Intensive treatment aimed at achieving a level of glycosylated hemoglobin A1c (HbA1c) less than 7% markedly decreases the incidence of microvascular disease in patients with T2DM.2 The efficacy of oral treatments for DM (measured as HbA1c decrease) is approximately 1% (Table 1).3 Although insulin therapy has traditionally been considered to have an unlimited hypoglycemic potency, the HbA1c goal is difficult to achieve in clinical practice with the current strategies and formulations. Even when intensive strategies for T2DM control are used, such as treatment with multiple basal-bolus insulin doses, HbA1c levels<7% are achieved in less than 60% of patients, as shown by the published meta-analyses.4,5

The new GLP-1 receptor agonists (GLP-1ra) may achieve greater HbA1c reductions than some oral drugs (−0.97% [95% confidence interval −1.13 to −0.81%]),6 specially long-acting GLP1ra as compared to DPPIV inhibitors.7 In addition, they have associated advantages in terms of weight and blood pressure reduction. However, treatment is still limited by the occurrence of gastrointestinal untoward effects, cost, and lack of experience with long-term use.

The beneficial effect of intensive therapy on macrovascular disease is not no completely proven.8 Two meta-analyses of clinical studies assessing standard versus intensive treatment in cardiovascular (CV) risk reduction concluded that intensive therapy significantly decreased the risk of CV events, but not CV death or all-cause mortality.9,10

The most recent data confirm that we are far from achieving the control goals proposed in T2DM. The results of the National Health and Nutrition Examination Survey for the 1999–2010 period were published in 2013 in the New England Journal of Medicine.11 Although an improvement was seen in these years, 33.4–48.7% of patients did not meet the blood glucose (HbA1c), lipid (LDL cholesterol), weight, and blood pressure goals. In a study on data from 286.791 patients conducted in Spain (the Econtrol study), only 12.1% of adults with T2DM achieved the goals of HbA1c<7%, LDL cholesterol<100mg/dL, and blood pressure<130/80mmHg.12

Treatment intensification in T2DM (mainly intended to decrease CV risk) has been associated to weight increase with treatments used to date. An interesting post hoc analysis of the Action to Control Cardiovascular Risk in Diabetes study reported the weight increases seen in the intensive treatment (+3kg) and standard treatment (+0.3) arms and suggested the potential associated factors.14 Although the analysis concluded that drug treatment alone would be responsible for 15% of the weight increase, raw data suggest significant differences depending on treatment used: patients on intensive treatment who did not use insulin or thiazolidinediones decreased weight by 2.9kg, but patients in this same arm who used both treatments showed weight increases ranging from 4.6 and 5.3kg.

Presence of DM is associated to a decrease in life expectancy which had been estimated at 10 years for people diagnosed in middle age.15 Some epidemiological data suggest that the morbidity and mortality rates have clearly decreased in people with DM from developed countries. The National Health Interview Surveys analyzes every year data from 107,000 non-institutionalized North American citizens. A study reported by Gregg et al. used data from the National Health Interview Surveys corresponding to ≥242,383 adults aged 18 years from the 1997–2004 surveys, whose life status was followed up until December 2006 (10 years).16 In an analysis adjusted for multiple variables, CV mortality decreased by 40% and all-cause mortality by 23% from 1997 to 2004 in people with DM. However, this study again confirms the difficulty in reducing obesity, as the body mass index increased in that same period from 29.8 to 31.0kg/m2 in people with DM (Fig. 1).

Figure 1.

Trends in all-cause and cardiovascular (CV) mortality and body mass index (BMI) in US adults (n=242,383) with (DM) and without diabetes (no DM) between 1997 and 2004.

(0.14MB).

Source: Gregg et al.16

Epidemiological studies clearly show a constant weight increase in the population with T2DM. This secular trend appears to have decrease as the result of recent introduction of new incretin mimetic treatments including GLP-1ra and DPPIV inhibitors. Morgan et al. reviewed data collected at 350 primary care centers in the United Kingdom, corresponding to 10 million patients, 184,474 with DM (2010), in the 1995–2010 period.17 As shown in Fig. 2, use of these drugs appears to result in a lower trend to weight increase in these patients. Other future options (sodium-glucose co-transporter-2 inhibitors, etc.) should try such a reverse trend.

Figure 2.

Secular trends in weight change in people with T2DM (A) and impact of alternative antihyperglycemic treatments (B). DPPIVIs: dipeptidyl peptidase IV inhibitors; GLP-1ras: glucagon-like type 1 peptide receptor agonists; SUs: sulfonylureas.

(0.34MB).

Source: Modified from Morgan et al.17

The most limiting adverse effect with use of drugs for DM is possibly hypoglycemia. Hypoglycemia is a significant reason for non-compliance and may increase mortality and CV and hospitalization risk.18,19 A recent study reviewed the drugs or therapeutic classes associated to urgent hospital admission in people over 65 years of age.20 Insulins and oral antidiabetic agents ranked second and fourth respectively by frequency of associated hospital admissions. Endocrine treatments accounted for 42.1% of all emergency admissions in this population, and hypoglycemia was the reason for admission in 94.6% in them.20

Risk of hypoglycemia is widely different depending on treatment used and its combinations (Fig. 3).21 Risk was lower with the most recent treatments (incretin mimetics, sodium-glucose cotransporter-2 inhibitors…), and it may be expected that molecules that minimize this major acute complication continue to be developed in the future.

Figure 3.

Risk of hypoglycemia associated to different treatments for type 2 diabetes mellitus added to metformin. AGIs: alpha-glucosidase inhibitors; DPPIVIs: dipeptidyl peptidase IV inhibitors; GLP-1ras: glucagon-like type 1 peptide receptor agonists; SUs: sulfonylureas; TZDs: thiazolidinediones.

(0.08MB).

Source: Phung et al.21

All current treatments are associated to potential adverse effects (Table 2). While most such effects are not severe, they are common and responsible for a drug significant discontinuation rate.

An example of this is the current drug of first choice, metformin. The rate of patients with gastrointestinal adverse effects reported varies widely (5–50%).22 Metformin discontinuation is more common in clinical practice than reported in the literature. Patients in whom metformin is contraindicated should be added to this discontinuation rate. Use of glitazones is not considered appropriate either in many of these patients because of the limitations and side effects of these drugs, which leaves a significant niche of patients with no specific insulin sensitizing treatment.

A two-way relationship exists between inflammation and insulin resistance-T2DM. A proinflammatory state may possibly be involved in the origin of T2DM, and T2DM also causes inflammation.30,31 Part of the CV risk associated to T2DM may be caused by oxidative inflammation.32 Insulin secretion by beta cells may also be threatened by inflammatory mechanisms mediating the known glucotoxicity and lipotoxicity events.27 Some drugs currently being developed act specifically on these targets and could provide benefits additional to purely antihyperglycemic benefits.33

T2DM leads to a prothrombotic state that increases the risk of ischemic CV events,34 including stroke. Hypoglycemic treatment modifies risk of stroke comparatively less than risk of other major CV events such as myocardial infarction.35,36 This prothrombotic state not controlled by current antidiabetic therapies may usually contribute to a relative failure in reduction of macrovascular complications.