Celiac crisis in an adult type 1 diabetes mellitus patient presented with diarrhea,weight loss and hypoglycemic attacks

Type 1 diabetes mellitus (T1DM) is an autoimmune disease, characterized by loss of the insulin-producing β cells of the islets of Langerhans in the pancreas, causing insulin deficiency. Celiac disease has been seen in 3 to 8 % of T1DM patients. Celiac crisis, an acute severe onset of celiac disease, is a rare and life-threatening manifestation. We report a 50-year-old man with type 1 diabetes mellitus who arrived at our service with a 2-month history of watery diarrhea associated with hypoglycemic attacks, abdominal pain, and weight loss of 13 kg. The diagnosis of celiac crisis was made based on diarrhea leading to dehydration, severe metabolic and electrolyte abnormalities, and subsequent improvement after introduction of a gluten-free diet.     

Pathophysiology of insulin secretion

Defects in pancreatic islet beta-cell function play a major role in the development of diabetes mellitus. Type 1 diabetes is caused by a more or less rapid destruction of pancreatic beta cells, and the autoimmune process begins years before the beta-cell destruction becomes complete, thereby providing a window of opportunity for intervention. During the preclinical period and early after diagnosis, much of the insulin deficiency may be the result of functional inhibition of insulin secretion that may be at least partially and transiently reversible. Type 2 diabetes is characterized by a progressive loss of beta-cell function throughout the course of the disease. The pattern of loss is an initial (probably of genetic origin) defect in acute or first-phase insulin secretion, followed by a decreasing maximal capacity of insulin secretion. Last, a defective steady-state and basal insulin secretion develops, leading to almost complete beta-cell failure requiring insulin treatment. Because of the reciprocal relation between insulin secretion and insulin sensitivity, valid representation of beta-cell function requires interpretation of insulin responses in the context of the prevailing degree of insulin sensitivity. This appropriate approach highlights defects in insulin secretion at the various stages of the natural history of type 2 diabetes and already present in individuals at risk to develop the disease. To date none of the available therapies can stop the progressive beta-cell defect and the progression of the metabolic disorder. The better understanding of the pathophysiology of the disease should lead to the development of new strategies to preserve beta-cell function in both type 1 and type 2 diabetes mellitus.     

GLP-1类似物在1型糖尿病和胰岛移植中的研究进展

1型糖尿病是在遗传和环境因素共同作用下,机体产生针对胰岛β细胞的自身免疫反应,随疾病进展大量β细胞被破坏而导致胰岛素分泌不足而致病.对1型糖尿病的理想冶疗模式是一方面阻断对β细胞的免疫损伤,另一方面促进β细胞再生,增加β细胞数量.体内和体外的研究表明胰升糖素样肽(GLP)-1类似物有促进胰岛素的合成与分泌,促进母细胞增殖并减少B细胞凋亡的作用,因此对于1型糖尿病有潜在的治疗作用.本文就近期发表的研究回顾了GLP-1类似物在1型糖尿病和胰岛移植中的研究进展,同时展望了未来的研究方向.     

胰岛素生成,胰岛素分泌及2型糖尿病:问题的核心在于β细胞

近年来,有人将2型糖尿病(T2DM)定义为由胰岛素抵抗引起的一种疾病,作为代谢综合征的一部分。胰岛素抵抗确实存在于T2DM,但同时也以同样程度存在于许多并无糖尿病的人群中,这些人可有或无代谢综合征。因而单独胰岛素抵抗不可能是T2DM的决定性致病因素。T2DM从其最早的阶段包括糖耐量受损(IGT)及空腹血糖受损(IFG),甚或在可测出的这些血糖变化之前的“糖尿病前期”就出现胰岛素释放动力学的障碍;其主要特征是对葡萄糖反应的胰岛素释放第一相丧失,随之而来的是逐渐加重的第二相胰岛素和总胰岛素分泌的受损。第一相胰岛素反应丧失的后果为肝脏未能迅速胰岛素化,延迟了对肝葡萄糖输出的抑制,从而引起餐后高血糖。在某些研究中,确已发现T2DM时β细胞量总体的减少,但并非所有研究中都有此同样结果,故对此尚须进一步证实。现已明确,糖尿病易发人群的β细胞的分泌适应能力是有限的,在胰岛素抵抗或热量负荷对胰岛素释放要求增加时,就难以胜任。此外,即使轻度的高血糖也会严重影响胰岛素的分泌并减少胰岛素原的合成,从而使代谢所需的胰岛素进一步减少。转录因子PDX-1在此损伤过程中起关键作用。因而,及早并有效地将T2DM血糖控制于接近正常水平至关重要,尤其是对胰岛素一相分泌的恢复更是如此。     

Immune Intervention and Preservation of Pancreatic Beta Cell Function in Type 1 Diabetes

Type 1 diabetes (T1D) results from the immune-mediated destruction of insulin-producing β cells located within the pancreatic islets of Langerhans. The autoimmune process leads to a deficiency in insulin production and resultant hyperglycemia requiring lifelong treatment with insulin administration. T1D continues to dramatically increase in incidence, especially in young children. Substantial knowledge surrounding human disease pathogenesis exists, such that T1D is now predictable with the measurement of antibodies in the peripheral blood directed against insulin and other β cell proteins. With the ability to predict, it naturally follows that T1D should be preventable. As such, over the last two decades, numerous well-controlled clinical trials have been completed attempting to prevent diabetes onset or maintain residual β cell function after clinical onset, all providing relatively disappointing results. Here, we review the T1D prevention efforts, the current landscape of clinical therapies, and end with a discussion regarding the future outlook for preventing T1D.     

Relationships among insulin resistance, type 2 diabetes, essential hypertension, and cardiovascular disease: similarities and differences

Insulin resistance plays a major role in the pathogenesis and clinical course of patients with type 2 diabetes (2DM) and essential hypertension. However, the syndromes differ in prevalence of insulin resistance, and associated insulin secretory response. Essentially all patients with type 2 diabetes are insulin resistant, whereas only approximately 50% of those with essential hypertension are insulin resistant. Furthermore, 2DM develops when the pancreatic β-cell can no longer maintain the degree of compensatory hyperinsulinemia needed to prevent hyperglycemia. In contrast, the compensatory hyperinsulinemia that prevents most insulin resistant individuals from developing 2DM acts on normally insulin sensitive tissues in a manner that predisposes to the development of essential hypertension. This review will discuss these similarities and differences in some detail, as well as exploring the relationship among insulin resistance and related metabolic abnormalities in the pathogenesis of cardiovascular disease in patients with 2DM and essential hypertension.     

Pancreatic polypeptide administration enhances insulin sensitivity and reduces the insulin requirement of patients on insulin pump therapy

Introduction

The effects of pancreatic polypeptide (PP) infusion were examined in patients on insulin pump therapy to determine whether PP administration can reduce insulin requirements in patients with type 1 diabetes mellitus (T1DM) or type 3c diabetes mellitus (T3cDM; pancreatogenic).

Methods

Ten subjects with long-standing T1DM (n = 7) or T3cDM (n = 3) on insulin pump treatment received a 72 h subcutaneous infusion of 2 pmol/kg/min bovine PP or saline by portable infusion pump in a single-blinded, randomized, crossover design.

Results

Pancreatic polypeptide infusion raised plasma PP levels to 450–700 pmol/liter. Daily insulin infusion requirements (I) fell from 48 ± 6.9 to 40 ± 7.5 U on day 2 (p < .05) and from 46 ± 7.7 to 37 ± 6.6 U on day 3 (p < .05) of PP infusion compared with saline. Corrected for average blood glucose concentration (G), I/G fell in 10/10 subjects during the second 24 h period and in 7/10 subjects during the third 24 h period; sensitivity to insulin, calculated as 1/(I/G), increased 45% ± 12% on day 2 (p < .01) and 34% ± 14% on day 3 (p < .05) of PP infusion. Pancreatic polypeptide responses to a test meal were compared with the change in insulin infusion requirements in 5 subjects; the reduction in insulin requirements seen during PP infusion correlated with the degree of baseline PP deficiency (p < .002).

Conclusions

A concurrent subcutaneous infusion of PP enhances insulin sensitivity and reduces insulin requirements in patients with long-standing T1DM and T3cDM on insulin pump therapy. The benefit of PP infusion correlated with the degree of PP deficiency.     

Optimizing the replacement of basal insulin in type 1 diabetes mellitus: no longer an elusive goal in the post-NPH era

In physiology, insulin is released continuously by the pancreas at a nearly constant rate between meals and in the fasting state (basal insulin secretion). The pivotal role of basal insulin is to restrain release of glucose from the liver and free fatty acids from adipose tissue, thus preventing hyperglycemia and ketosis. In type 1 diabetes mellitus (T1DM) (absolute insulin deficiency), the replacement of basal insulin is challenging because the currently available pharmacological preparations of long-acting insulin do not exactly reproduce the fine physiology of flat action profile of basal insulin of subjects without diabetes. NPH and NPH-based insulin mixtures no longer have a place in the treatment of T1DM because of their early peak effects and relatively short duration of action, which result into risk of nocturnal hypoglycemia and fasting hyperglycemia, respectively, after the evening injection. Only continuous subcutaneous (s.c.) insulin infusion (CSII) or long-acting analogs such as glargine (>24 h in duration, once a day) and detemir (<24 h in duration, once or more often twice a day) should be used as basal insulin in T1DM in combination with mealtime rapid-acting analogs. CSII and the long-acting analogs are nearly peakless and therefore reduce the risk for hypoglycemia (especially at night), blood glucose (BG) variability, and lower A1C with similar or less hypoglycemia. CSII is the "gold standard" of replacement of basal insulin because of better reproducibility of subcutaneous absorption of soluble insulin. Although CSII is not superior to multiple daily insulin injections in the general T1DM population, CSII might be indicated in subsets of T1DM (long-term T1DM with insulin "supersensitivity" and needs for low-dose insulin, some individuals with variable subcutaneous absorption of long-acting analogs) to minimize BG variability, reduce hypoglycemia, and benefit A1C.     

Alzheimer's Disease Is Type 3 Diabetes�CEvidence Reviewed

Alzheimer''s disease (AD) has characteristic histopathological, molecular, and biochemical abnormalities, including cell loss; abundant neurofibrillary tangles; dystrophic neurites; amyloid precursor protein, amyloid-β (APP-Aβ) deposits; increased activation of prodeath genes and signaling pathways; impaired energy metabolism; mitochondrial dysfunction; chronic oxidative stress; and DNA damage. Gaining a better understanding of AD pathogenesis will require a framework that mechanistically interlinks all these phenomena. Currently, there is a rapid growth in the literature pointing toward insulin deficiency and insulin resistance as mediators of AD-type neurodegeneration, but this surge of new information is riddled with conflicting and unresolved concepts regarding the potential contributions of type 2 diabetes mellitus (T2DM), metabolic syndrome, and obesity to AD pathogenesis. Herein, we review the evidence that (1) T2DM causes brain insulin resistance, oxidative stress, and cognitive impairment, but its aggregate effects fall far short of mimicking AD; (2) extensive disturbances in brain insulin and insulin-like growth factor (IGF) signaling mechanisms represent early and progressive abnormalities and could account for the majority of molecular, biochemical, and histopathological lesions in AD; (3) experimental brain diabetes produced by intracerebral administration of streptozotocin shares many features with AD, including cognitive impairment and disturbances in acetylcholine homeostasis; and (4) experimental brain diabetes is treatable with insulin sensitizer agents, i.e., drugs currently used to treat T2DM. We conclude that the term “type 3 diabetes” accurately reflects the fact that AD represents a form of diabetes that selectively involves the brain and has molecular and biochemical features that overlap with both type 1 diabetes mellitus and T2DM.     

Diabetes of the exocrine pancreas

Diabetes of the exocrine pancreas (DEP) is a form of diabetes that occurs due to pancreatic disease. It is far more common than has been previously considered, with a recent study showing 1.8% of adults with new‐onset diabetes should have been classified as DEP. The majority is misdiagnosed as type 2 diabetes mellitus (T2DM). Patients with DEP exhibit varying degrees of exocrine and endocrine dysfunction. Damage to the islet of Langerhans effects the secretion of hormones from the β, α, and pancreatic polypeptide cells; the combination of low insulin, glucagon, and pancreatic polypeptide contributes to rapid fluctuations in glucose levels. This form of “brittle diabetes” may result in the poorer glycemic control observed in patients with DEP, when compared with those with T2DM. Diabetes of the exocrine pancreas has a different natural history to other forms of diabetes; patients are more likely to require early insulin initiation compared with those with T2DM. Therefore, individuals with DEP should be advised about the symptoms of decompensated hyperglycemia, although they are less likely to develop ketoacidosis. Clinicians should screen for DEP in patients with acute or chronic pancreatitis, following pancreatic resection, or with co‐existing cystic fibrosis or hemochromatosis. Incident diabetes may herald the onset of pancreatic ductal carcinoma in a small subset of patients. Once identified, patients with DEP can benefit from specific lifestyle advice, pancreatic enzyme replacement therapy, metformin treatment, appropriate insulin dosing, and monitoring. Further research is needed to establish the ideal treatment regimens to provide optimal clinical outcomes for this unique form of diabetes.     

Undeniable need for ultrafast-acting insulin: the pediatric perspective

Insulin therapy in youth with type 1 diabetes mellitus (T1DM) poses a special challenge because childhood is an unsteady state with increasing weight, height, and caloric needs, leading to varying insulin requirements. The current rapid-acting insulin analogs are not as fast and short-acting as needed to meet these challenges. This review describes the unique characteristics of insulin action in youth with T1DM based on previously published euglycemic clamp studies. It also explains the rationale behind the need for ultrafast-acting insulins to advance open- and closed-loop insulin therapy for the pediatric population with diabetes. Lastly, it briefly summarizes ongoing and future projects to accelerate insulin action in youth with T1DM.     

Equivalent insulin resistance in latent autoimmune diabetes in adults (LADA) and type 2 diabetic patients

Insulin resistance is a primary component in the pathophysiology of type 2 diabetes. In latent autoimmune diabetes in adults (LADA), insulin resistance has been reported to be significantly lower than in autoantibody-negative type 2 diabetes (T2DM), but whether this might be related to differences in body mass index (BMI) has not been excluded. Furthermore, previous studies have used limiting inclusive criteria for LADA, requiring only the presence of GADA or IA-2A. To apply more inclusive criteria for LADA, consistent with recent recommendations, we defined LADA by clinical manifestations characteristic of T2DM, but with the presence of any combination of GADA, IA-2A, ICA, or IAA. We recruited 43 LADA patients, 70 T2DM patients, and 150 non-diabetic controls. Insulin resistance was assessed by both the homeostasis model assessment and the quantitative insulin sensitivity check index, and BMI was calculated. We found that insulin resistance in LADA is equivalent to that of T2DM. When insulin resistance is assessed as a function of BMI, both diabetic populations demonstrated an insulin resistance equally greater than normal controls. The interaction between insulin resistance and BMI in the two diabetic groups was significantly different from that demonstrated in non-diabetic controls. In summary, LADA demonstrates insulin resistance of similar magnitude to T2DM, but with the concurrent component of an immune attack against the pancreatic beta-cells. LADA patients may be at significant risk for metabolic consequences of insulin resistance other than glucose metabolism, such as those described in the metabolic syndrome. As complications and treatment regimens specific to LADA are realized, improved means of identification of LADA will become increasingly important.     

基于中国2型糖尿病患者的胰岛素分泌特点选择适宜的起始胰岛素治疗

在T2DM发生和发展过程中,同时存在胰岛素分泌减少和IS减弱的问题.不同种族人群的胰岛素分泌和IS缺陷呈现不同特征,中国T2DM患者更突出表现为胰岛素分泌不足,且以早相分泌缺陷为主,血糖异常以餐后血糖升高为主要表现.针对中国T2DM患者的上述特点,应适时起始胰岛素治疗,并给予可同时补充基础胰岛素分泌和早相分泌缺陷的治疗.多项随机临床试验和观察性研究表明,预混胰岛素类似物门冬胰岛素30（BIAsp30）每日两次起始治疗具有很好的降糖疗效,且低血糖风险低,体重变化不明显.BIAsp30每日一次注射也可作为起始治疗的更多选择.此外,BIAsp30的治疗方案调整简单方便,在从起始到强化的胰岛素治疗全程中,皆可方便、灵活地使用.     

Diabetes and pancreatic cancer

Epidemiological studies clearly indicate that the risk of pancreatic cancer (PC) is increased in diabetic patients, but most studies focus on overall diabetes or type 2 diabetes mellitus (T2DM), and there are few studies on the risks of type 1 and type 3c (secondary) diabetes. Possible mechanisms for increased cancer risk in diabetes include cellular proliferative effects of hyperglycemia, hyperinsulinemia, and abnormalities in insulin/IGF receptor pathways. Recently, insulin and insulin secretagogues have been observed to increase the PC risk, while metformin treatment reduces the cancer risk in diabetic subjects. In addition, anticancer drugs used to treat PC may either cause diabetes or worsen coexisting diabetes. T3cDM has emerged as a major subset of diabetes and may have the highest risk of pancreatic carcinoma especially in patients with chronic pancreatitis. T3cDM is also a consequence of PC in at least 30% of patients. Distinguishing T3cDM from the more prevalent T2DM among new-onset diabetic patients can be aided by an assessment of clinical features and confirmed by finding a deficiency in postprandial pancreatic polypeptide release. In conclusion, diabetes and PC have a complex relationship that requires more clinical attention. The risk of developing PC can be reduced by aggressive prevention and treatment of T2DM and obesity and the prompt diagnosis of T3cDM may allow detection of a tumor at a potentially curable stage.     

First-phase insulin secretion: can its evaluation direct therapeutic approaches?

Our work is aimed at unraveling the role of the first-phase insulin secretion in the natural history of type 2 diabetes mellitus (T2DM) and its interrelationship with insulin resistance and with β cell function and mass. Starting from pathophysiology, we investigate the impact of impaired secretion on glucose homeostasis and explore postmeal hyperglycemia as the main clinical feature, underlining its relevance in the management of the disease. We also review dietary and pharmacological approaches aimed at improving early secretory defects and restoring residual β cell function. Furthermore, we discuss possible approaches to detect early secretory defects in clinical practice. By providing a journey through human and animal data, we attempt a unification of the recent evidence in an effort to offer a new outlook on β cell secretion.     

Heat shock response regulates insulin sensitivity and glucose homeostasis: pathophysiological impact and therapeutic potential

A large and increasing number of people in all over the world suffer from obesity, metabolic syndrome (MS) and type 2 diabetes mellitus (T2DM). Attenuation of the heat shock response (HSR), which was originally identified as a cellular defense mechanism, is one of the key factors involved in the deterioration of metabolic abnormalities. On the other hand, activating the HSR increases heat shock protein 72 (HSP72) expression and improves insulin resistance and glucose homeostasis in rodents and humans, possibly by inhibiting the activation of stress kinases such as c-jun terminal kinase (JNK) and inhibitor of kappa B kinase β (IKKβ). These approaches may also reduce inflammatory cytokine production and prevent the onset of atherogenic complications. This review focuses on the physiological effects of HSR in regulating insulin sensitivity and hyperglycemia, and the potential to target the HSR system for the treatment of MS and T2DM, as well as other cellular stress-related diseases.     

胰岛素在2型糖尿病合并冠心病中作用的研究进展

与2型糖尿病相关的冠心病的发病率及死亡率呈上升趋势,相关研究表明胰岛素自身可能存在双向性作用,而在2型糖尿病患者中胰岛素对冠状动脉粥样硬化病变的作用仍然存在很大的争议。近年来,多项大型的观察性研究以及少量的随机对照性研究结果也不尽一致。目前,胰岛素在2型糖尿病合并冠心病中的作用机制较为流行“双信号通路”假说。进一步研究和阐明胰岛素在2型糖尿病合并冠心病中的作用显得尤为重要。     

Combining GLP‐1 receptor agonists with insulin: therapeutic rationales and clinical findings

Due to the increasing prevalence of type 2 diabetes mellitus (T2DM), the emergent trend towards diagnosis in younger patients and the progressive nature of this disease, many more patients than before now require insulin to maintain glycaemic control. However, there is a degree of inertia among physicians and patients regarding the initiation and intensification of insulin therapy, in part due to concerns about the associated weight gain and increased risk of hypoglycaemia. Glucagon‐like peptide‐1 receptor agonists (GLP‐1RAs) increase insulin release and suppress glucagon secretion in a glucose‐dependent manner, thus conferring glycaemic control with a low incidence of hypoglycaemia. GLP‐1RAs also promote weight loss, and have beneficial effects on markers of β cell function, lipid levels, blood pressure and cardiovascular risk markers. However, the durability of their effectiveness is unknown and, compared with insulin, the antihyperglycaemic efficacy of GLP‐1RAs is limited. The combination of a GLP‐1RA and insulin might thus be highly effective for optimal glucose control, ameliorating the adverse effects typically associated with insulin. Data from clinical studies support the therapeutic potential of GLP‐1RA–insulin combination therapy, typically showing beneficial effects on glycaemic control and body weight, with a low incidence of hypoglycaemia and, in established insulin therapy, facilitating reductions in insulin dose. In this review, the physiological and pharmacological rationale for using GLP‐1RA and insulin therapies in combination is discussed, and data from clinical studies that have assessed the efficacy and safety of this treatment strategy are outlined.     

Genetics of diabetes – Are we missing the genes or the disease?

Diabetes is a group of metabolic diseases characterized by hyperglycemia resulting from defects in insulin secretion, insulin action, or both. The chronic hyperglycemia of diabetes is associated with long-term damage, dysfunction, and failure of different organs, especially the eyes, kidneys, nerves, heart, and blood vessels. Several pathogenic processes are involved in the development of diabetes. These range from autoimmune destruction of the beta-cells of the pancreas with consequent insulin deficiency to abnormalities that result in resistance to insulin action (American Diabetes Association, 2011). The vast majority of cases of diabetes fall into two broad categories. In type 1 diabetes (T1D), the cause is an absolute deficiency of insulin secretion, whereas in type 2 diabetes (T2D), the cause is a combination of resistance to insulin action and an inadequate compensatory insulin secretory response. However, the subdivision into two main categories represents a simplification of the real situation, and research during the recent years has shown that the disease is much more heterogeneous than a simple subdivision into two major subtypes assumes.