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. Author manuscript; available in PMC: 2010 Sep 1.
Published in final edited form as: Postgrad Med. 2009 Sep;121(5):94–107. doi: 10.3810/pgm.2009.09.2056

The Impact of Weight Gain on Motivation, Compliance, and Metabolic Control in Patients with Type 2 Diabetes Mellitus

F Xavier Pi-Sunyer 1
PMCID: PMC2879281  NIHMSID: NIHMS197031  PMID: 19820278

Abstract

Patients with type 2 diabetes, approximately 85% of whom are overweight or obese, often have an increased incidence of cardiovascular disease (CVD) risk factors such as hypertension and dyslipidemia. Both type 2 diabetes and obesity are independent risk factors for CVD. Unfortunately, many therapies aimed at maintaining and improving glucose control are associated with weight gain. Among the older antidiabetes agents, most, including the insulin secretagogues and sensitizers, can lead to weight gain, except for metformin, which is weight-neutral. Among the newer agents, the dipeptidyl peptidase-4 inhibitors generally are weight-neutral in addition to lowering glucose, while the glucagon-like peptide–1 receptor agonists lead to weight reduction. Patients with type 2 diabetes are at an increased risk for both diabetes-and CV-related outcomes, and weight reduction is an important component of diabetes management. Weight gain in patients with type 2 diabetes can contribute to patient frustration and may negatively impact their compliance to therapeutic regimens. The selection of antidiabetes agents that not only improve glucose control but reduce or have a neutral effect on weight with beneficial effects on lipids are ideal options for managing patients with type 2 diabetes.

Keywords: type 2 diabetes mellitus, weight gain, obesity, cardiovascular disease, incretin therapy, exenatide

Introduction

Type 2 diabetes mellitus, the predominant form of diabetes, is a complex metabolic disorder characterized by hyperglycemia and inextricably linked to both weight gain and cardiovascular disease (CVD). Obesity, which is an independent CV risk factor in itself, is also a factor in the recent increase of newly diagnosed diabetes.1 This review examines the impact of weight gain on the motivation, compliance, and management of patients with type 2 diabetes. Additionally, based on a systematic review of clinical studies, it will provide an overview on the effects of currently approved and future therapies on weight in patients with type 2 diabetes.

Weight Gain/Obesity and CVD Risk in Type 2 Diabetes

According to the Centers for Disease Control and Prevention, 85% of patients with diabetes (of which type 2 diabetes accounts for > 90%) are overweight or obese.2,3 The growing prevalence of excessive visceral obesity and CV risk factors is associated with the increased incidence of type 2 diabetes and CVD.4,5 In fact, the term “diabesity” was coined several decades ago to underscore the strong link between diabetes and obesity,6,7 which are both associated with increased CV risk.8

The Framingham Heart Study showed that weight gain is independently associated with increased CV risk, morbidity, and mortality.9 Weight gain over the 26-year follow-up, that could not have resulted from initial patient weight or the levels of risk factors, was predictive of CVD in both men and women.9 Estimates have shown that a 5-kg weight gain in a man can increase coronary heart disease (CHD) risk as much as 30%.10 Data from the original and offspring cohorts of the Framingham study showed a high lifetime risk of CVD in men and women with diabetes, which was further increased by obesity. The 30-year risk of developing CVD among patients who were obese and had diabetes was 78.8% in women and 86.9% in men.8

A recent Swedish National Diabetes Register study showed that both overweight and obesity independently increase the risk of CVD in patients with type 2 diabetes.11 Analysis of data among overweight/obese type 2 diabetes patients who gained weight during the study showed a 13% increased risk of fatal and nonfatal CHD per 1 unit increase in body mass index (BMI).

Glucose-Lowering, CVD, and Weight: Lessons From Recent Large-Scale Trials

Hyperglycemia, due to type 2 diabetes, is an independent risk factor for CV morbidity and mortality.12,13 The benefits of intensive glycemic control in reducing the risk of microvascular complications have been demonstrated conclusively in several type 2 diabetes CV outcomes studies.14,15 However, the effects of intensive glucose control on macrovascular complications (eg, myocardial infarction, heart failure, stroke) is not as clearly understood.1517 Data from recently published Action in Diabetes and Vascular Disease: Preterax and Diamicron Modified-Release Controlled Evaluation (ADVANCE)17 and Action to Control Cardiovascular Risk in Diabetes (ACCORD)16 trials have shown inconsistent results regarding the effect of intensive glucose lowering on macrovascular complications.16,17 Approximately one-third of the patients in these studies had concomitant CVD.16,17

While intensive glucose control (defined as the use of the modified-release sulfonylurea, gliclazide, or other agents to achieve a hemoglobin AIC [Hb AIC] ≤ 6.5%) in the ADVANCE study (which had a 5-year median follow-up) was associated with a reduced incidence of major microvascular events and combined major microvascular and macrovascular events, there was no statistically significant difference between groups in the incidence of major macrovascular events, CV-related death, or all-cause mortality.17

In contrast, the ACCORD study found an increased risk of all-cause mortality in patients randomized to intensive therapy (ie, target HbAlc of < 6%), resulting in early termination of this study arm with a shift to standard therapy (ie, target HbAlc of 7%–7.9%) prior to the scheduled end of the study.16 Intensive treatment, over a 3.5-year mean follow-up, was associated with higher rates of CV death but a lower rate of nonfatal myocardial infarction, which led to a nonsignificant decrease in the primary outcome after 3 years.

An analysis to explore the relationship between hypoglycemia and mortality outcomes in ACCORD showed a statistically significant difference between the overall 1.22-fold increase in mortality and the 0.52-fold adjusted mortality ratio in intensive therapy patients who had severe hypoglycemia.18 However, since there was no systematic analysis or collection of low glucose concentrations other than the severe hypoglycemia defined in the study, it was concluded that severe hypoglycemia was not related to the higher mortality. Patients in the intensive treatment group also demonstrated a considerable increase in weight (27.8% gained > 10 kg with a mean gain of 3.5 kg at 3 years). This increase in weight may be attributed to the frequent use of thiazolidinediones (TZDs) (almost entirely rosiglitazone) and insulin.19 It remains undetermined, however, whether the patients with large increases in weight experienced higher rates of clinical events than patients with less weight gain.19

Reduction in Weight and CVD Risk Factors in Patients with Type 2 Diabetes

The Look AHEAD (Action for Health in Diabetes) study suggests that weight reduction in patients with type 2 diabetes is related to improvement in type 2 diabetes and CVD risk factors. One-year data showed that 37.8% of patients in the intensive lifestyle improvement (ILI) group and 3.2% of patients in the diabetes support and education group lost > 10% of their initial weight, with noninsulin users being more likely to achieve weight loss goals.20 The percentage of participants in the ILI group who attained the American Diabetes Association (ADA) HbAlc goal of < 7% increased from 46% to 73%. The decline in fasting serum glucose and HbAlc occurred despite the fact that these patients decreased their use of glucose-lowering medications. Additionally, there was a doubling in the percentage of patients in this group who met the ADA target goals for blood pressure (BP) and lipids. Results from Look AHEAD complement the data from the United Kingdom Prospective Diabetes Study (UKPDS) and the Steno-2 study regarding the benefits of a multifactorial treatment approach (including control of HbAlc, BP, and lipids).15,2022

Current treatment guidelines highlight the importance of weight management for patients with type 2 diabetes.2326 A position statement from the ADA, in conjunction with the North American Association for the Study of Obesity and the American Society for Clinical Nutrition, recognizes that even a modest weight loss (5% of body weight) can lead to improvement in insulin action, reduced fasting blood glucose concentrations, and decreased need for diabetes medications.26

The ADA recommends that weight loss programs include reduced carbohydrate and fat intake, increased physical activity, and lifestyle modifications.24,25 Patients with a BMI > 25 kg/m2 should try to reduce their BMI to ≤ 25 kg/m2. Patients with a BMI between 20 kg/m2 and 25 kg/m2 should maintain their present weight.27 Other specific recommendations include limiting saturated fat intake to < 7% of total calories and minimizing trans-fat intake. Carbohydrate intake should be monitored, and use of the glycemic index or glycemic load may be considered.24 Patients should be encouraged to perform ≥ 150 minutes of moderate-to-intense aerobic exercise and, in the absence of contraindications, resistance training 3 times per week.25 Consideration should be given to weight loss medications (combined with lifestyle modification) or bariatric surgery in overweight/obese patients in need of greater weight reduction.24

Benefits of weight reduction in overweight/obese patients with type 2 diabetes have been demonstrated in diet therapy and gastric banding studies. One study found that modest weight reduction with very-low energy diets was associated with a decrease in fasting plasma glucose (Figure 1), and significantly greater reductions correlated with increased weight loss.10 In another study, weight loss was associated with long-term improvements in CV risk factors in obese patients with type 2 diabetes who underwent laparoscopic gastric banding. One year after surgery, patients demonstrated a 43% reduction in triglyceride, an 18% increase in high-density lipoprotein cholesterol (HDL-C), improved BP control, and a reduced need for antihypertensive medications.28 Dixon et al28 reported remission in diabetes in these patients following weight loss via improved insulin sensitivity and β-cell function.

Figure 1.

Figure 1

Effects of weight loss (with very low-energy diets) on fasting plasma glucose in patients with obesity and type 2 diabetes mellitus.

Values (with SEM bars) are expressed as percentages of baseline values. Baseline fasting plasma glucose values were 14 mmol/L (95% confidence interval, 12–15.9 mmol/L).

Mean values from 10 studies including 152 subjects.

Reprinted with permission from J Am Coll Nutrition.10

Abbreviation: SEM, standard error of the mean.

Weight management is an ongoing challenge for patients with type 2 diabetes.29 Intensive lifestyle management and weight loss have positive short-term effects on decreasing CV risk, while nutritional education and counseling have low compliance rates, thus making long-term effects difficult to achieve.3032

Reviewing the Evidence: Weight, Motivation, Adherence, and Compliance in Patients with Type 2 Diabetes

One of the factors related to the success of weight loss programs and the pharmacologic management of type 2 diabetes is patient adherence and compliance.32 Many factors may affect the degree of adherence and compliance, including demographic, psychological, social, health care system, and disease-related factors. Knowledge of a patient’s disease and reasons for the treatment regimen may be lacking; family problems or psychological disorders may affect the patient’s ability to effectively manage their disease, or patients may become overwhelmed and feel they do not have the ability to succeed.32

Diabetes is largely a self-managed and self-monitored disease requiring patient motivation for successful health management.32 Therefore, the concept of patient compliance and adherence should be considered as it pertains to this population and management model. While compliance is described as the extent to which patients follow medical advice, adherence has been defined as active and voluntary patient involvement and a collaborative relationship with their provider to achieve disease management goals.

Motivation is an important tool in the management of patients with type 2 diabetes.33,34 Self-care behaviors play a major role in diabetes control and may be negatively impacted by patient apathy, which is characterized by lack of motivation and initiative.35 Motivated patients are aware of the importance of taking their medication as directed to control their diabetes and to prevent the onset of complications.34 A 12-month study showed that when patients with diabetes perceived their physicians as being autonomy supportive, the patients became more motivated to regulate their diet and exercise regimens, felt more compelled to manage their diabetes, and had significant (P < 0.001) reductions in HbAlc.36 Williams et al37 also showed that autonomy support of patients with diabetes by primary care physicians was related to perceived competence, depressive symptoms, patient satisfaction, and glycemic control. Results from recent research by Daly et al33 showed that family support, physician-patient communication, diabetes knowledge, and motivation and confidence to manage diabetes were keys to self-care behaviors for patients with type 2 diabetes.

It should also be considered that, while patients may not adhere to some aspects of their regimen, they may adopt other components. For diabetes management to be successful and patients to remain adherent, a collaborative care model, where patients are actively involved in setting their goals based on their willingness to change, and ongoing support and motivation are provided by the healthcare team, may be the best approach.32

The Diabetes Attitude, Wishes, and Needs (DAWN) study examined regimen adherence in patients with diabetes and the effect of psychosocial barriers.38 Among patients with type 2 diabetes, there was a 78% rate of medication adherence and a 72% rate of appointment keeping; however, adherence to diet and exercise was low (37% and 35%, respectively). Another study found that persistency rates for type 2 diabetes patients taking oral antidiabetes medications were approximately 68% at 1 year. Lack of adherence had a negative effect on outcomes with the nonpersistent use of oral antidiabetes agents leading to a 20% decrease in probability of attaining HbAlc goals in patients with type 2 diabetes.39

Analysis of data from an open-label, randomized clinical trial showed no significant differences in treatment satisfaction among patients with type 2 diabetes who received either biphasic or basal insulin analogs.40 Most (81%) of the 197 patients who completed the treatment satisfaction assessment did not change their weight status (normal, overweight, or obese), and no significant relationship between change in BMI classification and treatment satisfaction was found. However, there was a systematic improvement in treatment satisfaction across all scores among the 14.5% of patients in whom BMI was reduced, although the only statistically significant (P < 0.05) difference was in the lifestyle flexibility subscale.40

Sacco et al41 studied the impact of depression on the development and worsening of type 2 diabetes using the hypothesis that diabetes symptoms mediate the effect of behavioral adherence and BMI on depression. Patients were assessed for depression using the Patient Health Questionnaire: Nine Symptom Depression Checklist, and for self-efficacy by the diet, exercise, and weight control items of the Multidimensional Diabetes Questionnaire self-efficacy subscale (using a scale of 0 to 100, patients assess their confidence in following their diet and exercise regimen). Results suggest there are 2 independent pathways by which BMI and adherence could impact depression in patients with type 2 diabetes. The first pathway suggests the effects of higher BMI and poor adherence are mediated by lower self-efficacy perceptions, while the second pathway indicates that the effects of higher BMI on depression are mediated by increased diabetes symptoms. While causality cannot be established, these findings may help to explain why overweight/obese individuals with type 2 diabetes are predisposed to experience weight-related negative, self-relevant cognition, medical symptoms, and depression.41

Weight gain can contribute significantly to the frustration patients feel with their current antidiabetes therapies and may contribute to early discontinuation or decreased adherence.42,43 Many established antidiabetes regimens, including insulin secretagogues (eg, sulfonylureas, meglitinides) and insulin sensitizers or insulin-sparing agents (eg, TZDs) are associated with weight gain.6,44 The UKPDS showed that, during the first 12 months of therapy, intensive treatment regimens resulted in better glucose control than conventional interventions, but were associated with significantly (P < 0.0001) greater increases in weight.15,42 Patients may not want to take medications knowing there is a potential for weight gain to begin therapy as they are concerned about the adverse effects.42,43 The initiation of appropriate therapies, such as insulin, may be delayed due to patient fear of weight gain; this may lead to noncompliance while the patient is receiving therapy, leading to poor glucose control.

In patients with type 2 diabetes, weight loss has been associated with improvements in sleep, mental health, appearance evaluation, and health-related quality of life, which demonstrate improved psychosocial health.28 Results from a patient-reported outcomes study suggested that the increased efficacy, and potential for weight reduction, provided by the addition of injectable medications to patients inadequately controlled on oral agents may lead to improved patient outcomes including treatment satisfaction and quality of life.45 These improvements, which have the potential to motivate patients and improve the persistency of therapy, indicate an important place in therapy for effective antidiabetes agents with weight-neutral or weight-reducing effects.6

Reviewing the Evidence: Effects of Antidiabetes Agents on HbAlc, Weight, and Lipids

A literature search was conducted for primary studies on the antidiabetes agents glimepiride, metformin, acarbose, pioglitazone, rosiglitazone, repaglinide, nateglinide, and sitagliptin (all oral), and insulin glargine, insulin aspart, insulin detemir, pramlintide, exenatide, and liraglutide (all parenteral) to specifically examine the effects of antidiabetes therapies on weight in patients with type 2 diabetes. Dates were generally limited to 2005 through 2008 (except for an extension to 2004 in the case of the meglitinides repaglinide and nateglinide for lack of better data using the original search timeframe). Head-to-head studies and/or monotherapy studies were preferred as appropriate, and keywords focused on the generic names of the agents (which were either approved by the US Food and Drug Administration or already had a new drug application filing at the time of the writing of this review) and “weight.” The comparison focused on data related to HbAlc, weight effects, and lipids. Findings related to HbAlc, weight, and lipids among the oral antidiabetes agents are summarized in Table 1,4661 corresponding data with parenteral therapies are outlined in Table 2.47,48,52,57,6278

Table 1.

Summary of Clinical Data Evaluating the Effects of Oral Antidiabetes Agents on HbAlc Weight, and Lipid Parameters in Patients with Type 2 Diabetes

Agent Study Patient Population
Randomized to
Treatment Arm (n)
Dosage HbAlc, Percent
Change From
Baseline in
Absolute Units
Weight, kg
Change From
Baseline
Lipids, Change
From Baseline
Glimepiride Yamanouchi
200560
37 (treatment-naïve
to OAD)
Glimepiride
1–2 mg/day
for 12 mo
−2.1a −0.2 (BMI) (mmol/L)
TC, −0.19;
HDL-C.−0.01;
TG, 10.05
Nauck
200952
244 Glimepiride
(in combination with
metformin) 4 mg/day
for 26 wk
−1.0 +1.0 NR
Garber
200948
(LEAD-3)
248 (receiving OAD
plus diet/exercise)
Glimepiride 8 mg/day
for 52 wk
−0.51 +1.02 NR
Metformin Yamanouchi
200560
39 (treatment-naïve
to OAD)
Metformin
750 mg/day
for 12 mo
−2.1a −0.7 (BMI) (mmol/L)
TC. −0.18;
HDL-C. −0.01;
TG, −0.09
Yilmaz
200761
17 (receiving insulin) Metformin
1700 mg/day
for 6 mo
−2.0a +1.4 (mg/dL)
TC, −2.3;
LDL-C, +2.2;
HDLC, −0.1;
TG, −16.5a
Kawai
200849
35 (Japanese patients
who received metformin
500–750 mg/day
for 12wk)
Metformin
500–750 mg/day
for 6 mo
−0.1 +0.1 (mg/dL)
TC, +0.9;
HDL-C, +0.2;
TG, −6.0
Kusaka
200350
17 (Japanese patients
treated with diet/exercise
alone or with glimepiride
2 mg/day)
Metformin 750 mg/day
for 4 mo
−1.0a No change (BMI) (mmol/L)
LDL-C, −0.3;
HDL-C. no change:
TG, +0.2
Acarbose Yilmaz
200761
15 (receiving insulin) Acarbose
300 mg/day for 6 mo
−0.6a +2.7 (mg/dL)
TC, −2.3;
LDL-C, +6.9;
HDL-C+1.7;
TG, −27.4a
Pan 200853 220 (treatment-naïve) Acarbose ≤ 300 mg/day
for 24 wk
−1.3 −1.7 NR
Pioglitazone Yamanouchi
200560
38
(treatment-naïve to
OAD)
Pioglitazone
30–45 mg/day for
12 mo
−2.3a +0.9 (BMI) (mmol/L)
TC, −0.23;
HDL-C, +0.11;
TG, −0.39
Kawai
200849
28 (Japanese patients
who received metformin
500–750 mg/day for 12 wk)
Pioglitazone
15 mg/day for 6 mo
-1.2a +2.2a (mg/dL)
TC, + 1.5;
HDL-C, +5.6a;
TG.-13.5
Kusaka
200850
16 (Japanese patients
treated with diet/exercise
alone or with glimepiride
2 mg/day)
Pioglitazone 15 mg/day
(women) or 30 mg/day
(men) for 4 mo
−1.1a +0.9a (BMI) (mmol/L)
LDL-C, no change;
HDL-C, +0.2;
TG, +0.2
Miyazaki
200851
21 (treatment-naïve or
receiving sulfonylurea)
Pioglitazone 45 mg/day
for 3 mo
−1.3a +2.7a (mg/dL)
LDL-C, +1.0a;
HDL-C, +2.0;
TG, −47.0a
Rosiglitazone Rosen stock
200657
112 (insulin-naïve;
receiving sulfonylurea
plus metformin)
Rosiglitazone 4 mg/day
for 24 wk
−1.51 +3.0 (mg/dL)
TC,+19.0;
LDL-C, +14.0;
HDL-C, +4.4%;
TG, +11.0
Yilmaz
200761
15 (receiving insulin) Rosiglitazone 8 mg/day
for 6 mo
−2.5a +4.6 (mg/dL)
TC, −12.5;
LDL-C, −11.9;
HDL-C. +3.3;
TG, −29.7a
Miyazaki
200851
37 (treatment-naïve or
receiving sulfonylurea)
Rosiglitazone 8 mg/day
for 3 mo
−1.4a +2.9a (mg/dL)
LDL-C. +15.0a;
HDL-C, +4.0;
TG, −8.0a
Scott
200859
87 (receiving metformin) Rosiglitazone 8 mg/day
for 18 wk
−0.79 +1.5 (mg/dL, at wk 24)
TC, +26.2;
LDL-C, +20.4;
HDL-C, +3.5;
TG.-1.8
Repaglinide Rosenstock
200456
76 (treated with diet/
exercise for previous
3 mo)
Repaglinide
0.5–4.0 mg/meal
for 16 wk
120 mg/meal for 16 wk
−1.57a +1.8 NR
Nateglinide Rosenstock
200456
74 (treated with diet/
exercise for previous
3 mo)
Nateglinide
60–120 mg/meal for
16 wk
−1.04 +0.7 NR
Sitagliptin Aschner
200646
467 (not receiving an
OAD)
Sitagliptin
100–200 mg/day
for 24 wk
−0.61 to −0.76a −0.1 to −0.2 NR
Raz 200654 392 (uncontrolled by
diet/exercise)
Sitagliptin
100–200 mg/day
for 18 wk
−0.36 to −0.48a −0.2 to −0.6 NR
Rosenstock
200658
175 (added to
pioglitazone)
Sitagliptin
100 mg/day plus
pioglitazone for 24 wk
−0.85a +1.8 (mg/dL)
TC, +1.7;
LDL-C, +1.2;
HDL-C,+0.1;
TG, −1.1
DeFronzo
200847
61 (receiving metformin) Sitagliptin
100 mg/day for 2 wk
(then crossover to
exenatide)
−19 (FPG, mg/dL) −0.3 NR
Raz 200855 96 (receiving metformin
for > 6 wk)
Sitagliptin 100 mg/day
for 30 wk
−1.0a −0.5 No significant
between-group
differences in TC,
LDL-C, HDL-C
Scott
200859
94 (receiving metformin) Sitagliptin 100 mg/day
for 18 wk
−0.73 −0.4 (mg/dL, at wk 24)
TC +8.1;
LDL-C, +9.2;
HDL-C, +1.8:
TG, −14.5
a

P < 0.05.

Abbreviations: BMI, body mass index; FPG. fasting plasma glucose: HDL-C. high-density lipoprotein cholesterol; LEAD. Liraglutide Effects and Actions in Diabetes; LDL-C, low-density lipoprotein cholesterol: NR, not reported; OAD. oral antidiabetes (agent); TC. total cholesterol; TG, triglyceride.

Table 2.

Summary of Clinical Data Evaluating the Effects of Parenteral Antidiabetes Agents on HbAlc, Weight, and Lipid Parameters in Patients with Type 2 Diabetes

Agent Study Patient Population
Randomized to
Treatment Arm (n)
Dosage HbAlc, Percent
Change From
Baseline in
Absolute Units
Weight, kg
Change From
Baseline
Lipids, Change From
Baseline
Insulin
Glargine
Heine 200567 260 (uncontrolled
by metformin plus
sulfonylurea)
Insulin glargine QD
titrated to
FBG < 5.6 mmol/L
for 26 wk
−1.11 +1.8 NR
Rosenstock
200657
104 (insulin-naïve;
receiving sulfonylurea
plus metformin)
Insulin glargine
10 U/day titrated
to FPG of
5.5–6.7 mmol/L for
24 wk
−1.66 +1.7 (mg/dL)
TC, -10.0;
LDL-C, -2.0;
HDL-C, no change;
TG, -4I.0
Barnett 200762 70 in insulin glargine/
exenatide group
(receiving a single
OAD)
Insulin glargine QD
titrated to
FSG < 5.6 mmol/L
for 16 wk (then
crossover to
exenatide)
−1.36a +1.0 in 1st
period and
+2.3 in 2nd
period
NR
Fakhoury
200866
869 (uncontrolled by
OAD)
Insulin glargine
23–68 IU/day for
24 to 52 wk
−0.76 to −2.36 +2.57 to +3.7 NR
Insulin
Aspart
Nauck 200773 248 (receiving
metformin plus a
sulfonylurea)
Biphasic insulin
aspart 30/70
BID for 52 wk
−0.89a +2.9a Greater increase in HDL-C
with insulin aspart (LS mean,
exenatide minus
insulin, −0.04 mmol/L;
P = 0.003; absolute values NR)
Insulin
Detemir
Fakhoury
200866
169 (uncontrolled
by OAD)
Insulin detemir
mean dose of
37 IU/day for
20 wk
−1.48 +0.69 NR
Pramlintide Karl 200768 166 (uncontrolled
by insulin)
Pramlintide
120 µg BID or TID
for 6 mo
−0.56a −2.8a NR
Riddle 200774 105 (uncontrolled
by insulin glargine
with or without an
OAD)
Pramlintide 60 or
l20 µg BID or TID
for 16 wk
−0.7a −1.6a NR
Exenatide
BID
DeFronzo
200564
223 (receiving
metformin)
Exenatide 5–10 µg
BID for 30 wk
−0.40 to −0.78a −1.6 to −2.8a NR
Heine 200567 275 (uncontrolled
by metformin plus a
sulfonylurea)
Exenatide 10 µg
BID for 26 wk
−l.11 −2.3 NR
Kendall 200569 486 (receiving
metformin plus a
sulfonylurea)
Exenatide 5–10 µg
BID for 30 wk
−0.55 to −0.77a −1.6a NR
Barnett 200762 68 in exenatide/insulin
glargine group
(receiving a single
OAD)
Exenatide 10 µg
BID for 16 wk
(then crossover to
insulin glargine)
−1.36a −2.0 in 1st
period and
−2.2 in 2nd
period
NR
Nauck 200773 253 (receiving
metformin plus a
sulfonylurea)
Exenatide 5 µg BID
for 4 wk then 10
µg BID for 48 wk
−1.04a −2.5a Greater increase in HDL-C
with insulin aspart (LS mean,
exenatide minus insulin,
−0.04 mmol/L;
P = 0.003; absolute values NR)
Zinman 200777 121 (uncontrolled by
a thiazolidinedione
with or without
metformin)
Exenatide 10 µg
BID for 16 wk
−0.89a −1.75 NR
DeFronzo
200847
61 (receiving met-
formin)
Exenatide 5 µg
BID for 1 wk then
10 µg BID for 1 wk
(then crossover to
sitagliptin)
-15
(FPG, mg/dL)
−0.8a NR
Drucker 200365 148 (uncontrolled by
OAD with or without
diet/exercise)
Exenatide 10 µg
BID for 30 wk
−1.5a −3.6 (mmol/L)
TC, −0.1;
LDL-C, +0.03;
HDL-C, −0.03;
TG, −11%
Klonoff 200871 217 (uncontrolled by
metformin with or
without a sulfonyl
urea)
Exenatide 5 µg
BID for 4 wk then
10 µg for up to
3.5 y
−0.8a −5.3a (mg/dL)
TC, −10.81a;
LDL-C, −11.8a;
HDL-C, +8.5a;
TG, −44.1a
Exenatide
Once
Weeklyb
Kim 200770 31 (uncontrolled by
metformin with or
without diet/exercise)
Exenatide 0.8 to
2.0 mg/wk for
15 wk
−1.4 to −1.7a −3.8a (with
2.0 mg/wk
dose)
NR
Drucker 200865
(DURATION-1)
147 (uncontrolled by
OAD With or without
diet/exercise)
Exenatide 2 mg/wk
for 30 wk
−1.9a −3.7 (mmol/L)
TC, −0.31;
LDL-C, −0.13;
HDL-C, −0.02;
TG, −15%
Bergenstal
200863
120 (52-wk data of
DURATION-I)
Exenatide 2 mg/wk
SC for 52 wk
−2.0 −4.1 (mg/dL)
TC, −7.9;
LDL-C, −2.2;
HDL-C, −0.3;
TG, −40.1
Liraglutideb Vilsbøll 200776 123 (as monotherapy) Liraglutide 0.65,
1.25, 1.90 mg QD
SC for 14 wk
−0.98 to −1.45 −2.99
(1.90 mg dose)
No consistent changes among
treatment in TC, LDL-C,
HDL-C (no data shown)
Seino 200875 180 (Japanese
patients)
Liraglutide
0.1−0.9 mg/day
SC for 14 wk
−0.72 to −1.67 +0.13 to −0.48 NR
Garber 200948
(LEAD-3)
498 (receiving an
OAD plus diet/exercise)
Liraglutide
1.2–1.8 mg/day for
52 wk
−0.84 to −1.14 −2.0 to −2.5a NR
Marre 200972
(LEAD-I)
695 (added to
sulfonylurea)
Liraglutide 0.6, 1.2,
1.8 mg QD SC for
26 wk
−1.1a +0.7 to −0.2 NR
Nauck 200952
(LEAD-2)
725 (plus metformin) Liraglutide
0.6–1.8 mg/day for
26 wk
−0.7 to −1.0a −1.8 to −2.8a NR
Zinman 200978
(LEAD-4)
356 (in combination
with metformin and
rosiglitazone)
Liraglutide
1.2–1.8 mg/day
for 26 wk
−1.5 −1.0 to −2.0 (mmol/L)
TC, −0.20 to −0.21;
LDL-C, −0.23 to −0.28a;
HDL-C, −0.03 to −0.04;
TG, −0.32 to −0.38a
a

P < 0.05.

b

Not currently approved by the US Food and Drug Administration; undergoing regulatory review.

Abbreviations: DURATION-1, Diabetes Therapy Utilization; Researching Changes in AIC, Weight and Other Factors Through Intervention with Exenatide Once Weekly-1; FBG, fasting blood glucose; FPG, fasting plasma glucose; FSG, fasting serum glucose; HDL-C, high-density lipoprotein cholesterol; LEAD, Liraglutide Effects and Actions in Diabetes; LDL-C, low-density lipoprotein cholesterol: LS, least squares: NR, not reported; OAD, oral antidiabetes (agent); SC, subcutaneous: TC, total cholesterol; TG, triglyceride.

Findings in the data review of newer agents and their effects on weight and other CV risk parameters are consistent with and confirm findings from previous reports. Most antidiabetes agents result in weight gain or are weight-neutral despite attempts at lifestyle and diet modification interventions.44 In a 2003 literature review of the effects of antidiabetes agents on weight, insulin, sulfonylureas, and TZDs were associated with increases in BMI and weight gain while biguanides, such as metformin, and α-glucosidase inhibitors, such as acarbose, had a weight-neutral effect.44

A recently published review of newer classes of oral/injectable antidiabetes agents, including the dipeptidyl peptidase–4 (DPP-4) inhibitors, as monotherapy or in combination, reported this class of agents to be weight-neutral and to have no effects on lipid profiles.79 In a review by Bolen et al,80 findings confirm that the majority of available oral antidiabetes agents cause a weight increase of 1 to 5 kg, with the exception of metformin, which does not affect weight in either direction. In addition, effects on lipids were compared with TZDs increasing low-density lipoprotein cholesterol (LDL-C), as well as HDL-C. Metformin has been found to decrease LDL-C while the other agents had no significant effect on LDL-C.80 Rosiglitazone was the only oral agent shown to increase triglycerides.80

The current review expands on the findings of previous studies and provides new insights by including additional data from trials of the newer antidiabetes agents, such as incretin-based therapies—the parenterally administered (ie, subcutaneously) glucagon-like peptide–1 (GLP-I) receptor agonists and the oral DPP-4 inhibitors. Increases in body weight were greatest among patients treated with pioglitazone, rosiglitazone, and insulin glargine. Consistent with the findings of earlier studies, including studies in which these drugs were used as add-on therapy,58,81 the DPP-4 inhibitors (ie, sitagliptin) were found to be generally weight-neutral. The largest reduction in body weight from a therapy prescribed to manage hyperglycemia in patients with type 2 diabetes was seen with the GLP-I receptor agonists (eg, exenatide produced weight reductions ranging from −1.6 kg at 12 weeks to −5.3 kg at 3.5 years).71

Exenatide may be helpful in patients with the metabolic syndrome because of its effects on glycemic control and other surrogates of CV risk, including weight, BP, and lipids.82 The effects of long-term exenatide therapy on diabetes, obesity, CV risk factors, and hepatic markers were assessed in an open-ended, open-label clinical trial in patients with type 2 diabetes,71 All patients received exenatide 10 µg twice daily for ≥ 3 years. Patients demonstrated significant reductions in HbAlc and fasting glucose as early as week 12 and these were sustained throughout the study. In patients who completed 3 years of therapy, HbAlc was significantly (P < 0.0001) reduced by −1% (46% of patients had an HbAlc ≤ 7%), and fasting plasma glucose was reduced by −23.5 mg/dL. For patients who continued therapy, exenatide was associated with a significant and progressive reduction in weight (Figure 2): −1.6 kg at 12 weeks, −2.1 kg at 30 weeks, −4.7 kg at 2 years, and up to −5.3 kg at 3.5 years (P < 0.0001).71 A total of 84% of patients lost weight over the 3-year follow-up and 50% lost ≥ 5% of baseline body weight.

Figure 2.

Figure 2

Progressive reductions in weight from baseline (P < 0.0001) in patients with type 2 diabetes treated with exenatide 10 µg twice daily.

Abbreviation: CI, confidence interval.

Reprinted with permission from Curr Med Res Opin.71

There are other advances in incretin-based therapies. The DPP-4 inhibitor vildagliptin is approved for use in the European Union and Latin America. Other DPP-4 inhibitors under development or being investigated include alogliptin and saxagliptin.83 Among the GLP-I receptor agonists, a new once-weekly formulation of the currently approved agent exenatide is being investigated in phase III clinical trials, as is liraglutide, an agent which is projected to be administered once daily.83 To date, there have been several published studies for both once-weekly exenatide63,65,70 and once-daily liraglutide (Table 2).48,52,72,75,76,78

Integrated Approach to Antihyperglycemic and CV Risk Factor Management in Type 2 Diabetes

According to data from the National Health and Nutrition Examination Survey (NHANES) between 1993 and 2004, only approximately 13% of adult US patients with diagnosed diabetes achieved target goals for HbAlc, BP, and lipids concurrently. The majority of these patients were overweight or obese.2,84 Unfortunately, most of the traditional hypoglycemic agents for patients with type 2 diabetes are associated with weight gain.44 Weight gain can lead to therapeutic noncompliance and, when extreme, further increase CV risk in a population that already has increased potential for adverse events.30 An open-label study to assess treatment satisfaction was conducted in patients not reaching glycemic targets with insulin who were given adjunctive pramlintide. Treatment satisfaction was highest in patients who reported better clinical outcomes, including improved glycemic control, weight loss, and reduced insulin requirements.85

The comprehensive and goal-oriented management of type 2 diabetes and associated CV risk factors is warranted. When selecting treatment regimens, the focus should not be solely on glucose-lowering effects but also on nonglycemic factors such as weight and other CV risk factors, as well as ease of use, tolerability, and long-term adherence.30 Although lifestyle interventions themselves have failed to show long-term success, lifestyle changes, including increased physical activity and weight reduction, should be part of the management program of patients with type 2 diabetes and reinforced every visit.24,30 The incorporation of appropriate therapies to improve risk factors for diabetes and CV-related events should enhance clinical outcomes of patients with type 2 diabetes.30,86 Given that weight management is an important part of treating patients with type 2 diabetes and given the challenges these patients face in reducing and/or maintaining their weight, agents, such as incretin-based therapies, that can provide beneficial effects on both glucose and weight, represent an important addition to the antidiabetes armamentarium.24,82

Conclusion

Weight reduction remains a significant challenge in patients with type 2 diabetes, the majority of whom are overweight or obese. Additionally, weight gain associated with antidiabetes medications may increase CV risk and reduce adherence to therapy. Weight loss has been associated with improvements in mental health, self-evaluation of appearance, and health-related quality of life in patients with type 2 diabetes, as well as correlated with patient-reported treatment satisfaction. Patient motivation coupled with safe and effective treatment is critical to achieving optimal management of type 2 diabetes.

Appreciating the different effects that antidiabetes agents have on HbAlc, weight, and lipids can lead to better agent selection and potentially improved clinical outcomes. In the literature reviewed, antidiabetes medications were associated with varying effects on weight and other CV risk factors. Given the increased focus on the importance of weight loss in patients with type 2 diabetes, the selection of regimens that not only improve glucose control but have weight-reducing effects (ie, GLP-I receptor agonists), or are at least weight-neutral (ie, DPP-4 inhibitors) may be the best approach to treatment. Therapies that lead to weight reduction in addition to effective glucose lowering may motivate patients with diabetes to remain compliant to their therapies and consequently improve their CV risk profiles.

Acknowledgment

The author thanks Jose Iglesia, MD, for editorial assistance and for support from Amylin Pharmaceuticals, Inc. and Eli Lilly and Company.

Footnotes

Conflict of Interest Statement

F. Xavier Pi-Sunyer, MD discloses conflicts of interest with Amylin Pharmaceuticals, AstraZeneca, Eli Lilly and Co., Novo-Nordisk, and Roche.

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