower at 52 weeks compared to baseline in both the groups (P<0.001 both groups). The mean reduction in HbA1c at 52 weeks was 0.6% and 0.9% in “teneligliptin to teneligliptin” group and “placebo to teneligliptin” group, respectively. Significant improvement in proinsulin/insulin ratio, HOMA-β, and postprandial glucagon was also noted in the teneligliptin group compared with the placebo group. The incidence of AEs/adverse drug reactions (ADRs) including hypoglycemia with teneligliptin was similar to placebo during the randomized period. Two patients (2.1%; 0.091 events/patient-years) in the teneligliptin group and three patients (3.1%; 0.226 events/patient-years) in the placebo group reported hypoglycemic symptoms. A similar trend of AEs/ADRs was noted in the open-label period. Only 0.5–0.7 kg increase in body weight was noted over the 52-week period. In patients with inadequate glycemic control with glimepiride monotherapy, an addition of teneligliptin improved glycemic control, which was sustained for 52 weeks. Teneligliptin therapy was well tolerated.25

Teneligliptin added to pioglitazone in patients with T2DM

Kadowaki et al evaluated the efficacy and safety of teneligliptin added to pioglitazone in patients with T2DM. Two hundred and four patients with T2DM receiving pioglitazone (15 mg/d or 30 mg/d) monotherapy for at least 12 weeks and reporting inadequate glycemic control (HbA1c 6.8%–10.3%) were randomized to receive teneligliptin 20 mg or a placebo through a multicenter, randomized, double-blind, placebo-controlled, parallel-group, Phase III clinical trial. All patients were continued on a stable dose of pioglitazone in addition to teneligliptin or a placebo. After 12 weeks of the double-blind period, all patients continued a 40-week open-label period during which they received teneligliptin 20 mg or 40 mg. At 12 weeks, teneligliptin reported a significant reduction in HbA1c of 0.9% compared to placebo of 0.2% (P<0.001). The trend of reduction in HbA1c continued further for 52 weeks. Patients who were receiving teneligliptin during a double-blind period and who further continued on teneligliptin (T/T) during an open-label period reported a reduction in HbA1c of 0.9% at 52 weeks. Patients who were receiving placebo during a double-blind period and who further continued on teneligliptin (P/T) during an open-label period reported reduction in HbA1c of 0.7% at 52 weeks. Teneligliptin reported more reduction in FPG compared to placebo (P<0.001) at 12 weeks, and this trend continued for 52 weeks. Slightly higher incidences of AE/ADRs were noted in teneligliptin group compared to placebo group at week 12. Gastrointestinal disorders and skin disorders were commonly reported AEs. Two patients (1.9%) reported hypoglycemia; however, all episodes of hypoglycemia were mild in severity. Incidences of peripheral edema were low in both the groups, and a slight increase in body weight was noted in both the groups. Thus, improvement in glycemic control was noted with addition of teneligliptin in patients with T2DM with inadequate glycemic control with pioglitazone.26

Teneligliptin added to insulin therapy in patients with T2DM

Efficacy of teneligliptin on glucose fluctuations in patients with T2DM was analyzed in a prospective, nonblinded, pilot study involving 26 patients. These patients were treated with diet and insulin therapy with or without other antidiabetic drugs for steady glycemic control in hospitalized setting. Continuous glucose monitoring was done successively for 7 days. For the first 3 days (days 1–3), patients received insulin with or without other antidiabetic drugs, and for the next 4 days (days 4–7), teneligliptin 20 mg once daily was added to existing therapy. Insulin dose was kept constant throughout the study period. Significant improvement in various glycemic parameters, such as 24-hour mean glucose levels, a proportion of time in normoglycemia, mean amplitude of glycemic excursions, and total area under the curve within 2 hours after each meal, was noted with the addition of teneligliptin. No significant increase in the proportion of time in hypoglycemia and high-sensitivity C-reactive protein levels was noted with the addition of teneligliptin. This study concluded that in patients with T2DM receiving insulin therapy, with or without other antidiabetic agents, the addition of teneligliptin reported significant improvement in diurnal glycemic control and significant reductions in glucose fluctuations in 24-hour periods without increasing the risk of hypoglycemia.27

Tolerability of teneligliptin

As mentioned earlier, teneligliptin was well tolerated in various clinical trials.22–27 Data from 1,183 patients reported that 118 (10%) patients experienced AEs, and the most common AEs were hypoglycemia (3%) and constipation (0.9%). Hypoglycemia can occur when other antidiabetic drugs are coadministered.5 Intestinal obstruction may occur with teneligliptin and must be administered cautiously in patients with a history of intestinal obstruction or surgery.5 This may be because of reduced gastrointestinal motility due to enhanced activity of incretins. Cases of intestinal obstruction were also reported with sitagliptin, vildagliptin, exenatide, and liraglutide.28

QT/QTc evaluation was studied for teneligliptin, this may be as a part of regular drug development program.5,29,30 Reported evidence suggests that no QT prolongations were noted with teneligliptin 40 mg daily dose. Nevertheless, mild and transient QTc prolongation can be seen at a supra-clinical dose of 160 mg/day given for a prolonged period.5,28 Therefore, caution is exercised if the drug needs to be used for a longer period of time in patients who are prone or have comorbid arrhythmia/ischemic heart disease and along with medications known for QT prolongation.5,31

Cardioprotective effects of teneligliptin were studied in a small group (n=29) of patients with T2DM with a high risk of chronic heart failure. Treatment with teneligliptin for 3 months reported improvements in left ventricular systolic and diastolic function, endothelial function, and an increase in circulating adiponectin levels.32 This evidence supports cardioprotective effects of teneligliptin.

Summary and expert opinion

Globally, prevalence of diabetes has reached an alarming stage with 415 million patients.1 This has a huge burden on public health system, and prompt intervention is required to reduce various short-term and long-term complications associated with diabetes. In this situation, the addition of newer and effective medicines is always welcomed.

Teneligliptin is a novel DPP-4 inhibitor developed in Japan and recently available in some countries and presently under development in many countries.5–7,18 Teneligliptin has a unique structure and binds to S1, S2, and S2 extensive subsite of DPP-4 enzyme leading to enhanced potency and selectivity.16,17 Once-a-day administration with maximum inhibition of DPP-4 enzyme within 2 hours and >50% inhibition has been noted at 24 hours; no drug–drug interaction and elimination by renal and hepatic route are some of the important clinically significant properties of teneligliptin.5,22

Teneligliptin was systematically studied in various patient profiles of T2DM as monotherapy and in combination with metformin, glimepiride, pioglitazone, and insulin.22–27 These studies included short-term studies for 12 weeks and long-term studies up to 52 weeks. These studies have reported a significant and clinically meaningful reduction of blood glucose with a reduction of HbA1c of 0.8%–0.9% in 12 weeks, which was maintained up to 52 weeks of teneligliptin therapy (Table 6). The landscape of these studies has also pointed out that teneligliptin can be safely used as monotherapy and a part of dual therapy.22–27

Table 6

Summary of some important teneligliptin studies

Study	Treatment arm	Design and duration (weeks)	Sample size	Mean change in HbA1c (%)
Patients with T2DM inadequately controlled with diet and exercise
Kadowaki and Kondo23	Teneligliptin 10 mg ODTeneligliptin 20 mg ODTeneligliptin 40 mg OD	DB, PL-controlled, MC, PG, RCT, 12 weeks	324	Teneligliptin 10 mg: −0.8%*Teneligliptin 20 mg: −0.8%*Teneligliptin 40 mg: −0.9%*
	Placebo OD			Placebo: 0.1%
Patients with T2DM inadequately controlled with metformin
Kim et al24	Metformina + teneligliptin 20 mg	DB, PL-controlled, MC, PG, Phase III, RCT, 16 weeks	204	Metformin + teneligliptin 20 mg: −0.87%**
	Metformina + placebo			Metformin + placebo: −0.06%
Patients with T2DM inadequately controlled with glimepiride
Kadowaki and Kondo25	Glimepirideb + teneligliptin 20 mg	DB, PL-controlled, MC, PG, Phase III, RCT, 12 weeks, followed by 40 weeks open-label extension:	194	At 12 weeks:Glimepiride + teneligliptin 20 mg: −0.7%Glimepiride + placebo: 0.3%
	Glimepirideb + placebo	Glimepiride + teneligliptin → glimepiride + teneligliptin 20 mgd (T/T)Glimepiride + placebo → glimepiride + teneligliptin 20 mgd (P/T)		At 52 weeks:Glimepiride + teneligliptin 20 mg (T/T): −0.6%***Glimepiride + teneligliptin 20 mg (P/T): −0.9%***
Patients with T2DM inadequately controlled with pioglitazone
Kadowaki and Kondo26	Pioglitazonec + teneligliptin 20 mg	DB, PL-controlled, MC, PG, Phase III, RCT, 12 weeks, followed by 40 weeks open-label extension:	204	At 12 weeks:Pioglitazone + teneligliptin 20 mg: −0.9%*Pioglitazone + placebo: −0.2%
	Pioglitazonec + placebo	Pioglitazone + teneligliptin → pioglitazone + teneligliptin 20 mgd (T/T)Pioglitazone + placebo → pioglitazone + teneligliptin 20 mgd (P/T)		At 52 weeks:Pioglitazone + teneligliptin 20 mg (T/T): −0.9%***Pioglitazone + teneligliptin 20 mg (P/T): −0.7%***

Notes:

Metformin dosage: ≥1,000 mg/d.

Glimepiride dosage: 1–4 mg/d.

Pioglitazone dosage: 15 mg/d or 30 mg/d.

Uptitrated to 40 mg if required. T/T, patients who were receiving teneligliptin during a double-blind period and who further continued on teneligliptin during an open-label period; P/T, patients who were receiving placebo during a double-blind period and who further continued on teneligliptin during an open-label period.

P<0.001 versus placebo;

P<0.0001 versus baseline;

P<0.001 versus baseline. Data from previous studies.23–26

Abbreviations: AC, active controlled; DB, double blind; DD, double dummy; MC, multicentric; NB, nonblind; OD, once daily; PG, parallel group; PL, placebo; RCT, randomized controlled trial; T2DM, type 2 diabetes mellitus.

Additionally, there are some signals of possible pleiotropic benefits of teneligliptin in terms of improvement in vascular endothelial function, body weight, and lipid levels.33 However, this needs to be confirmed in a well-designed systematic study. This drug is under development in the US and the UK, and it may be available in these countries in near future.18

Teneligliptin reported favorable tolerability with few AEs and is weight neutral. No dose adjustment is required in patients with any degree of renal impairment or ESRD and even in mild-to-moderate hepatic impairment.19,20 These are some unique and useful properties of teneligliptin.

Presently, no direct comparative study of teneligliptin with another DPP-4 inhibitor is reported; therefore, it is difficult to establish superiority or noninferiority of teneligliptin vis-a-vis with other DPP-4 inhibitors. Nevertheless, it is a welcome addition to the armamentarium of antidiabetic drugs available at a relatively affordable price. A systematic cost-effective analysis is required to analyze its economic benefits versus other available antidiabetic therapies.

This drug is recently approved, and therefore, long-term safety studies including cardiovascular safety studies are still awaited and required. However, current data of teneligliptin do not point any signal for serious adverse effect.31,32 Current evidence from short-term and small sample size studies supported cardioprotective effects of teneligliptin, which needs to be confirmed in the large randomized long duration study. The majority of studies involved Japanese and Korean (Asian) patients of T2DM, and clinical evidence in another population is missing and required. A properly designed, large, global, long-term safety study of teneligliptin is required.

Conclusion

Teneligliptin is a newer DPP-4 inhibitor in the management of T2DM. It provides clinically significant glycemic control within 12 weeks of therapy, which was maintained up to 52 weeks of therapy with favorable tolerability. It is useful as monotherapy and in combination with other antidiabetic drugs. It can be used in T2DM patients with renal impairment and mild-to-moderate hepatic impairment and thus has a unique place in therapy.