NIH Public Access Author Manuscript Curr Diab Rep. Author manuscript. Interventions to Preserve Beta-Cell Function in the Management and Prevention of Type 2 Diabetes Kathleen A. Page and Division of Endocrinology and Diabetes, Department of Internal Medicine, Keck School of Medicine, University of Southern California, 1333 San Pablo Street; BMT-B11, Los Angeles, CA 90033, USA Tamar Reisman Department of Internal Medicine, Keck School of Medicine, University of Southern California, Los Angeles, CA, USA
Kathleen A. Page: [email protected]; Tamar Reisman: [email protected]Abstract
The International Diabetes Federation estimates that there are currently 336 million peopleworldwide who have type 2 diabetes (T2DM), and the global prevalence of diabetes has more thandoubled since 1980. The rapid rise in rates of T2DM echoes a similar rise in rates of obesity,which causes insulin resistance and places an increased insulin secretory demand on pancreatic βcells. While diabetes is diagnosed clinically by elevated plasma glucose levels, loss of β-cellfunction is progressive over time and β-cell dysfunction is far advanced by the time diabetes isdiagnosed. Methods for preserving or restoring β-cell function are important for the preventionand treatment of T2DM. Interventions that reduce body fat or that change fat biology provide thebest evidence for slowing or arresting the deterioration of β-cell function that causes T2DM. Theseinterventions should form the basis of interventions to prevent and treat T2DM, particularly earlyin its course. Keywords
Diabetes; Prevention; β-cell function; Glucose; Type 2 diabetes
Introduction
The global prevalence of diabetes mellitus has more than doubled since 1980 and isexpected to continue to rise at alarming rates [1]. An estimated 336 million peopleworldwide now have T2DM [2]. T2DM results from an interaction between genetic andenvironmental factors that impair β-cell function and insulin action. Diabetes is diagnosedclinically by elevated plasma glucose levels, however, loss of β-cell function is progressiveover time and β-cell dysfunction is far advanced by the time diabetes is diagnosed clinically[3, 4]. Patients with impaired glucose tolerance have <50 % of normal β-cell function [5–7]and patients with T2DM have <15 % of normal β-cell function for their degree of insulinresistance [8], demonstrating the progressive nature of β-cell dysfunction in the course ofT2DM. Therefore, methods for preserving or restoring β-cell function are important in our
Springer Science+Business Media New York 2013
Correspondence to: Kathleen A. Page, [email protected]. Disclosure No potential conflicts of interest relevant to this article were reported.
attempts to prevent and treat T2DM. In this review, we discuss current evidence for causesof the progressive loss of β-cell function in T2DM, and the effects of current therapeutic
strategies on preservation of β-cell function and the prevention and treatment of T2DM. Pathogenesis of Type 2 Diabetes β-cell Compensation for Insulin Resistance
Diabetes is defined clinically as an increase in plasma glucose levels. Plasma glucose levelsare determined by the sensitivity of tissues to insulin and by the amount of insulin secretedby the pancreatic β cells. A number of factors, including lack of exercise, obesity, andvisceral fat are major determinants of insulin resistance [4].
Normally, increases in insulin resistance are matched by a compensatory increase in insulinsecretion by the β cells, and the relationship between insulin resistance and insulin secretionis defined by a hyperbola [9]. Based on this hyperbolic relationship, β-cell compensation canbe determined by the disposition index, defined as the product of insulin secretion andinsulin sensitivity [9] (Fig. 1). As long as the product of insulin secretion times insulinsensitivity remains constant, glucose tolerance is preserved. For example, in a lean, insulinsensitive individual, less insulin secretion is required to maintain normal glucose levels. Anobese, insulin resistant individual requires a compensatory increase in insulin secretion in
order to maintain normal glucose levels. Inadequate β-cell compensation for insulinresistance results in impaired glucose homeostasis and eventually to T2DM. Longitudinalstudies have shown that reduced β-cell function as reflected in the disposition index is apowerful predictor of conversion from normal glucose tolerance to T2DM in at-riskpopulations [10, 11].
Multiple factors, including genetic predisposition, glucotoxicity, lipotoxicity, and decreasedβ-cell mass and function are thought to play a role in the pathogenesis of T2DM [2, 4]. Glucotoxicity and Lipotoxicity
Glucotoxicity refers to irreversible damage to pancreatic β cells caused by chronicallyelevated glucose levels and has been demonstrated with in vitro and in vivo studies [12–14]. Similarly to chronically elevated glucose levels, chronically elevated levels of free fattyacids (FFA) are known to cause β-cell dysfunction, a concept referred to as lipotoxicity [12]. Obesity, especially abdominal adiposity, results in increased FFA levels, and has beenshown to correlate with decreased insulin gene expression and β-cell death [12]. In vitro andin vivo studies using lipid infusions have shown that chronic exposure to FFA results indecreased glucose stimulated insulin secretion, decreased insulin gene expression, and
increased β-cell apoptosis in β cell lines and isolated human islets [15–17]. Recently, theconcept of “glucolipotoxicity” has been introduced because of evidence suggesting thatlipotoxicity is dependent on the simultaneous presence of hyperglycemia, and that elevatedglucose and FFA act synergistically to impair β-cell function [12, 15, 18].
Two proposed mechanisms for glucotoxicity are endoplasmic reticulum (ER) stress andoxidative stress [15, 19]. ER Stress
The ER is the organelle responsible for folding, modification, and trafficking of proteins[20]. β cells are particularly rich in ER, given their secretory function. ER stress occurswhen the ER’s folding capacity cannot match the protein load, and unfolded or misfoldedproteins accumulate in the ER’s lumen [12]. Chronic hyperglycemia increases theproduction demand on β cells, which puts them at risk for ER stress. As the β cells of
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hyperglycemic individuals increase their preproinsulin production to account for elevatedglucose levels, misfolded proinsulin may result in ER stress [12].
It is important to note that the processing of proinsulin into mature insulin is a critical step ininsulin production and secretion, and high proinsulin levels relative to circulating levels ofmature insulin can indicate β-cell stress. Recent genome-wide association studies (GWAS)have identified 9 genetic variants associated with fasting proinsulin that may contribute to β-cell function and susceptibility for T2DM [21].
When ER stress occurs, a number of different stress responses collectively referred to as theunfolded protein response (UPR) are activated in an attempt to restore cell function [20]. This is accomplished by (a) decreased translation, (b) increased ER folding capacity, (c) ERstress associated protein degradation and, ultimately (d) cell apoptosis if a, b, and c areunsuccessful [12].
ER stress also results in increased production of molecular chaperones, which help withprotein folding, such as 78 kDa glucose-regulated protein (GRP78) and 4-phenylbutyrate(PBA) [19]. A recent study reported that glucose infusion to rats for 48 hours increased ERstress markers and induced β-cell dysfunction, but co-infusion with the chaperone moleculePBA prevented glucose-induced β-cell dysfunction [19]. Oxidative Stress
In vitro and in vivo studies implicate oxidative stress in glucose-induced β-cell dysfunction[19, 22, 23]. As glucose is metabolized in the mitochondria via oxidative phosphorylation,reactive oxygen species (ROS) are produced. As studies involving rat islets have shown,ROS reduce the ability of the mitochondria to produce ATP, thereby decreasing glucose-stimulated insulin secretion [24]. Isolated islets from T2DM patients have increased markersof oxidative stress compared with islets from controls without T2DM, and levels ofoxidative stress correlate with the degree of impairment in glucose-stimulated insulinsecretion [23]. Moreover, exposure to the antioxidant, glutathione, for 24 hours was shownto significantly improve glucose-stimulated insulin release and resulted in decreasedmarkers of oxidative stress suggesting that reducing islet cell oxidative stress may improvethe functional impairment of T2DM islets [23]. Reduced β-Cell Mass
A number of studies have demonstrated that β-cell mass and/or volume is reduced inpatients with T2DM [25–29]. In a study examining pancreatic tissue from 124 autopsies,relative β-cell volume was found to be increased by 50 % in obese individuals without
T2DM when compared with lean individuals without T2DM. In contrast, in obeseindividuals with impaired fasting glucose (IFG) there was a 40 % deficit in β-cell volumeand in obese individuals with T2DM there was a 63 % deficit in β-cell volume whencompared with obese individuals without T2DM [27]. The presence of decreased β-cellvolume in individuals with IFG suggests that this process occurs early on in the process ofdeveloping T2DM [27]. Effects of Type 2 Diabetes Therapies on β-Cell Function
Clinical management of T2DM is currently based on achieving plasma glucose levels thatare associated with a low risk of developing long-term microvascular complications [30]. There are a number of therapies that are effective in reducing plasma glucose levels throughvarious mechanisms, however current therapeutic strategies have different effects on β-cellfunction. Interventions that reduce the load on β-cells by decreasing insulin demand havebetter durability on glycemic control and are more effective in preventing T2DM in high
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risk patients. Below, we discuss current therapies used in the treatment of T2DM and theireffects on β-cell function, long-term durability, and effectiveness in preventing progression
Intensive Lifestyle Modification
Obesity is a major risk factor for T2DM, and the increased prevalence of obesity is largelyresponsible for the concomitant increase in T2DM [1]. Obesity and lack of physical activitycause insulin resistance and increase the workload on β cells [31]. Weight loss and exerciseinterventions increase insulin sensitivity and unload the secretory demand on β-cells.
The United States Diabetes Prevention Program (DPP) showed that implementing a programthat achieved at least a 7 % reduction in body weight through diet and exercise reduced theincidence of T2DM by 58 % in patients with impaired glucose tolerance (IGT) [32]. Theeffect of lifestyle intervention on reducing the incidence of T2DM was related to overallimprovements in β-cell function driven by its gains in insulin sensitivity, such that thehyperbola describing the relationship between insulin secretion and in insulin sensitivity wasshifted to the right [33]. The Finnish Diabetes Prevention Study (DPS) also showed a 58 %reduction in the incidence of T2DM in individuals with IGT who were assigned to a lifestyleintervention that included weight loss and increased physical activity [34] (Table 1). Arecent analysis of the DPS indicated that lifestyle intervention helps to preserve β-cell
function and prevent the development of T2DM through improvements in insulin sensitivity[35]. Pharmacological Weight Loss
The Xenical in the Prevention of Diabetes in Obese Subjects (XENDOS) Study reported thatorlistat, a gastrointestinal lipase inhibitor, added to lifestyle intervention resulted in greaterweight loss and a 37 % reduced relative risk for diabetes compared with lifestyleintervention alone in obese adults with normal and impaired glucose tolerance [36]. In obesesubjects with IGT at baseline, orlistat plus lifestyle intervention resulted in a 45 % reducedrelative risk for diabetes vs lifestyle intervention alone (Table 1).
These randomized controlled trials demonstrate the importance of lifestyle modificationsand pharmacological weight loss in T2DM prevention, but it is important to note that weightregain is common [37], even with pharmacological treatment. For example, in the XENDOStrial, mean weight loss after the first year of treatment was 10.6 kg with orlistat plus lifestyleintervention and 6.2 kg after lifestyle intervention alone, but after 4 years of treatment themean weight loss was only 5.8 kg in orlistat plus lifestyle and 3.0 kg in lifestyle interventionalone [36]. Therefore, early intervention measures, including public health initiatives aimed
at preventing obesity by promoting physical activity and healthier diets early in life may beparticularly important to prevent the upward trends in prevalence of T2DM. For obeseindividuals with impaired glucose levels, interventions aimed at more robust and sustainedweight loss, including modestly invasive bariatric surgery, deserve exploration as anapproach towards β-cell preservation for the prevention of T2DM [38] (see “On theHorizon; Newer Approaches” below). Sulfonylureas
Sulfonylureas are oral medications that stimulate insulin secretion by binding to thesulfonylurea receptor 1, resulting in membrane depolarization and calcium influx, whichtriggers exocytosis of insulin containing secretory granules [39]. While sulfonylureas arewidely used clinically in the treatment of T2DM, evidence from the Diabetes OutcomeProgression Trial (ADOPT) study demonstrates a more rapid deterioration of glycemiccontrol with the sulfonylurea, glyburide, compared with treatment with metformin and the
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thiazolidinedione (TZD), rosiglitazone in patients with recently diagnosed T2DM [40]. Invitro studies have suggested that the lack of durability of sulfonylurea treatment observed in
clinical studies may be due to its potentially damaging effects on pancreatic β-cells [41, 42]. Studies in isolated human islets indicate that the sulfonylurea, glibenclamide, decreasesinsulin content, and induces β-cell apoptosis [41, 42]; however, 1 study suggested that thesulfonylurea, gliclazide, may protect β cells from apoptosis potentially through antioxidanteffects [42]. No clinical studies have demonstrated a beneficial effect of sulfonylureas in theprevention of T2DM, and as mentioned above, sulfonylurea monotherapy has less durableeffects on glycemic control compared with a TZD or metformin in patients recentlydiagnosed with T2DM [40]. Metformin
Metformin is effective at reducing hyperglycemia primarily by inhibiting hepatic glucoseproduction and by increasing insulin sensitivity [43]. It is currently recommended as a first-line drug for the treatment of T2DM [30]. In vitro studies demonstrated that metformincould protect isolated human islets from glucotoxicity and lipotoxicity suggesting thatmetformin may have beneficial effects on β-cell health [44, 45]. In clinical studies, the DPPshowed that metformin reduced the conversion from IGT to T2DM by 31 % [32] suggestingthat it has modest effects on slowing the progression of T2DM (Table 1). The U.K. Prospective Diabetes Study (UKPDS) showed similar rates of deterioration of β-cell
function (assessed with HOMA-B index) and loss of glycemic control with metformintreatment compared with sulfonylureas or insulin treatment in patients with recentlydiagnosed T2DM [46, 47]. The ADOPT study showed that the durability of metforminmonotherapy was better than glyburide, but it still resulted in a 21 % failure rate at 5 years inpatients with recently diagnosed T2DM [40]. Acarbose
Acarbose is an α-glucosidase inhibitor that improves post-prandial hyperglycemia byinhibiting the activity of enzymes in the small intestine resulting in reduced glucoseabsorption. The Study to Prevent NIDDM (STOP-NIDDM) found a 25 % relative riskreduction in the development of T2DM over 3.3 years in patients with impaired glucoselevels treated with acarbose compared with placebo [48] (Table 1). However, in the 3-monthobservation period after acarbose was discontinued, the incidence of diabetes in patientswho had not converted was higher in the group initially assigned to acarbose (15 %)compared with group first randomized to placebo (10 %) suggesting that the benefit ofacarbose is lost after discontinuation of active treatment [48]. Thiazolidinediones (TZDs)
TZDs are potent insulin sensitizers that improve glycemic control in patients with T2DM[43, 49]. TZDs are ligands for the nuclear transcription factor peroxisome-proliferator-activated-receptor-γ, and they have a wide spectrum of action [49]. Studies have shown thatTZDs reduce lipotoxicity [50, 51], prevent β-cell apoptosis [52], increase serum adiponectinlevels [53], and improve β-cell function [54–57]. Prevention trials have consistently shownthat TZDs are effective in preventing the onset of type 2 diabetes in high-risk patients by~50 %–75 % (DPP, Troglitazone in Prevention of Diabetes (TRIPOD), Pioglitazone inPrevention of Diabetes (PIPOD), Diabetes Reduction Assessment with Ramipril andRosiglitazone Medication (DREAM), and Actos now (ACT-NOW) [55, 56, 58–60] (seeTable 1). The TRIPOD study was the first to carefully examine changes in β-cell functionthrough treatment of insulin resistance as a way to reduce T2DM risk. Notably, the TRIPODstudy showed that protection from diabetes in women with previous gestational diabetespersisted 8 months after T2DM treatment stopped, and patients who were protected fromdiabetes during TZD treatment had stable β-cell function and insulin resistance for almost 5
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years demonstrating that TZDs slow the natural progression of the disease [55, 56]. Theability of TZDs to slow or stop progression to T2DM was supported by DREAM and DPP,
in which the protection from diabetes that was achieved during treatment persisted aftertreatment was stopped [61].
The ADOPT Study demonstrated that TZDs had significantly greater durability for glycemiccontrol in patients with recently diagnosed T2DM when compared with both metformin andsulfonylureas [40]. Subsequent analysis of the ADOPT data showed that the reduction intreatment failure with rosiglitazone corresponded with improved β-cell function andincreased insulin sensitivity [62] supporting results from the TRIPOD prevention study andsuggesting that TZDs may preserve β-cell function by improving insulin sensitivity andunloading the secretory demand on β-cells [55].
The clinical use of TZDs for the prevention of T2DM is limited due to adverse side effects,including fluid retention and weight gain, and recent safety concerns including reports of anassociation with increased risk for bone fractures and bladder cancer [49] The developmentof safer compounds with selective PPARγ modulation offers the potential for targetedinsulin sensitization in the absence of adverse side effects [49]. GLP-1 Receptor Agonists
Glucagon-like polypeptide-1 (GLP-1) is an incretin hormone secreted by the L cells in theintestines in response to nutrient stimulation. GLP-1 possesses a number of properties thatmake it an ideal agent for the treatment of T2DM. GLP-1 potentiates glucose stimulatedinsulin secretion, suppresses glucagon secretion, delays gastric emptying and suppressesappetite [43]. GLP-1 is cleaved by the enzyme dipeptidyl peptidase-4 (DPP-4) leading to itsrapid inactivation, but DPP-4 resistant GLP-1 receptor agonists, including exenatide andliraglutide, and DPP-4 inhibitors have been developed for the treatment of T2DM [43]. Studies in animals have shown the GLP-1 analogues decrease β-cell apoptosis and increaseβ-cell mass [63–65], and human studies indicate that exenatide exerts potent anti-inflammatory effects that are independent of weight loss [66]. Findings from recentrandomized controlled trials demonstrate that exenatide improves β-cell function [67, 68,69•, 70••]. Bunck and colleagues compared the effects of exenatide with the insulin,glargine, on β-cell function over 3 years in metformin treated patients with T2DM [68, 69•]. They found that exenatide significantly improved β-cell function during 52 weeks of activetreatment compared with glargine, but after stopping the treatments for 4 weeks, β-cellfunction returned to pre-treatment values in both groups [68]. In contrast, in the 3-yearextension study, β-cell function was sustained in the exenatide group after a 4-week off-drugperiod whereas the glargine treated patients had a reduction in β-cell function suggesting
that at least 3 years of exenatide treatment may be necessary to delineate a significant,prolonged benefit on β-cell function [69•].
A recent study in obese adults showed that a 20-week treatment with liraglutide (in dosesranging from 1.8 to 3 mg per day) resulted in greater weight loss and an 84 %–96 %reduction in the prevalence of prediabetes compared with placebo [71••]. Another clinicaltrial showed that a 24-week treatment with exenatide plus lifestyle modification resulted ingreater weight loss and normalization of glucose tolerance in 77 % of obese participantswith impaired glucose homeostasis (IGT or IFG) compared with 56 % in the placebo group[72•]. Longer term prevention trials in high-risk patients are needed to determine whetherGLP-1 agonists can modify the progressive course of T2DM.
A recent randomized controlled trial suggested that the GLP-1 receptor agonist, exenatide,may have durable effects on glycemic control in patients with T2DM [70••]. The EUREXAstudy compared exenatide with glimepiride as add-on to metformin for durability of
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glycemic control in patients with T2DM who were inadequately controlled with metforminalone [70••]. Results showed that glycemic control was maintained for longer (180 weeks
with exenatide vs 142 weeks with glimepiride) and treatment failure was lower in theexenatide (41 %) compared with glimepiride (54 %) group over the 48 month follow upperiod. The exenatide group also had a significantly greater increase in disposition indexcompared with the glimepiride group demonstrating beneficial effects of exenatide on β-cellfunction [70••]. On the Horizon; Newer Approaches Early Intensive Treatment with Insulin and/or Multiple Agents
In vitro studies investigating the effects of glucose toxicity on a pancreatic β-cell lineshowed that shortening the duration of antecedent glucose toxicity increases the likelihoodof recovering β-cell function [73]. Thus, early and more aggressive treatment strategies thatquickly normalize glucose levels in patients with newly diagnosed T2DM may preserveresidual β-cell function by reducing glucotoxicity. Clinical studies have shown beneficialeffects of early short-term (2–3 weeks) intensive insulin therapy in patients with newlydiagnosed T2DM [74–78]. A multi-center randomized trial showed that early, short-termintensive insulin treatment at the time of T2DM diagnosis led to improved β-cell functionand greater diabetes remission rates at 1 year compared with early, short-term treatment with
oral hypoglycemic agents [75]. A recent randomized control trial evaluated β-cell functionpreservation after 3.5 years of intensive therapy with insulin plus metformin compared withtriple oral therapy with metformin, glyburide, and pioglitazone after an initial 3-monthinsulin treatment period and found that both approaches were effective in preserving β-cellfunction [77]. Based on these results, the authors suggested that patients with newlydiagnosed T2DM should be treated with an initial period of intensive insulin therapy tomaximize β-cell recovery and then continued either on insulin therapy or switched to acombination of oral agents with complementary mechanisms of action [77].
The Outcome Reduction with an Initial Glargine Intervention (ORIGIN) trial recentlyreported results of the comparison between treatment with insulin glargine to normalizefasting plasma glucose levels compared with standard care on cardiovascular outcomes,cancer, and incident diabetes in over 12,000 patients with cardiovascular disease risk factorsplus IFG or T2DM who were followed for a median of 6.2 years [79]. They found thatglargine had a neutral effect on cardiovascular outcomes and cancers, but that it reducednew-onset diabetes among the participants without diabetes at randomization providingsupport for the idea that the early use of insulin may preserve β-cell function in patients withimpaired glucose homeostasis.
There is a growing interest in the early use of combination therapies for the treatment ofpatients with IGT and T2DM [67, 80]. A recent clinical study examined the effects ofcombination therapy with exenatide and rosiglitazone vs each therapy alone on insulinsensitivity and β-cell function in patients with T2DM already on metformin [67]. The 20-week combination therapy with exenatide and rosiglitazone resulted in greaterimprovements in insulin sensitivity and β-cell function and better glycemic controlcompared with either treatment alone suggesting a beneficial effect of the combinationtherapy [67]. However, randomized controlled studies are needed to determine whether earlyuse of a combination of oral agents is effective in preventing T2DM in high risk patients andthe long-term durability of this treatment strategy on glycemic control. Bariatric Surgery
Bariatric surgery is an effective and durable treatment for obesity and provides substantialimprovements in glycemic control in obese patients with T2DM [81]. Four bariatric surgical
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procedures are used conventionally, including Roux-en-Y gastric bypass (RYGB),laparoscopic adjustable gastric banding (LAGB), biliopancreatic diversion (BPD), and
laparoscopic sleeve gastrectomy (LSG), and RYGB and LAGB are the most widely usedsurgical procedures [81]. A meta-analysis indicated that bariatric surgery results inresolution of diabetes in 78 % of patients with T2DM demonstrating its significant impacton T2DM remission [82]. The effects of bariatric surgery on β-cell function were recentlysummarized in a review by Bradley et al [83], and indicate that LAGB surgery increases thedisposition index following modest weight loss, RYGB surgery increases the dispositionindex after significant weight loss, BPD surgery increases early insulin secretion anddisposition index in patients with T2DM, and LSG surgery increases early insulin secretionin patients with T2DM, but its effects on disposition index are currently unknown [83].
Three randomized controlled trials have compared the effects of bariatric surgery to medicaltherapy on remission of T2DM, and all 3 studies showed that bariatric surgery wassignificantly more effective than medical therapy in achieving remission of T2DM within 1to 2 years following surgery [84, 85••, 86••]. The first randomized controlled trial showedthat LAGB surgery resulted in T2DM remission in 73 % of patients vs only 13 % whoreceived standard medical treatment [84]. In a recent randomized controlled trial, 42 % ofobese patients with T2DM who underwent RYGB surgery and 37 % of those whounderwent LSG surgery achieved remission of T2DM compared with 12 % of patients
treated with conventional medical therapy [85••]. In another recent randomized controlledtrial, 95 % of individuals with T2DM who underwent BPD and 75 % of those whounderwent RYGB surgery, but none of those who received standard medical therapyachieved remission of T2DM [86••].
The long- term effects of bariatric surgery on T2DM remission were examined in theSwedish Obese Subjects Study (SOS), a nonrandomized prospective case-control study inover 4,000 obese patients who underwent bariatric surgery [87]. They found that 72 % ofT2DM patients achieved remission at 2 years after surgery, and 36 % had maintained T2DMremission at 10 years after surgery [87]. Similar results were found in another smaller studywhich showed durable remission of T2DM (>5 years) in over half of the 89 % of patientswho had achieved early following RYBG remission [88], and a meta-analysis whichreported that 62 % of patients with T2DM remained free of diabetes for more than 2 yearsfollowing bariatric surgery [82].
The effect of bariatric surgery (LAGB, VBG, RYGB) on the prevention of T2DM in obeseadults was recently examined in the SOS study which followed surgically treated andmatched controls for 15 years [89••]. Bariatric surgery compared with standard care reduced
the long-term relative risk of T2DM by 78 % in obese adults, and among those with IFG itreduced the relative risk of T2DM by 82 %. The postoperative mortality was 0.2 %, and 2.8% of patients had complications that required a reoperation [89••]. These findings indicatethat bariatric surgery has effective and durable effects on the prevention of T2DM in obeseadults, particularly among those with IFG. Randomized controlled trials are needed toconfirm whether bariatric surgery is an effective and safe approach for preventing T2DM inhigh-risk individuals. Conclusions
T2DM is characterized by a progressive loss of β-cell function that occurs against abackground of chronic insulin resistance. The rapid rise in rates of T2DM echoes a similarrise in rates of obesity, which causes insulin resistance and may have additional effects on β-cell health. Interventions that reduce body fat (such as diet and exercise, GLP-1 receptoragonists, or bariatric surgery) or that change fat biology (TZDs) provide the best evidence
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for slowing or arresting the deterioration of β-cell function that causes T2DM. Theseinterventions should form the basis of interventions to prevent and treat T2DM, particularly
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Curr Diab Rep. Author manuscript. Fig 1. The Disposition Index (DI) is the product of insulin secretion and insulin sensitivity. Normally, increases in insulin resistance (due to factors such as weight gain and inactivity) are matched by a compensatory increase in insulin secretion in a hyperbolic relationship (A to B) and DI remains constant. Inadequate insulin secretion to compensate for insulin resistance results in a reduction in DI and impaired glucose homeostasis (A to C) and eventually to type 2 diabetes (A to D). (Data adapted from: Bergman RN, Phillips LS, Cobelli C. Physiologic evaluation of factors controlling glucose tolerance in man: measurement of insulin sensitivity and beta-cell glucose sensitivity from the response to intravenous glucose. J Clin Invest. 1981;68(6):1456–67) [9]. Curr Diab Rep. Author manuscript. Participants at high-risk for diabetes Intervention Relative reduction in risk of diabetesa DPP Diabetes Prevention Program, DPS Diabetes Prevention Study, TRIPOD troglitazone in prevention of diabetes, DREAM diabetes reductionassessment with ramipril and rosiglitazone medication, ACT NOW Actos now, IGT impaired glucose tolerance, GDM gestational diabetes mellitus
Curr Diab Rep. Author manuscript.
The effect of coffee and caffeine consumption on serum lipids in rats.N. Rakicioglu, G. Pekcan and A. Cevik. International Journal of Food Sciences and Nutrition 49.6 (Nov 1998): p441(1). (3575 words) Abstract: Coronary heart disease research confirms that coffee alone is not a significant risk factor. Laboratory rats were fed controlled diets with varying levels of coffee, caffeine
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