Type 1 diabetes

Last updated

Type 1 diabetes
Other namesDiabetes mellitus type 1, insulin-dependent diabetes, juvenile diabetes
Blue circle for diabetes.svg
A blue circle, the symbol for diabetes
Pronunciation
Specialty Endocrinology
Symptoms Frequent urination, increased thirst, weight loss
Complications Diabetic ketoacidosis, severe hypoglycemia, cardiovascular disease, and damage to the eyes, kidneys, and nerves
Usual onsetAt any age; over days to weeks
DurationLifelong
CausesBody does not produce enough insulin
Risk factors Family history, celiac disease, autoimmune diseases
Diagnostic method High blood sugar levels, autoantibodies targeting insulin-producing cells
Prevention Teplizumab
TreatmentMonitoring blood sugar, injected insulin, managing diet
Prognosis 10-12 years shorter life expectancy [1] [2] [3]
Frequency11–22 million cases globally [4]

Type 1 diabetes (T1D), formerly known as juvenile diabetes, is an autoimmune disease that occurs when pancreatic cells (beta cells) are destroyed by the body's immune system. [5] In healthy persons, beta cells produce insulin. Insulin is a hormone required by the body to store and convert blood sugar into energy. [6] T1D results in high blood sugar levels in the body prior to treatment. [7] Common symptoms include frequent urination, increased thirst, increased hunger, weight loss, and other complications. [5] [8] Additional symptoms may include blurry vision, tiredness, and slow wound healing (owing to impaired blood flow). [6] While some cases take longer, symptoms usually appear within weeks or a few months. [9] [7]

Contents

The cause of type 1 diabetes is not completely understood, though there have been recent studies that suggest linkage with HLA-DR3/DR4-DQ8. [10] [5] Further, it is believed to involve a combination of genetic and environmental factors. [11] [7] The underlying mechanism involves an autoimmune destruction of the insulin-producing beta cells in the pancreas. [6] Diabetes is diagnosed by testing the level of sugar or glycated hemoglobin (HbA1C) in the blood. [12] [13]

Type 1 diabetes can typically be distinguished from type 2 by testing for the presence of autoantibodies [12] and/or declining levels/absence of C-peptide.

There is no known way to prevent type 1 diabetes. [5] Treatment with insulin is required for survival. [7] Insulin therapy is usually given by injection just under the skin but can also be delivered by an insulin pump. [14] A diabetic diet, exercise, and lifestyle modifications are considered cornerstones of management. [6] If left untreated, diabetes can cause many complications. [5] Complications of relatively rapid onset include diabetic ketoacidosis and nonketotic hyperosmolar coma. [12] Long-term complications include heart disease, stroke, kidney failure, foot ulcers, and damage to the eyes. [5] Furthermore, since insulin lowers blood sugar levels, complications may arise from low blood sugar if more insulin is taken than necessary. [12]

Type 1 diabetes makes up an estimated 5–10% of all diabetes cases. [15] The number of people affected globally is unknown, although it is estimated that about 80,000 children develop the disease each year. [12] Within the United States the number of people affected is estimated to be one to three million. [12] [16] Rates of disease vary widely, with approximately one new case per 100,000 per year in East Asia and Latin America and around 30 new cases per 100,000 per year in Scandinavia and Kuwait. [17] [18] It typically begins in children and young adults but can begin at any age. [7] [19]

Signs and symptoms

Overview of the most significant symptoms of diabetes Main symptoms of diabetes.png
Overview of the most significant symptoms of diabetes

Type 1 diabetes can develop at any age, with a peak in onsets during childhood and adolescence. Adult onsets on the other hand are often initially misdiagnosed as type 2. [19] [20] [21] [22] The major sign of type 1 diabetes is very high blood sugar, which typically manifests in children as a few days to weeks of polyuria (increased urination), polydipsia (increased thirst), and weight loss after being exposed to a triggering factor including infections, strenuous exercise, dehydration. [23] [24] [25] [26] [27] Children may also experience increased appetite, blurred vision, bedwetting, recurrent skin infections, candidiasis of the perineum, irritability, and reduced scholastic performance. [26] [27] Adults with type 1 diabetes tend to have more varied symptoms, which come on over months, rather than days or weeks. [28] [27]

Prolonged lack of insulin can cause diabetic ketoacidosis, characterized by fruity breath odor, mental confusion, persistent fatigue, dry or flushed skin, abdominal pain, nausea or vomiting, and labored breathing. [28] [29] Blood and urine tests reveal unusually high glucose and ketones in the blood and urine. [30] Untreated ketoacidosis can rapidly progress to loss of consciousness, coma, and death. [30] The percentage of children whose type 1 diabetes begins with an episode of diabetic ketoacidosis varies widely by geography, as low as 15% in parts of Europe and North America, and as high as 80% in the developing world. [30]

Causes

Type 1 diabetes is caused by the destruction of β-cells—the only cells in the body that produce insulin—and the consequent progressive insulin deficiency. Without insulin, the body cannot respond effectively to increases in blood sugar. Due to this, people with diabetes have persistent hyperglycemia. [31] In 70–90% of cases, β-cells are destroyed by one's own immune system, for reasons that are not entirely clear. [31] The best-studied components of this autoimmune response are β-cell-targeted antibodies that begin to develop in the months or years before symptoms arise. [31] Typically, someone will first develop antibodies against insulin or the protein GAD65, followed eventually by antibodies against the proteins IA-2, IA-2β, and/or ZNT8. People with a higher level of these antibodies, especially those who develop them earlier in life, are at higher risk for developing symptomatic type 1 diabetes. [32] The trigger for the development of these antibodies remains unclear. [33] A number of explanatory theories have been put forward, and the cause may involve genetic susceptibility, a diabetogenic trigger, and/or exposure to an antigen. [34] The remaining 10–30% of type 1 diabetics have β-cell destruction but no sign of autoimmunity; this is called idiopathic type 1 diabetes and its cause is unknown. [31]

Environmental

Various environmental risks have been studied in an attempt to understand what triggers β-cell destroying autoimmunity. Many aspects of environment and life history are associated with slight increases in type 1 diabetes risk, however the connection between each risk and diabetes often remains unclear. Type 1 diabetes risk is slightly higher for children whose mothers are obese or older than 35, or for children born by caesarean section. [35] Similarly, a child's weight gain in the first year of life, total weight, and BMI are associated with slightly increased type 1 diabetes risk. [35] Some dietary habits have also been associated with type 1 diabetes risk, namely consumption of cow's milk and dietary sugar intake. [35] Animal studies and some large human studies have found small associations between type 1 diabetes risk and intake of gluten or dietary fiber; however, other large human studies have found no such association. [35] Many potential environmental triggers have been investigated in large human studies and found to be unassociated with type 1 diabetes risk including duration of breastfeeding, time of introduction of cow milk into the diet, vitamin D consumption, blood levels of active vitamin D, and maternal intake of omega-3 fatty acids. [35] [36]

A longstanding hypothesis for an environmental trigger is that some viral infection early in life contributes to type 1 diabetes development. Much of this work has focused on enteroviruses, with some studies finding slight associations with type 1 diabetes, and others finding none. [37] Large human studies have searched for, but not yet found an association between type 1 diabetes and various other viral infections, including infections of the mother during pregnancy. [37] Conversely, some have postulated that reduced exposure to pathogens in the developed world increases the risk of autoimmune diseases, often called the hygiene hypothesis. Various studies of hygiene-related factors—including household crowding, daycare attendance, population density, childhood vaccinations, antihelminth medication, and antibiotic usage during early life or pregnancy—show no association with type 1 diabetes. [38]

Genetics

Type 1 diabetes is partially caused by genetics, and family members of type 1 diabetics have a higher risk of developing the disease themselves. In the general population, the risk of developing type 1 diabetes is around 1 in 250. For someone whose parent has type 1 diabetes, the risk rises to 1–9%. If a sibling has type 1 diabetes, the risk is 6–7%. If someone's identical twin has type 1 diabetes, they have a 30–70% risk of developing it themselves. [39]

About half of the disease's heritability is due to variations in three HLA class II genes involved in antigen presentation: HLA-DRB1 , HLA-DQA1 , and HLA-DQB1 . [39] The variation patterns associated with increased risk of type 1 diabetes are called HLA-DR3 and HLA-DR4-HLA-DQ8, and are common in people of European descent. A pattern associated with reduced risk of type 1 diabetes is called HLA-DR15-HLA-DQ6. [39] Large genome-wide association studies have identified dozens of other genes associated with type 1 diabetes risk, mostly genes involved in the immune system. [39]

Chemicals and drugs

Some medicines can reduce insulin production or damage β cells, resulting in disease that resembles type 1 diabetes. The antiviral drug didanosine triggers pancreas inflammation in 5 to 10% of those who take it, sometimes causing lasting β-cell damage. [40] Similarly, up to 5% of those who take the anti-protozoal drug pentamidine experience β-cell destruction and diabetes. [40] Several other drugs cause diabetes by reversibly reducing insulin secretion, namely statins (which may also damage β cells), the post-transplant immunosuppressants cyclosporin A and tacrolimus, the leukemia drug L-asparaginase, and the antibiotic gatifloxicin. [40] [41]

Diagnosis

Diabetes is typically diagnosed by a blood test showing unusually high blood sugar. The World Health Organization defines diabetes as blood sugar levels at or above 7.0 mmol/L (126 mg/dL) after fasting for at least eight hours, or a glucose level at or above 11.1 mmol/L (200 mg/dL) two hours after an oral glucose tolerance test. [42] The American Diabetes Association additionally recommends a diagnosis of diabetes for anyone with symptoms of hyperglycemia and blood sugar at any time at or above 11.1 mmol/L, or glycated hemoglobin (hemoglobin A1C) levels at or above 48 mmol/mol. [43]

Once a diagnosis of diabetes is established, type 1 diabetes is distinguished from other types by a blood test for the presence of autoantibodies that target various components of the beta cell. [44] The most commonly available tests detect antibodies against glutamic acid decarboxylase, the beta cell cytoplasm, or insulin, each of which are targeted by antibodies in around 80% of type 1 diabetics. [44] Some healthcare providers also have access to tests for antibodies targeting the beta cell proteins IA-2 and ZnT8; these antibodies are present in around 58% and 80% of type 1 diabetics respectively. [44] Some also test for C-peptide, a byproduct of insulin synthesis. Very low C-peptide levels are suggestive of type 1 diabetes. [44]

Management

The mainstay of type 1 diabetes treatment is the regular injection of insulin to manage hyperglycemia. [45] Injections of insulin via subcutaneous injection using either a syringe or an insulin pump are necessary multiple times per day, adjusting dosages to account for food intake, blood glucose levels, and physical activity. [45] The goal of treatment is to maintain blood sugar in a normal range—80–130 mg/dL before a meal; <180 mg/dL after—as often as possible. [46] To achieve this, people with diabetes often monitor their blood glucose levels at home. Around 83% of type 1 diabetics monitor their blood glucose by capillary blood testing: pricking the finger to draw a drop of blood, and determining blood glucose with a glucose meter. [47] The American Diabetes Association recommends testing blood glucose around 6–10 times per day: before each meal, before exercise, at bedtime, occasionally after a meal, and any time someone feels the symptoms of hypoglycemia. [47] Around 17% of people with type 1 diabetes use a continuous glucose monitor, a device with a sensor under the skin that constantly measures glucose levels and communicates those levels to an external device. [47] Continuous glucose monitoring is associated with better blood sugar control than capillary blood testing alone; however, continuous glucose monitoring tends to be substantially more expensive. [47] Healthcare providers can also monitor someone's hemoglobin A1C levels which reflect the average blood sugar over the last three months. [48] The American Diabetes Association recommends a goal of keeping hemoglobin A1C levels under 7% for most adults and 7.5% for children. [48] [49]

The goal of insulin therapy is to mimic normal pancreatic insulin secretion: low levels of insulin constantly present to support basic metabolism, plus the two-phase secretion of additional insulin in response to high blood sugar, then an extended phase of continued insulin secretion. [50] This is accomplished by combining different insulin preparations that act with differing speeds and durations. The standard of care for type 1 diabetes is a bolus of rapid-acting insulin 10–15 minutes before each meal or snack, and as-needed to correct hyperglycemia. [50] In addition, constant low levels of insulin are achieved with one or two daily doses of long-acting insulin, or by steady infusion by an insulin pump. [50] The exact dose of insulin appropriate for each injection depends on the content of the meal/snack, and the individual person's sensitivity to insulin, and is therefore typically calculated by the individual with diabetes or a family member by hand or assistive device (calculator, chart, mobile app, etc.). [50] People unable to manage these intensive insulin regimens are sometimes prescribed alternate plans relying on mixtures of rapid- or short-acting and intermediate-acting insulin, which are administered at fixed times along with meals of pre-planned times and carbohydrate composition. [50] The National Institute for Health and Care Excellence now recommends closed-loop insulin systems as an option for all women with type 1 diabetes who are pregnant or planning pregnancy. [51] [52] [53]

A non-insulin medication approved by the U.S. Food and Drug Administration for treating type 1 diabetes is the amylin analog pramlintide, which replaces the beta-cell hormone amylin. Addition of pramlintide to mealtime insulin injections reduces the boost in blood sugar after a meal, improving blood sugar control. [54] Occasionally, metformin, GLP-1 receptor agonists, dipeptidyl peptidase-4 inhibitors, or SGLT2 inhibitor are prescribed off-label to people with type 1 diabetes, although fewer than 5% of type 1 diabetics use these drugs. [45]

Lifestyle

Besides insulin, the major way type 1 diabetics control their blood sugar is by learning how various foods impact their blood sugar levels. This is primarily done by tracking their intake of carbohydrates, the type of food with the greatest impact on blood sugar. [55] In general, people with type 1 diabetes are advised to follow an individualized eating plan rather than a pre-decided one. [56] There are camps for children to teach them how and when to use or monitor their insulin without parental help. [57] As psychological stress may have a negative effect on diabetes, a number of measures have been recommended including: exercising, taking up a new hobby, or joining a charity, among others. [58]

Regular exercise is important for maintaining general health, though the effect of exercise on blood sugar can be challenging to predict. [59] Exogenous insulin can drive down blood sugar, leaving those with diabetes at risk of hypoglycemia during and immediately after exercise, then again seven to eleven hours after exercise (called the "lag effect"). [59] Conversely, high-intensity exercise can result in a shortage of insulin, and consequent hyperglycemia. [59] The risk of hypoglycemia can be managed by beginning exercise when blood sugar is relatively high (above 100 mg/dL), ingesting carbohydrates during or shortly after exercise, and reducing the amount of injected insulin within two hours of the planned exercise. [59] Similarly, the risk of exercise-induced hyperglycemia can be managed by avoiding exercise when insulin levels are very low, when blood sugar is extremely high (above 350 mg/dL), or when one feels unwell. [59]

While there is a lot of research on diabetes in youth, it is important to keep progressing, expanding and building our knowledge of Type 1 Diabetes and Type 2 Diabetes.  T1DM is an autoimmune disease that prevents the pancreas from producing insulin, which helps the body regulate blood sugar levels.  T2DM is a chronic disease that occurs when your body produces insulin but doesn’t use it properly or doesn’t produce enough, resulting in high blood sugar levels or hyperglycemia.  There is not a definitive answer on what type of exercise is the best for either of these metabolic diseases, but the physical activity guidelines state that children should get at least 60 minutes of moderate to vigorous intensity activity each day, which is the same for children without T1DM or T2DM. Addressing challenges is vital for enhancing care and health outcomes for pediatric diabetes patients.  Prior to engaging in physical activity, it is important to know your diagnosis and be able to manage it properly.

When focusing on the type of exercise, the first two studies explicitly focus on the role of exercise in managing diabetes, with the first study exploring the benefits of HIIT for psychological and physical health in T1DM and the second focusing on the effectiveness of exercise in T2DM. [60] [61] The third study, however, discusses the implications of diabetes misdiagnosis, which indirectly relates to exercise by stressing the importance of managing diabetes properly before engaging in physical activity. [62]   For the impacts that exercise has, the first and second studies highlight exercise as a beneficial tool for managing diabetes, but they present different outcomes. [60] [61] In T2DM, exercise is shown to be a powerful tool for improving glycemic control and reducing cardiovascular risk. In T1DM, while exercise can improve lipid profiles and other aspects of health, it doesn't necessarily lead to better blood sugar control, and there are additional barriers such as fear of hypoglycemia. [61] The first study, however, finds that HIIT can still be effective in improving psychological well-being and exercise adherence for T1DM, showing that exercise has a broader benefit beyond just metabolic control. [60]   All three studies provide insight into the barriers to exercise in diabetes. The first study mentions fear of hypoglycemia and low motivation as challenges for T1DM, while the second reinforces the issue of blood sugar fluctuations and the unpredictability of exercise for those with T1DM. [60] [61] The third study is more focused on the broader implications of misdiagnosis, but it implies that exercise could be counterproductive or harmful if a child's diabetes is misdiagnosed. [62] When looking at other factors such as psychological and motivational, the first study places a strong emphasis on psychological factors like exercise enjoyment and intrinsic motivation, suggesting that overcoming psychological barriers is key to exercise adherence in T1DM. [60] In contrast, the second study is more focused on the physical and metabolic effects of exercise, with less emphasis on motivation or enjoyment, although it does briefly mention that many individuals with T1DM are still motivated to exercise by the health benefits or inspiration from others. [61]   Clinical implications show the first two studies focus on the effectiveness of exercise for specific diabetes types, while the third study highlights the importance of correct diagnosis for appropriate care. [60] [62] [61] This suggests that exercise programs must be tailored not only to the type of diabetes but also to the individual’s health status and management plan. The third study emphasizes that without proper diagnosis and management, exercise recommendations could be inappropriate or unsafe. [62] In summary, while the first two studies explore the benefits and challenges of exercise in different diabetes types, the third study stresses the importance of accurate diagnosis and management before engaging in physical activity. Together, these studies highlight the complex interactions between exercise, diabetes type, treatment, and individual challenges.

Transplant

In some cases, people can receive transplants of the pancreas or isolated islet cells to restore insulin production and alleviate diabetic symptoms. Transplantation of the whole pancreas is rare, due in part to the few available donor organs, and to the need for lifelong immunosuppressive therapy to prevent transplant rejection. [63] [64] The American Diabetes Association recommends pancreas transplant only in people who also require a kidney transplant, or who struggle to perform regular insulin therapy and experience repeated severe side effects of poor blood sugar control. [64] Most pancreas transplants are done simultaneously with a kidney transplant, with both organs from the same donor. [65] The transplanted pancreas continues to function for at least five years in around three quarters of recipients, allowing them to stop taking insulin. [66]

Transplantations of islets alone have become increasingly common. [67] Pancreatic islets are isolated from a donor pancreas, then injected into the recipient's portal vein from which they implant onto the recipient's liver. [68] In nearly half of recipients, the islet transplant continues to work well enough that they still do not need exogenous insulin five years after transplantation. [69] If a transplant fails, recipients can receive subsequent injections of islets from additional donors into the portal vein. [68] Like with whole pancreas transplantation, islet transplantation requires lifelong immunosuppression and depends on the limited supply of donor organs; it is therefore similarly limited to people with severe poorly controlled diabetes and those who have had or are scheduled for a kidney transplant. [67] [70]

Donislecel (Lantidra) allogeneic (donor) pancreatic islet cellular therapy was approved for medical use in the United States in June 2023. [71]

Pathogenesis

Type 1 diabetes is a result of the destruction of pancreatic beta cells, although what triggers that destruction remains unclear. [72] People with type 1 diabetes tend to have more CD8+ T-cells and B-cells that specifically target islet antigens than those without type 1 diabetes, suggesting a role for the adaptive immune system in beta cell destruction. [72] [73] Type 1 diabetics also tend to have reduced regulatory T cell function, which may exacerbate autoimmunity. [72] Destruction of beta cells results in inflammation of the islet of Langerhans, called insulitis. These inflamed islets tend to contain CD8+ T-cells and – to a lesser extent – CD4+ T cells. [72] Abnormalities in the pancreas or the beta cells themselves may also contribute to beta-cell destruction. The pancreases of people with type 1 diabetes tend to be smaller, lighter, and have abnormal blood vessels, nerve innervations, and extracellular matrix organization. [74] In addition, beta cells from people with type 1 diabetes sometimes overexpress HLA class I molecules (responsible for signaling to the immune system) and have increased endoplasmic reticulum stress and issues with synthesizing and folding new proteins, any of which could contribute to their demise. [74]

The mechanism by which the beta cells actually die likely involves both necroptosis and apoptosis, induced or exacerbated by CD8+ T-cells and macrophages. [75] Necroptosis can be triggered by activated T cells – which secrete toxic granzymes and perforin – or indirectly as a result of reduced blood flow or the generation of reactive oxygen species. [75] As some beta cells die, they may release cellular components that amplify the immune response, exacerbating inflammation and cell death. [75] Pancreases from people with type 1 diabetes also have signs of beta cell apoptosis, linked to activation of the janus kinase and TYK2 pathways. [75]

Partial ablation of beta-cell function is enough to cause diabetes; at diagnosis, people with type 1 diabetes often still have detectable beta-cell function. Once insulin therapy is started, many people experience a resurgence in beta-cell function, and can go some time with little-to-no insulin treatment – called the "honeymoon phase". [74] This eventually fades as beta-cells continue to be destroyed, and insulin treatment is required again. [74] Beta-cell destruction is not always complete, as 30–80% of type 1 diabetics produce small amounts of insulin years or decades after diagnosis. [74]

Alpha cell dysfunction

Onset of autoimmune diabetes is accompanied by impaired ability to regulate the hormone glucagon, [76] which acts in antagonism with insulin to regulate blood sugar and metabolism. Progressive beta cell destruction leads to dysfunction in the neighboring alpha cells which secrete glucagon, exacerbating excursions away from euglycemia in both directions; overproduction of glucagon after meals causes sharper hyperglycemia, and failure to stimulate glucagon upon hypoglycemia prevents a glucagon-mediated rescue of glucose levels. [77]

Hyperglucagonemia

Onset of type 1 diabetes is followed by an increase in glucagon secretion after meals. Increases have been measured up to 37% during the first year of diagnosis, while C-peptide levels (indicative of islet-derived insulin), decline by up to 45%. [78] Insulin production will continue to fall as the immune system destroys beta cells, and islet-derived insulin will continue to be replaced by therapeutic exogenous insulin. Simultaneously, there is measurable alpha cell hypertrophy and hyperplasia in the early stage of the disease, leading to expanded alpha cell mass. This, together with failing beta cell insulin secretion, begins to account for rising glucagon levels that contribute to hyperglycemia. [77] Some researchers believe glucagon dysregulation to be the primary cause of early stage hyperglycemia. [79] Leading hypotheses for the cause of postprandial hyperglucagonemia suggest that exogenous insulin therapy is inadequate to replace the lost intraislet signalling to alpha cells previously mediated by beta cell-derived pulsatile insulin secretion. [80] [81] Under this working hypothesis intensive insulin therapy has attempted to mimic natural insulin secretion profiles in exogenous insulin infusion therapies. [82] In young people with type 1 diabetes, unexplained deaths could be due to nighttime hypoglycemia triggering abnormal heart rhythms or cardiac autonomic neuropathy, damage to nerves that control the function of the heart.

Hypoglycemic glucagon impairment

Glucagon secretion is normally increased upon falling glucose levels, but normal glucagon response to hypoglycemia is blunted in type 1 diabetics. [83] [84] Beta cell glucose sensing and subsequent suppression of administered insulin secretion is absent, leading to islet hyperinsulinemia which inhibits glucagon release. [83] [85]

Autonomic inputs to alpha cells are much more important for glucagon stimulation in the moderate to severe ranges of hypoglycemia, yet the autonomic response is blunted in a number of ways. Recurrent hypoglycemia leads to metabolic adjustments in the glucose sensing areas of the brain, shifting the threshold for counter regulatory activation of the sympathetic nervous system to lower glucose concentration. [85] This is known as hypoglycemic unawareness. Subsequent hypoglycemia is met with impairment in sending of counter regulatory signals to the islets and adrenal cortex. This accounts for the lack of glucagon stimulation and epinephrine release that would normally stimulate and enhance glucose release and production from the liver, rescuing the diabetic from severe hypoglycemia, coma, and death. Numerous hypotheses have been produced in the search for a cellular mechanism of hypoglycemic unawareness, and a consensus has yet to be reached. [86] The major hypotheses are summarized in the following table: [87] [85] [86]

Mechanisms of hypoglycemic unawareness
Glycogen supercompensationIncreased glycogen stores in astrocytes might contribute supplementary glycosyl units for metabolism, counteracting the central nervous system perception of hypoglycemia.
Enhanced glucose metabolismAltered glucose transport and enhanced metabolic efficiency upon recurring hypoglycemia relieves oxidative stress that would activate sympathetic response.
Alternative fuel hypothesisDecreased reliance on glucose, supplementation of lactate from astrocytes, or ketones meet metabolic demands and reduce stress to brain.
Brain neuronal communication Hypothalamic inhibitory GABA normally decreases during hypoglycemia, disinhibiting signals for sympathetic tone. Recurrent episodes of hypoglycemia result in increased basal GABA which fails to decrease normally during subsequent hypoglycemia. Inhibitory tone remains and sympathetic tone is not increased.

In addition, autoimmune diabetes is characterized by a loss of islet specific sympathetic innervation. [88] This loss constitutes an 80–90% reduction of islet sympathetic nerve endings, happens early in the progression of the disease, and is persistent through the life of the patient. [89] It is linked to the autoimmune aspect of type 1 diabetics and fails to occur in type 2 diabetics. Early in the autoimmune event, the axon pruning is activated in islet sympathetic nerves. Increased BDNF and ROS that result from insulitis and beta cell death stimulate the p75 neurotrophin receptor (p75NTR), which acts to prune off axons. Axons are normally protected from pruning by activation of tropomyosin receptor kinase A (Trk A) receptors by NGF, which in islets is primarily produced by beta cells. Progressive autoimmune beta cell destruction, therefore, causes both the activation of pruning factors and the loss of protective factors to the islet sympathetic nerves. This unique form of neuropathy is a hallmark of type 1 diabetes, and plays a part in the loss of glucagon rescue of severe hypoglycemia. [88]

Complications

The most pressing complication of type 1 diabetes are the always present risks of poor blood sugar control: severe hypoglycemia and diabetic ketoacidosis. Hypoglycemia – typically blood sugar below 70 mg/dL – triggers the release of epinephrine, and can cause people to feel shaky, anxious, or irritable. [90] People with hypoglycemia may also experience hunger, nausea, sweats, chills, headaches, dizziness, and a fast heartbeat. [90] Some feel lightheaded, sleepy, or weak. [90] Severe hypoglycemia can develop rapidly, causing confusion, coordination problems, loss of consciousness, and seizure. [90] [91] On average, people with type 1 diabetes experience a hypoglycemia event that requires assistance of another 16–20 times in 100 person-years, and an event leading to unconsciousness or seizure 2–8 times per 100 person-years. [91] The American Diabetes Association recommends treating hypoglycemia by the "15–15 rule": eat 15 grams of carbohydrates, then wait 15 minutes before checking blood sugar; repeat until blood sugar is at least 70 mg/dL. [90] Severe hypoglycemia that impairs someone's ability to eat is typically treated with injectable glucagon, which triggers glucose release from the liver into the bloodstream. [90] People with repeated bouts of hypoglycemia can develop hypoglycemia unawareness, where the blood sugar threshold at which they experience symptoms of hypoglycemia decreases, increasing their risk of severe hypoglycemic events. [92] Rates of severe hypoglycemia have generally declined due to the advent of rapid-acting and long-acting insulin products in the 1990s and early 2000s; [50] however, acute hypoglycemia still causes 4–10% of type 1 diabetes-related deaths. [91]

The other persistent risk is diabetic ketoacidosis – a state where lack of insulin results in cells burning fat rather than sugar, producing toxic ketones as a byproduct. [29] Ketoacidosis symptoms can develop rapidly, with frequent urination, excessive thirst, nausea, vomiting, and severe abdominal pain all common. [93] More severe ketoacidosis can result in labored breathing, and loss of consciousness due to cerebral edema. [93] People with type 1 diabetes experience diabetic ketoacidosis 1–5 times per 100 person-years, the majority of which result in hospitalization. [94] 13–19% of type 1 diabetes-related deaths are caused by ketoacidosis, [91] making ketoacidosis the leading cause of death in people with type 1 diabetes less than 58 years old. [94]

Long-term complications

In addition to the acute complications of diabetes, long-term hyperglycemia results in damage to the small blood vessels throughout the body. This damage tends to manifest particularly in the eyes, nerves, and kidneys causing diabetic retinopathy, diabetic neuropathy, and diabetic nephropathy respectively. [92] In the eyes, prolonged high blood sugar causes the blood vessels in the retina to become fragile. [95]

People with type 1 diabetes also have increased risk of cardiovascular disease, which is estimated to shorten the life of the average type 1 diabetic by 8–13 years. [96] Cardiovascular disease [97] as well as neuropathy [98] may have an autoimmune basis, as well. Women with type 1 DM have a 40% higher risk of death as compared to men with type 1 DM. [99]

About 12 percent of people with type 1 diabetes have clinical depression. [100] About 6 percent of people with type 1 diabetes also have celiac disease, but in most cases there are no digestive symptoms [101] [102] or are mistakenly attributed to poor control of diabetes, gastroparesis, or diabetic neuropathy. [102] In most cases, celiac disease is diagnosed after onset of type 1 diabetes. The association of celiac disease with type 1 diabetes increases the risk of complications, such as retinopathy and mortality. This association can be explained by shared genetic factors, and inflammation or nutritional deficiencies caused by untreated celiac disease, even if type 1 diabetes is diagnosed first. [101]

Urinary tract infection

People with diabetes show an increased rate of urinary tract infection. [103] The reason is bladder dysfunction is more common in people with diabetes than people without diabetes due to diabetes nephropathy. When present, nephropathy can cause a decrease in bladder sensation, which in turn, can cause increased residual urine, a risk factor for urinary tract infections. [104]

Sexual dysfunction

Sexual dysfunction in people with diabetes is often a result of physical factors such as nerve damage and poor circulation, and psychological factors such as stress and/or depression caused by the demands of the disease. [105] The most common sexual issues in males with diabetes are problems with erections and ejaculation: "With diabetes, blood vessels supplying the penis's erectile tissue can get hard and narrow, preventing the adequate blood supply needed for a firm erection. The nerve damage caused by poor blood glucose control can also cause ejaculate to go into the bladder instead of through the penis during ejaculation, called retrograde ejaculation. When this happens, semen leaves the body in the urine." Another cause of erectile dysfunction is reactive oxygen species created as a result of the disease. Antioxidants can be used to help combat this. [106] Sexual problems are common in women who have diabetes, [105] including reduced sensation in the genitals, dryness, difficulty/inability to orgasm, pain during sex, and decreased libido. Diabetes sometimes decreases estrogen levels in females, which can affect vaginal lubrication. Less is known about the correlation between diabetes and sexual dysfunction in females than in males. [105]

Oral contraceptive pills can cause blood sugar imbalances in women who have diabetes. Dosage changes can help address that, at the risk of side effects and complications. [105]

Women with type 1 diabetes show a higher than normal rate of polycystic ovarian syndrome (PCOS). [107] The reason may be that the ovaries are exposed to high insulin concentrations since women with type 1 diabetes can have frequent hyperglycemia. [108]

Autoimmune disorders

People with type 1 diabetes are at an increased risk for developing several autoimmune disorders, particularly thyroid problems – around 20% of people with type 1 diabetes have hypothyroidism or hyperthyroidism, typically caused by Hashimoto thyroiditis or Graves' disease respectively. [109] [91] Celiac disease affects 2–8% of people with type 1 diabetes, and is more common in those who were younger at diabetes diagnosis, and in white people. [109] Type 1 diabetics are also at increased risk of rheumatoid arthritis, lupus, autoimmune gastritis, pernicious anemia, vitiligo, and Addison's disease. [91] Conversely, complex autoimmune syndromes caused by mutations in the immunity-related genes AIRE (causing autoimmune polyglandular syndrome), FoxP3 (causing IPEX syndrome), or STAT3 include type 1 diabetes in their effects. [110]

Prevention

There is no way to prevent type 1 diabetes; [111] however, the development of diabetes symptoms can be delayed in some people who are at high risk of developing the disease. In 2022 the FDA approved an intravenous injection of teplizumab to delay the progression of type 1 diabetes in those older than eight who have already developed diabetes-related autoantibodies and problems with blood sugar control. In that population, the anti-CD3 monoclonal antibody teplizumab can delay the development of type 1 diabetes symptoms by around two years. [112]

In addition to anti-CD3 antibodies, several other immunosuppressive agents have been trialled with the aim of preventing beta cell destruction. Large trials of cyclosporine treatment suggested that cyclosporine could improve insulin secretion in those recently diagnosed with type 1 diabetes; however, people who stopped taking cyclosporine rapidly stopped making insulin, and cyclosporine's kidney toxicity and increased risk of cancer prevented people from using it long-term. [113] Several other immunosuppressive agents – prednisone, azathioprine, anti-thymocyte globulin, mycophenolate, and antibodies against CD20 and IL2 receptor α – have been the subject of research, but none have provided lasting protection from development of type 1 diabetes. [113] There have also been clinical trials attempting to induce immune tolerance by vaccination with insulin, GAD65, and various short peptides targeted by immune cells during type 1 diabetes; none have yet delayed or prevented development of disease. [114]

Several trials have attempted dietary interventions with the hope of reducing the autoimmunity that leads to type 1 diabetes. Trials that withheld cow's milk or gave infants formula free of bovine insulin decreased the development of β-cell-targeted antibodies, but did not prevent the development of type 1 diabetes. [115] Similarly, trials that gave high-risk individuals injected insulin, oral insulin, or nicotinamide did not prevent diabetes development. [115]

Other strategies under investigation for the prevention of type 1 diabetes include gene therapy, stem cell therapy, and modulation of the gut microbiome. Gene therapy approaches, while still in early stages, aim to alter genetic factors that contribute to beta-cell destruction by editing immune responses. [116] Stem cell therapies are also being researched, with the hope that they can either regenerate insulin-producing beta cells or protect them from immune attack. [117] Trials using stem cells to restore beta cell function or regulate immune responses are ongoing.

Modifying the gut microbiota through the use of probiotics, prebiotics, or specific diets has also gained attention. Some evidence suggests that the gut microbiome plays a role in immune regulation, and researchers are investigating whether altering the microbiome could reduce the risk of autoimmunity and, subsequently, type 1 diabetes. [118]

Tolerogenic therapies, which seek to induce immune tolerance to beta-cell antigens, are another area of interest. Techniques such as using dendritic cells or regulatory T cells engineered to promote tolerance to beta cells are being studied in clinical trials, though these approaches remain experimental. [119]

There is also a hypothesis that certain viral infections, particularly enteroviruses, may trigger type 1 diabetes in genetically predisposed individuals. Researchers are investigating whether vaccines targeting these viruses could reduce the risk of developing the disease. [120]

Combination immunotherapies are being explored as well, with the aim of achieving more durable immune protection by using multiple agents together. For example, anti-CD3 antibodies may be combined with other immunomodulatory agents such as IL-1 blockers or checkpoint inhibitors. [121]

Finally, researchers are studying how environmental factors such as infections, diet, and stress may affect immune regulation through epigenetic modifications. The hope is that targeting these epigenetic changes could delay or prevent the onset of type 1 diabetes in high-risk individuals. [122]

Epidemiology

Type 1 diabetes makes up an estimated 10–15% of all diabetes cases [32] or 11–22 million cases worldwide. [4] Symptoms can begin at any age, but onset is most common in children, with diagnoses slightly more common in 5 to 7 year olds, and much more common around the age of puberty. [123] [21] In contrast to most autoimmune diseases, type 1 diabetes is slightly more common in males than in females. [123]

In 2006, type 1 diabetes affected 440,000 children under 14 years of age and was the primary cause of diabetes in those less than 15 years of age. [124] [32]

Rates vary widely by country and region. Incidence is highest in Scandinavia, at 30–60 new cases per 100,000 children per year, intermediate in the U.S. and Southern Europe at 10–20 cases per 100,000 per year, and lowest in China, much of Asia, and South America at 1–3 cases per 100,000 per year. [36]

In the United States, type 1 and 2 diabetes affected about 208,000 youths under the age of 20 in 2015. Over 18,000 youths are diagnosed with Type 1 diabetes every year. Every year about 234,051 Americans die due to diabetes (type I or II) or diabetes-related complications, with 69,071 having it as the primary cause of death. [125]

In Australia, about one million people have been diagnosed with diabetes and of this figure 130,000 people have been diagnosed with type 1 diabetes. Australia ranks 6th-highest in the world with children under 14 years of age. Between 2000 and 2013, 31,895 new cases were established, with 2,323 in 2013, a rate of 10–13 cases per 100,00 people each year. Aboriginals and Torres Strait Islander people are less affected. [126] [127]

Since the 1950s, the incidence of type 1 diabetes has been gradually increasing across the world by an average 3–4% per year. [36] The increase is more pronounced in countries that began with a lower incidence of type 1 diabetes. [36] A single 2023 study suggested a relationship between COVID-19 infection and the incidence of type 1 diabetes in children; [128] confirmatory studies have not appeared to date.

Type 1 Diabetes in Youth

Type 1 diabetes, also known as "Juvenile-onset" Diabetes is increasing in children and adolescents under the age of 15. [129] Type 1 diabetes is an autoimmune disease where the body attacks the beta-cells produced by the pancreas; therefore, causing the body to have insulin deficiency. [130] Type 1 diabetes is mainly diagnosed in children, and the number of diagnoses is increasing all around the world. [130]

Management- Exercise

Children with type 1 diabetes typically manage their blood sugar levels with regular insulin injections; however, exercise can also play a vital role in the management of type 1 diabetes. [129] For youth with type 1 diabetes, exercise is correlated with greater blood sugar control. [130] HbA1c levels are reduced significantly when children with type 1 diabetes participate in structured exercise interventions. [130] In one study, Garcia-Hermoso and colleagues found that high-intensity exercise, concurrent training, exercise intervention lasting 24 weeks or more, and exercise sessions lasting 60 minutes or more caused greater HbA1c reduction in children with type 1 diabetes. [130] Garcia-Hermoso and colleagues also observed that exercise sessions lasting 60 minutes or more, high-intensity exercise, and concurrent training interventions led to a decrease in insulin dosage per day. [130] Additionally, Petschnig and colleagues looked at the effect of strength training on blood sugar levels and they found that children with type 1 diabetes who performed strength training exercises for 17 weeks did not experience any change in HbA1c levels, but after 32 weeks of training experienced a significant decrease in HbA1c levels. [129] Petschnig and colleagues also observed blood sugar levels decrease significantly following strength training sessions. [129] Finally, the Diabetes Research in Children Network Study Group found that children who participated in prolonged aerobic exercise after school experienced a decrease in plasma glucose levels 40% below their baseline values. [131] The Diabetes Research in Children Network Study Group observed blood sugar levels decrease rapidly in the first 15 minutes of exercise and continue to drop during the 75-minute session. [131] The Diabetes Research Group also found that after participating in prolonged aerobic exercise, 83% of participants had at least a 25% decrease in blood sugar levels. [131] High-intensity and concurrent training interventions, [130] strength training, [129] and prolonged aerobic exercise [131] all have been shown to help reduce HbA1c and blood glucose levels in children with type 1 diabetes; therefore, demonstrating that exercise plays a vital role in the management of type 1 diabetes. [129]

History

The connection between diabetes and pancreatic damage was first described by the German pathologist Martin Schmidt, who in a 1902 paper noted inflammation around the pancreatic islet of a child who had died of diabetes. [132] The connection between this inflammation and diabetes onset was further developed through the 1920s by Shields Warren, and the term "insulitis" was coined by Hanns von Meyenburg in 1940 to describe the phenomenon. [132]

Type 1 diabetes was described as an autoimmune disease in the 1970s, based on observations that autoantibodies against islets were discovered in diabetics with other autoimmune deficiencies. [133] It was also shown in the 1980s that immunosuppressive therapies could slow disease progression, further supporting the idea that type 1 diabetes is an autoimmune disorder. [134] The name juvenile diabetes was used earlier as it often first is diagnosed in childhood.

Society and culture

Type 1 and 2 diabetes was estimated to cause $10.5 billion in annual medical costs ($875 per month per diabetic) and an additional $4.4 billion in indirect costs ($366 per month per person with diabetes) in the U.S. [135] In the United States $245 billion every year is attributed to diabetes. Individuals diagnosed with diabetes have 2.3 times the health care costs as individuals who do not have diabetes. One in ten health care dollars are spent on individuals with type 1 and 2 diabetes. [125]

Research

Funding for research into type 1 diabetes originates from government, industry (e.g., pharmaceutical companies), and charitable organizations. Government funding in the United States is distributed via the National Institutes of Health, and in the UK via the National Institute for Health and Care Research or the Medical Research Council. The Juvenile Diabetes Research Foundation (JDRF), founded by parents of children with type 1 diabetes, is the world's largest provider of charity-based funding for type 1 diabetes research. [136] Other charities include the American Diabetes Association, Diabetes UK, Diabetes Research and Wellness Foundation, [137] Diabetes Australia, and the Canadian Diabetes Association.

Artificial pancreas

There has also been substantial effort to develop a fully automated insulin delivery system or "artificial pancreas" that could sense glucose levels and inject appropriate insulin without conscious input from the user. [138] Current "hybrid closed-loop systems" use a continuous glucose monitor to sense blood sugar levels, and a subcutaneous insulin pump to deliver insulin; however, due to the delay between insulin injection and its action, current systems require the user to initiate insulin before taking meals. [139] Several improvements to these systems are currently undergoing clinical trials in humans, including a dual-hormone system that injects glucagon in addition to insulin, and an implantable device that injects insulin intraperitoneally where it can be absorbed more quickly. [140]

Disease models

Various animal models of disease are used to understand the pathogenesis and etiology of type 1 diabetes. Currently available models of T1D can be divided into spontaneously autoimmune, chemically induced, virus induced and genetically induced. [141]

The nonobese diabetic (NOD) mouse is the most widely studied model of type 1 diabetes. [141] It is an inbred strain that spontaneously develops type 1 diabetes in 30–100% of female mice depending on housing conditions. [142] Diabetes in NOD mice is caused by several genes, primarily MHC genes involved in antigen presentation. [142] Like diabetic humans, NOD mice develop islet autoantibodies and inflammation in the islet, followed by reduced insulin production and hyperglycemia. [142] [143] Some features of human diabetes are exaggerated in NOD mice, namely the mice have more severe islet inflammation than humans, and have a much more pronounced sex bias, with females developing diabetes far more frequently than males. [142] In NOD mice the onset of insulitis occurs at 3–4 weeks of age. The islets of Langerhans are infiltrated by CD4+, CD8+ T lymphocytes, NK cells, B lymphocytes, dendritic cells, macrophages, and neutrophils, similar to the disease process in humans. [144] In addition to sex, breeding conditions, gut microbiome composition or diet also influence the onset of T1D. [145]

The BioBreeding Diabetes-Prone (BB) rat is another widely used spontaneous experimental model for T1D. The onset of diabetes occurs, in up to 90% of individuals (regardless of sex) at 8–16 weeks of age. [144] During insulitis, the pancreatic islets are infiltrated by T lymphocytes, B lymphocytes, macrophages, and NK cells, with the difference from the human course of insulitis being that CD4 + T lymphocytes are markedly reduced and CD8 + T lymphocytes are almost absent. The aforementioned lymphopenia is the major drawback of this model. The disease is characterized by hyperglycemia, hypoinsulinemia, weight loss, ketonuria, and the need for insulin therapy for survival. [144] BB Rats are used to study the genetic aspects of T1D and are also used for interventional studies and diabetic nephropathy studies. [146]

LEW-1AR1 / -iddm rats are derived from congenital Lewis rats and represent a rarer spontaneous model for T1D. These rats develop diabetes at about 8–9 weeks of age with no sex differences unlike NOD mice. [147] In LEW mice, diabetes presents with hyperglycemia, glycosuria, ketonuria, and polyuria. [148] [144] The advantage of the model is the progression of the prediabetic phase, which is very similar to human disease, with infiltration of islet by immune cells about a week before hyperglycemia is observed. This model is suitable for intervention studies or for the search for predictive biomarkers. It is also possible to observe individual phases of pancreatic infiltration by immune cells. The advantage of congenic LEW mice is also the good viability after the manifestation of T1D (compared to NOD mice and BB rats). [149]

Chemically induced

The chemical compounds aloxan and streptozotocin (STZ) are commonly used to induce diabetes and destroy β-cells in mouse/rat animal models. [144] In both cases, it is a cytotoxic analog of glucose that passes GLUT2 transport and accumulates in β-cells, causing their destruction. The chemically induced destruction of β-cells leads to decreased insulin production, hyperglycemia, and weight loss in the experimental animal. [150] The animal models prepared in this way are suitable for research into blood sugar-lowering drugs and therapies (e.g. for testing new insulin preparations). They are also the most commonly used genetically induced T1D model is the so-called AKITA mouse (originally C57BL/6NSIc mouse). The development of diabetes in AKITA mice is caused by a spontaneous point mutation in the Ins2 gene, which is responsible for the correct composition of insulin in the endoplasmic reticulum. Decreased insulin production is then associated with hyperglycemia, polydipsia, and polyuria. If severe diabetes develops within 3–4 weeks, AKITA mice survive no longer than 12 weeks without treatment intervention. The description of the etiology of the disease shows that, unlike spontaneous models, the early stages of the disease are not accompanied by insulitis. [151] AKITA mice are used to test drugs targeting endoplasmic reticulum stress reduction, to test islet transplants, and to study diabetes-related complications such as nephropathy, sympathetic autonomic neuropathy, and vascular disease. [144] [152] for testing transplantation therapies. Their advantage is mainly the low cost, the disadvantage is the cytotoxicity of the chemical compounds. [153]

Genetically induced

Type 1 diabetes (T1D) is a multifactorial autoimmune disease with a strong genetic component. Although environmental factors also play a significant role, the genetic susceptibility to T1D is well established, with several genes and loci implicated in disease development.

The most significant genetic contribution to T1D comes from the human leukocyte antigen (HLA) region on chromosome 6p21. [154] The HLA class II genes, particularly HLA-DR and HLA-DQ, are the strongest genetic determinants of T1D risk. Specific combinations of alleles such as HLA-DR3-DQ2 and HLA-DR4-DQ8 have been associated with a higher risk of developing T1D. [155] Individuals carrying both of these haplotypes (heterozygous DR3/DR4) are at an even greater risk. These HLA variants are thought to influence the immune system’s ability to differentiate between self and non-self antigens, leading to the autoimmune destruction of pancreatic beta cells. [156]

Conversely, some HLA haplotypes, such as HLA-DR15-DQ6, are associated with protection against T1D, suggesting that variations in these immune-related genes can either predispose or protect against the disease. [157]

In addition to HLA, multiple non-HLA genes have been implicated in T1D susceptibility. Genome-wide association studies (GWAS) have identified over 50 loci associated with an increased risk of T1D. [158] Some of the most notable genes include:

  • INS: The insulin gene (INS) on chromosome 11p15 is one of the earliest identified non-HLA genes linked to T1D. A variable number tandem repeat (VNTR) polymorphism in the promoter region of the insulin gene affects its thymic expression, with certain alleles reducing the ability to develop immune tolerance to insulin, a key autoantigen in T1D. [159]
  • PTPN22: This gene encodes a protein tyrosine phosphatase involved in T-cell receptor signaling. A common single nucleotide polymorphism (SNP), R620W, in the PTPN22 gene is associated with an increased risk of T1D and other autoimmune diseases, suggesting its role in modulating immune responses. [160]
  • IL2RA: The interleukin-2 receptor alpha (IL2RA) gene, located on chromosome 10p15, plays a crucial role in regulating immune tolerance and T-cell activation. Variants in IL2RA affect the susceptibility to T1D by altering the function of regulatory T-cells, which help maintain immune homeostasis. [161]
  • CTLA4: The cytotoxic T-lymphocyte-associated protein 4 (CTLA4) gene is another immune-related gene associated with T1D. CTLA4 acts as a negative regulator of T-cell activation, and certain variants are linked to impaired immune regulation and a higher risk of autoimmunity.

T1D is considered a polygenic disease, meaning that multiple genes contribute to its development. While individual genes confer varying degrees of risk, it is the combination of several genetic factors, along with environmental triggers, that ultimately leads to disease onset. [162] Family studies show that T1D has a relatively high heritability, with siblings of affected individuals having about a 6–10% risk of developing the disease, compared to a 0.3% risk in the general population. [163]

The risk of T1D is also influenced by the presence of affected first-degree relatives. For instance, children of fathers with T1D have a higher risk of developing the disease compared to children of mothers with T1D. Monozygotic (identical) twins have a concordance rate of about 30–50%, highlighting the importance of both genetic and environmental factors in disease onset. [155]

Recent research has also focused on the role of epigenetics and gene-environment interactions in T1D development. [164] Environmental factors such as viral infections, early childhood diet, and gut microbiome composition are thought to trigger the autoimmune process in genetically susceptible individuals. [165] Epigenetic modifications, such as DNA methylation and histone modifications, may influence gene expression in response to these environmental triggers, further modulating the risk of developing T1D.

While much progress has been made in understanding the genetic basis of T1D, ongoing research aims to unravel the complex interplay between genetic susceptibility, immune regulation, and environmental influences that contribute to disease pathogenesis. [166]

Virally induced

Viral infections play a role in the development of a number of autoimmune diseases, including human type 1 diabetes. However, the mechanisms by which viruses are involved in the induction of type 1 DM are not fully understood. Virus-induced models are used to study the etiology and pathogenesis of the disease, in particular the mechanisms by which environmental factors contribute to or protect against the occurrence of type 1 DM. [167] Among the most commonly used are coxsackievirus, lymphocytic choriomeningitis virus, encephalomyocarditis virus, and Kilham rat virus. Examples of virus-induced animals include NOD mice infected with coxsackie B4 that developed type 1 DM within two weeks. [168]

Related Research Articles

<span class="mw-page-title-main">Hypoglycemia</span> Decrease in blood sugar

Hypoglycemia, also spelled hypoglycaemia or hypoglycæmia, sometimes called low blood sugar, is a fall in blood sugar to levels below normal, typically below 70 mg/dL (3.9 mmol/L). Whipple's triad is used to properly identify hypoglycemic episodes. It is defined as blood glucose below 70 mg/dL (3.9 mmol/L), symptoms associated with hypoglycemia, and resolution of symptoms when blood sugar returns to normal. Hypoglycemia may result in headache, tiredness, clumsiness, trouble talking, confusion, fast heart rate, sweating, shakiness, nervousness, hunger, loss of consciousness, seizures, or death. Symptoms typically come on quickly.

<span class="mw-page-title-main">Insulin</span> Peptide hormone

Insulin is a peptide hormone produced by beta cells of the pancreatic islets encoded in humans by the insulin (INS) gene. It is the main anabolic hormone of the body. It regulates the metabolism of carbohydrates, fats, and protein by promoting the absorption of glucose from the blood into cells of the liver, fat, and skeletal muscles. In these tissues the absorbed glucose is converted into either glycogen, via glycogenesis, or fats (triglycerides), via lipogenesis; in the liver, glucose is converted into both. Glucose production and secretion by the liver are strongly inhibited by high concentrations of insulin in the blood. Circulating insulin also affects the synthesis of proteins in a wide variety of tissues. It is thus an anabolic hormone, promoting the conversion of small molecules in the blood into large molecules in the cells. Low insulin in the blood has the opposite effect, promoting widespread catabolism, especially of reserve body fat.

<span class="mw-page-title-main">Pancreas</span> Organ of the digestive system and endocrine system of vertebrates

The pancreas is an organ of the digestive system and endocrine system of vertebrates. In humans, it is located in the abdomen behind the stomach and functions as a gland. The pancreas is a mixed or heterocrine gland, i.e., it has both an endocrine and a digestive exocrine function. 99% of the pancreas is exocrine and 1% is endocrine. As an endocrine gland, it functions mostly to regulate blood sugar levels, secreting the hormones insulin, glucagon, somatostatin and pancreatic polypeptide. As a part of the digestive system, it functions as an exocrine gland secreting pancreatic juice into the duodenum through the pancreatic duct. This juice contains bicarbonate, which neutralizes acid entering the duodenum from the stomach; and digestive enzymes, which break down carbohydrates, proteins and fats in food entering the duodenum from the stomach.

The following is a glossary of diabetes which explains terms connected with diabetes.

<span class="mw-page-title-main">Beta cell</span> Type of cell found in pancreatic islets

Beta cells (β-cells) are specialized endocrine cells located within the pancreatic islets of Langerhans responsible for the production and release of insulin and amylin. Constituting ~50–70% of cells in human islets, beta cells play a vital role in maintaining blood glucose levels. Problems with beta cells can lead to disorders such as diabetes.

<span class="mw-page-title-main">Pancreatic islets</span> Regions of the pancreas

The pancreatic islets or islets of Langerhans are the regions of the pancreas that contain its endocrine (hormone-producing) cells, discovered in 1869 by German pathological anatomist Paul Langerhans. The pancreatic islets constitute 1–2% of the pancreas volume and receive 10–15% of its blood flow. The pancreatic islets are arranged in density routes throughout the human pancreas, and are important in the metabolism of glucose.

<span class="mw-page-title-main">Glucagon</span> Peptide hormone

Glucagon is a peptide hormone, produced by alpha cells of the pancreas. It raises the concentration of glucose and fatty acids in the bloodstream and is considered to be the main catabolic hormone of the body. It is also used as a medication to treat a number of health conditions. Its effect is opposite to that of insulin, which lowers extracellular glucose. It is produced from proglucagon, encoded by the GCG gene.

Drugs used in diabetes treat diabetes mellitus by decreasing glucose levels in the blood. With the exception of insulin, most GLP-1 receptor agonists, and pramlintide, all diabetes medications are administered orally and are thus called oral hypoglycemic agents or oral antihyperglycemic agents. There are different classes of hypoglycemic drugs, and selection of the appropriate agent depends on the nature of diabetes, age, and situation of the person, as well as other patient factors.

<span class="mw-page-title-main">Alpha cell</span> Glucagon secreting cell

Alpha cells (α-cells) are endocrine cells that are found in the Islets of Langerhans in the pancreas. Alpha cells secrete the peptide hormone glucagon in order to increase glucose levels in the blood stream.

Hyperinsulinemic hypoglycemia describes the condition and effects of low blood glucose caused by excessive insulin. Hypoglycemia due to excess insulin is the most common type of serious hypoglycemia. It can be due to endogenous or injected insulin.

The main goal of diabetes management is to keep blood glucose (BG) levels as normal as possible. If diabetes is not well controlled, further challenges to health may occur. People with diabetes can measure blood sugar by various methods, such as with a BG meter or a continuous glucose monitor, which monitors over several days. Glucose can also be measured by analysis of a routine blood sample. Usually, people are recommended to control diet, exercise, and maintain a healthy weight, although some people may need medications to control their blood sugar levels. Other goals of diabetes management are to prevent or treat complications that can result from the disease itself and from its treatment.

<span class="mw-page-title-main">Diabetes and pregnancy</span> Effects of pre-existing diabetes upon pregnancy

For pregnant women with diabetes, some particular challenges exist for both mother and fetus. If the pregnant woman has diabetes as a pre-existing disorder, it can cause early labor, birth defects, and larger than average infants. Therefore, experts advise diabetics to maintain blood sugar level close to normal range about 3 months before planning for pregnancy.

Slowly evolving immune-mediated diabetes, or latent autoimmune diabetes in adults (LADA), is a form of diabetes that exhibits clinical features similar to both type 1 diabetes (T1D) and type 2 diabetes (T2D), and is sometimes referred to as type 1.5 diabetes. It is an autoimmune form of diabetes, similar to T1D, but patients with LADA often show insulin resistance, similar to T2D, and share some risk factors for the disease with T2D. Studies have shown that LADA patients have certain types of antibodies against the insulin-producing cells, and that these cells stop producing insulin more slowly than in T1D patients. Since many people develop the disease later in life, it is often misdiagnosed as type 2 diabetes.

<span class="mw-page-title-main">Islet cell transplantation</span> Transference of pancreatic islets

Islet transplantation is the transplantation of isolated islets from a donor pancreas into another person. It is a treatment for type 1 diabetes. Once transplanted, the islets begin to produce insulin, actively regulating the level of glucose in the blood.

<span class="mw-page-title-main">Blood sugar regulation</span> Hormones regulating blood sugar levels

Blood sugar regulation is the process by which the levels of blood sugar, the common name for glucose dissolved in blood plasma, are maintained by the body within a narrow range.

Chronic Somogyi rebound is a contested explanation of phenomena of elevated blood sugars experienced by diabetics in the morning. Also called the Somogyi effect and posthypoglycemic hyperglycemia, it is a rebounding high blood sugar that is a response to low blood sugar. When managing the blood glucose level with insulin injections, this effect is counter-intuitive to people who experience high blood sugar in the morning as a result of an overabundance of insulin at night.

<span class="mw-page-title-main">Insulitis</span> Medical condition

Insulitis is an inflammation of the islets of Langerhans, a collection of endocrine tissue located in the pancreas that helps regulate glucose levels, and is classified by specific targeting of immune cell infiltration in the islets of Langerhans. This immune cell infiltration can result in the destruction of insulin-producing beta cells of the islets, which plays a major role in the pathogenesis, the disease development, of type 1 and type 2 diabetes. Insulitis is present in 19% of individuals with type 1 diabetes and 28% of individuals with type 2 diabetes. It is known that genetic and environmental factors contribute to insulitis initiation, however, the exact process that causes it is unknown. Insulitis is often studied using the non-obese diabetic (NOD) mouse model of type 1 diabetes. The chemokine family of proteins may play a key role in promoting leukocytic infiltration into the pancreas prior to pancreatic beta-cell destruction.

Complications of diabetes are secondary diseases that are a result of elevated blood glucose levels that occur in diabetic patients. These complications can be divided into two types: acute and chronic. Acute complications are complications that develop rapidly and can be exemplified as diabetic ketoacidosis (DKA), hyperglycemic hyperosmolar state (HHS), lactic acidosis (LA), and hypoglycemia. Chronic complications develop over time and are generally classified in two categories: microvascular and macrovascular. Microvascular complications include neuropathy, nephropathy, and retinopathy; while cardiovascular disease, stroke, and peripheral vascular disease are included in the macrovascular complications.

<span class="mw-page-title-main">Diabetes</span> Group of endocrine diseases characterized by high blood sugar levels

Diabetes mellitus, often known simply as diabetes, is a group of common endocrine diseases characterized by sustained high blood sugar levels. Diabetes is due to either the pancreas not producing enough insulin, or the cells of the body becoming unresponsive to the hormone's effects. Classic symptoms include polydipsia, polyuria, weight loss, and blurred vision. If left untreated, the disease can lead to various health complications, including disorders of the cardiovascular system, eye, kidney, and nerves. Diabetes accounts for approximately 4.2 million deaths every year, with an estimated 1.5 million caused by either untreated or poorly treated diabetes.

<span class="mw-page-title-main">Dulaglutide</span> Diabetes medication

Dulaglutide, sold under the brand name Trulicity among others, is a medication used for the treatment of type 2 diabetes in combination with diet and exercise. It is also approved in the United States for the reduction of major adverse cardiovascular events in adults with type 2 diabetes who have established cardiovascular disease or multiple cardiovascular risk factors.

References

  1. Zheng Y, Permanyer I, Canudas-Romo V, Aburto JM, Nigri A, Plana-Ripoll O (2023). "Lifespan variation among people with a given disease or condition". PLOS ONE. 18 (9): e0290962. Bibcode:2023PLoSO..1890962Z. doi: 10.1371/journal.pone.0290962 . ISSN   1932-6203. PMC   10473533 . PMID   37656703.
  2. Livingstone SJ, Levin D, Looker HC, Lindsay RS, Wild SH, Joss N, et al. (6 January 2015). "Estimated life expectancy in a Scottish cohort with type 1 diabetes, 2008-2010". JAMA. 313 (1): 37–44. doi:10.1001/jama.2014.16425. ISSN   1538-3598. PMC   4426486 . PMID   25562264.
  3. Arffman M, Hakkarainen P, Keskimäki I, Oksanen T, Sund R (April 2023). "Long-term and recent trends in survival and life expectancy for people with type 1 diabetes in Finland". Diabetes Research and Clinical Practice. 198: 110580. doi: 10.1016/j.diabres.2023.110580 . ISSN   1872-8227. PMID   36804193.
  4. 1 2 "Diabetes". World Health Organization. Archived from the original on 26 January 2011. Retrieved 24 January 2011.
  5. 1 2 3 4 5 6 "Diabetes Fact sheet N°312". WHO. November 2016. Archived from the original on 26 August 2013. Retrieved 29 May 2017.
  6. 1 2 3 4 "Types of Diabetes". NIDDK. February 2014. Archived from the original on 16 August 2016. Retrieved 31 July 2016.
  7. 1 2 3 4 5 "Causes of Diabetes". NIDDK. August 2014. Archived from the original on 10 August 2016. Retrieved 31 July 2016.
  8. Torpy JM, Lynm C, Glass RM (September 2007). "JAMA patient page. Type 1 diabetes". JAMA. 298 (12): 1472. doi:10.1001/jama.298.12.1472. PMID   17895465.
  9. "NIDDK Central Repository - Diabetes Prevention Trial of Type 1 Diabetes (DPT-1)".
  10. TEDDY Study Group (2008). "The Environmental Determinants of Diabetes in the Young (TEDDY) Study". Annals of the New York Academy of Sciences. 1150 (1): 1–13. Bibcode:2008NYASA1150....1.. doi:10.1196/annals.1447.062. PMC   2886800 . PMID   19120261.
  11. Erlich H, Valdes AM, Noble J, Carlson JA, Varney M, Concannon P, et al. (2008). "HLA DR-DQ haplotypes and genotypes and type 1 diabetes risk: Analysis of the type 1 diabetes genetics consortium families". Diabetes. 57 (4): 1084–1092. doi:10.2337/db07-1331. PMC   4103420 . PMID   18252895.
  12. 1 2 3 4 5 6 Chiang JL, Kirkman MS, Laffel LM, Peters AL (July 2014). "Type 1 diabetes through the life span: a position statement of the American Diabetes Association". Diabetes Care. 37 (7): 2034–2054. doi:10.2337/dc14-1140. PMC   5865481 . PMID   24935775.
  13. "Diagnosis of Diabetes and Prediabetes". NIDDK. May 2015. Archived from the original on 16 August 2016. Retrieved 31 July 2016.
  14. "Alternative Devices for Taking Insulin". NIDDK. July 2016. Archived from the original on 16 August 2016. Retrieved 31 July 2016.
  15. Daneman D (March 2006). "Type 1 diabetes". Lancet. 367 (9513): 847–858. doi:10.1016/S0140-6736(06)68341-4. PMID   16530579. S2CID   21485081.
  16. "Fast Facts Data and Statistics about Diabetes". American Diabetes Association. Archived from the original on 16 December 2015. Retrieved 25 July 2014.
  17. Global report on diabetes (PDF). World Health Organization. 2016. pp. 26–27. ISBN   978-92-4-156525-7. Archived (PDF) from the original on 7 October 2016. Retrieved 31 July 2016.
  18. Skyler J (2012). Atlas of diabetes (4th ed.). New York: Springer. pp. 67–68. ISBN   978-1-4614-1028-7. Archived from the original on 8 September 2017.
  19. 1 2 Fang M, Wang D, Echouffo-Tcheugui JB, Selvin E (2023). "Age at Diagnosis in U.S. Adults With Type 1 Diabetes". Ann Intern Med. 176 (11): 1567–1568. doi:10.7326/M23-1707. PMC   10841362 . PMID   37748184.
  20. McNulty R (7 October 2023). "Many Cases of Adult-Onset T1D Are Diagnosed After Age 30, Study Finds". ajmc. Retrieved 29 April 2024.
  21. 1 2 Atkinson et al. 2020, Table 36.1.
  22. "WHAT IS TYPE 1 DIABETES?". Diabetes Daily. 18 April 2016.
  23. Sadeharju K, Hämäläinen AM, Knip M, Lönnrot M, Koskela P, Virtanen SM, et al. (2003). "Enterovirus infections as a risk factor for type I diabetes: Virus analyses in a dietary intervention trial". Clinical and Experimental Immunology. 132 (2): 271–277. doi:10.1046/j.1365-2249.2003.02147.x. PMC   1808709 . PMID   12699416.
  24. Kamrath C, Mönkemöller K, Biester T, Rohrer TR, Warncke K, Hammersen J, et al. (2020). "Ketoacidosis in Children and Adolescents with Newly Diagnosed Type 1 Diabetes During the COVID-19 Pandemic in Germany". JAMA. 324 (8): 801–804. doi:10.1001/jama.2020.13445. PMC   7372511 . PMID   32702751.
  25. Kostopoulou E, Sinopidis X, Fouzas S, Gkentzi D, Dassios T, Roupakias S, et al. (2023). "Diabetic Ketoacidosis in Children and Adolescents; Diagnostic and Therapeutic Pitfalls". Diagnostics. 13 (15): 2602. doi: 10.3390/diagnostics13152602 . PMC   10416834 . PMID   37568965.
  26. 1 2 Wolsdorf & Garvey 2016, "Type 1 Diabetes".
  27. 1 2 3 Atkinson et al. 2020, "Clinical presentation".
  28. 1 2 DiMeglio, Evans-Molina & Oram 2018, p. 2449.
  29. 1 2 "DKA (Ketoacidosis) & Ketones". American Diabetes Association. Retrieved 28 July 2021.
  30. 1 2 3 Delli & Lernmark 2016, "Signs and symptoms".
  31. 1 2 3 4 Katsarou et al. 2017, p. 1.
  32. 1 2 3 Katsarou et al. 2017, "Epidemiology".
  33. Katsarou et al. 2017, "Introduction".
  34. Knip M, Veijola R, Virtanen SM, Hyöty H, Vaarala O, Akerblom HK (December 2005). "Environmental triggers and determinants of type 1 diabetes". Diabetes. 54 (Suppl 2): S125–S136. doi: 10.2337/diabetes.54.suppl_2.S125 . PMID   16306330.
  35. 1 2 3 4 5 Norris, Johnson & Stene 2020, "Environmental factors".
  36. 1 2 3 4 Norris, Johnson & Stene 2020, "Trends in epidemiology".
  37. 1 2 Norris, Johnson & Stene 2020, "Infections".
  38. Norris, Johnson & Stene 2020, "The hygiene hypothesis and proxies of microbial exposures".
  39. 1 2 3 4 DiMeglio, Evans-Molina & Oram 2018, p. 2450.
  40. 1 2 3 Repaske 2016, "Additional medications that decrease insulin release".
  41. Repaske 2016, "A common medication that decreases insulin release".
  42. Definition and Diagnosis of Diabetes Mellitus and Intermediate Hyperglycemia (PDF). Geneva: World Health Organization. 2006. p. 1. ISBN   978-92-4-159493-6 . Retrieved 28 July 2021.
  43. American Diabetes Association (January 2021). "2. Classification and Diagnosis of Diabetes: Standards of Medical Care in Diabetes-2021". Diabetes Care. 44 (Suppl 1). American Diabetes Association: S15–S33. doi: 10.2337/dc21-S002 . PMID   33298413.
  44. 1 2 3 4 Butler & Misselbrook 2020, "What is the next investigation?".
  45. 1 2 3 DiMeglio, Evans-Molina & Oram 2018, p. 2453.
  46. Katsarou et al. 2017, p. 11.
  47. 1 2 3 4 Smith & Harris 2018, "Self monitoring".
  48. 1 2 American Diabetes Association (6) 2021, "Glycemic assessment".
  49. DiMeglio, Evans-Molina & Oram 2018, "Management of clinical disease".
  50. 1 2 3 4 5 6 Atkinson et al. 2020, "Insulin Therapy".
  51. "Overview | Diabetes in pregnancy: management from preconception to the postnatal period | Guidance | NICE". nice.org.uk. 25 February 2015. Retrieved 31 January 2024.
  52. Lee TT, Collett C, Bergford S, Hartnell S, Scott EM, Lindsay RS, et al. (26 October 2023). "Automated Insulin Delivery in Women with Pregnancy Complicated by Type 1 Diabetes". New England Journal of Medicine. 389 (17): 1566–1578. doi:10.1056/NEJMoa2303911. ISSN   0028-4793. PMID   37796241. Archived from the original on 5 November 2023. Retrieved 31 January 2024.
  53. "Closed-loop insulin systems are effective for pregnant women with type 1 diabetes". NIHR Evidence. 16 January 2024. doi:10.3310/nihrevidence_61786.
  54. Atkinson et al. 2020, "Use of Adjunctive Drugs in T1DM".
  55. Atkinson et al. 2020, "Nutrition Therapy".
  56. Seckold R, Fisher E, de Bock M, King BR, Smart CE (March 2019). "The ups and downs of low-carbohydrate diets in the management of Type 1 diabetes: a review of clinical outcomes". Diabetic Medicine (Review). 36 (3): 326–334. doi:10.1111/dme.13845. PMID   30362180. S2CID   53102654. Low‐carbohydrate diets are of interest for improving glycaemic outcomes in the management of Type 1 diabetes. There is limited evidence to support their routine use in the management of Type 1 diabetes.
  57. Ly TT (2015). "Technology and type 1 diabetes: Closed-loop therapies". Current Pediatrics Reports. 3 (2): 170–176. doi:10.1007/s40124-015-0083-y. S2CID   68302123.
  58. "Stress". diabetes.org. American Diabetes Association. Archived from the original on 12 November 2014. Retrieved 11 November 2014.
  59. 1 2 3 4 5 Atkinson et al. 2020, "Physical Activity and Exercise".
  60. 1 2 3 4 5 6 Alarcón-Gómez J, Chulvi-Medrano I, Martin-Rivera F, Calatayud J (January 2021). "Effect of High-Intensity Interval Training on Quality of Life, Sleep Quality, Exercise Motivation and Enjoyment in Sedentary People with Type 1 Diabetes Mellitus". International Journal of Environmental Research and Public Health. 18 (23): 12612. doi: 10.3390/ijerph182312612 . ISSN   1660-4601. PMC   8656786 . PMID   34886337.
  61. 1 2 3 4 5 6 Lumb A (1 December 2014). "Diabetes and exercise". Clinical Medicine. 14 (6): 673–676. doi:10.7861/clinmedicine.14-6-673. ISSN   1470-2118. PMC   4954144 . PMID   25468857.
  62. 1 2 3 4 Tosur M, Huang X, Inglis AS, Aguirre RS, Redondo MJ (17 April 2024). "Inaccurate diagnosis of diabetes type in youth: prevalence, characteristics, and implications". Scientific Reports. 14 (1): 8876. Bibcode:2024NatSR..14.8876T. doi:10.1038/s41598-024-58927-6. ISSN   2045-2322. PMC   11024140 . PMID   38632329.
  63. Atkinson et al. 2020, "Pancreas and Islet Cell Transplantation".
  64. 1 2 Robertson RP, Davis C, Larsen J, Stratta R, Sutherland DE (April 2006). "Pancreas and islet transplantation in type 1 diabetes". Diabetes Care. 29 (4): 935. doi: 10.2337/diacare.29.04.06.dc06-9908 . PMID   16567844.
  65. Dean et al. 2017, "Simultaneous pancreas-kidney transplant".
  66. Dean et al. 2017, "Outcomes of pancreas transplantation".
  67. 1 2 Shapiro, Pokrywczynska & Ricordi 2017, "Main".
  68. 1 2 Rickels & Robertson 2019, "Islet allotransplantation for the treatment of type 1 diabetes".
  69. Rickels & Robertson 2019, "Long-term outcomes and comparison with pancreas transplantation".
  70. Shapiro, Pokrywczynska & Ricordi 2017, "Indications for islet transplantation".
  71. "FDA Approves First Cellular Therapy to Treat Patients with Type 1 Diabetes". U.S. Food and Drug Administration (FDA) (Press release). 28 June 2023. Retrieved 28 June 2023.PD-icon.svg This article incorporates text from this source, which is in the public domain .
  72. 1 2 3 4 DiMeglio, Evans-Molina & Oram 2018, "The immune phenotype of type 1 diabetes".
  73. DiMeglio, Evans-Molina & Oram 2018, "Diagnosis".
  74. 1 2 3 4 5 DiMeglio, Evans-Molina & Oram 2018, "The β-cell phenotype of type 1 diabetes".
  75. 1 2 3 4 Atkinson et al. 2020, "Mechanisms of Beta-Cell Death in T1DM".
  76. Farhy LS, McCall AL (July 2015). "Glucagon – the new 'insulin' in the pathophysiology of diabetes". Current Opinion in Clinical Nutrition and Metabolic Care. 18 (4): 407–414. doi:10.1097/mco.0000000000000192. PMID   26049639. S2CID   19872862.
  77. 1 2 Yosten GL (February 2018). "Alpha cell dysfunction in type 1 diabetes". Peptides. 100: 54–60. doi:10.1016/j.peptides.2017.12.001. PMID   29412832. S2CID   46878644.
  78. Brown RJ, Sinaii N, Rother KI (July 2008). "Too much glucagon, too little insulin: time course of pancreatic islet dysfunction in new-onset type 1 diabetes". Diabetes Care. 31 (7): 1403–1404. doi:10.2337/dc08-0575. PMC   2453684 . PMID   18594062.
  79. Unger RH, Cherrington AD (January 2012). "Glucagonocentric restructuring of diabetes: a pathophysiologic and therapeutic makeover". The Journal of Clinical Investigation. 122 (1): 4–12. doi:10.1172/JCI60016. PMC   3248306 . PMID   22214853.
  80. Meier JJ, Kjems LL, Veldhuis JD, Lefèbvre P, Butler PC (April 2006). "Postprandial suppression of glucagon secretion depends on intact pulsatile insulin secretion: further evidence for the intraislet insulin hypothesis". Diabetes. 55 (4): 1051–1056. doi: 10.2337/diabetes.55.04.06.db05-1449 . PMID   16567528.
  81. Cooperberg BA, Cryer PE (December 2009). "Beta-cell-mediated signaling predominates over direct alpha-cell signaling in the regulation of glucagon secretion in humans". Diabetes Care. 32 (12): 2275–2280. doi:10.2337/dc09-0798. PMC   2782990 . PMID   19729529.
  82. Paolisso G, Sgambato S, Torella R, Varricchio M, Scheen A, D'Onofrio F, et al. (June 1988). "Pulsatile insulin delivery is more efficient than continuous infusion in modulating islet cell function in normal subjects and patients with type 1 diabetes". The Journal of Clinical Endocrinology and Metabolism. 66 (6): 1220–1226. doi:10.1210/jcem-66-6-1220. PMID   3286673.
  83. 1 2 Banarer S, McGregor VP, Cryer PE (April 2002). "Intraislet hyperinsulinemia prevents the glucagon response to hypoglycemia despite an intact autonomic response". Diabetes. 51 (4): 958–965. doi: 10.2337/diabetes.51.4.958 . PMID   11916913.
  84. Raju B, Cryer PE (March 2005). "Loss of the decrement in intraislet insulin plausibly explains loss of the glucagon response to hypoglycemia in insulin-deficient diabetes: documentation of the intraislet insulin hypothesis in humans". Diabetes. 54 (3): 757–764. doi: 10.2337/diabetes.54.3.757 . PMID   15734853.
  85. 1 2 3 Tesfaye N, Seaquist ER (November 2010). "Neuroendocrine responses to hypoglycemia". Annals of the New York Academy of Sciences. 1212 (1): 12–28. Bibcode:2010NYASA1212...12T. doi:10.1111/j.1749-6632.2010.05820.x. PMC   2991551 . PMID   21039590.
  86. 1 2 Reno CM, Litvin M, Clark AL, Fisher SJ (March 2013). "Defective counterregulation and hypoglycemia unawareness in diabetes: mechanisms and emerging treatments". Endocrinology and Metabolism Clinics of North America. 42 (1): 15–38. doi:10.1016/j.ecl.2012.11.005. PMC   3568263 . PMID   23391237.
  87. Martín-Timón I, Del Cañizo-Gómez FJ (July 2015). "Mechanisms of hypoglycemia unawareness and implications in diabetic patients". World Journal of Diabetes. 6 (7): 912–926. doi: 10.4239/wjd.v6.i7.912 . PMC   4499525 . PMID   26185599.
  88. 1 2 Mundinger TO, Taborsky GJ (October 2016). "Early sympathetic islet neuropathy in autoimmune diabetes: lessons learned and opportunities for investigation". Diabetologia. 59 (10): 2058–2067. doi:10.1007/s00125-016-4026-0. PMC   6214182 . PMID   27342407.
  89. Mundinger TO, Mei Q, Foulis AK, Fligner CL, Hull RL, Taborsky GJ (August 2016). "Human Type 1 Diabetes Is Characterized by an Early, Marked, Sustained, and Islet-Selective Loss of Sympathetic Nerves". Diabetes. 65 (8): 2322–2330. doi:10.2337/db16-0284. PMC   4955989 . PMID   27207540.
  90. 1 2 3 4 5 6 "Hypoglycemia (Low blood sugar)". American Diabetes Association. Retrieved 20 March 2022.
  91. 1 2 3 4 5 6 DiMeglio, Evans-Molina & Oram 2018, p. 2455.
  92. 1 2 DiMeglio, Evans-Molina & Oram 2018, "Complications of type 1 diabetes".
  93. 1 2 Cashen & Petersen 2019, "Diagnosis, screening and prevention".
  94. 1 2 Cashen & Petersen 2019, "Epidemiology".
  95. Brownlee et al. 2020, "Pathophysiology of diabetic retinopathy".
  96. DiMeglio, Evans-Molina & Oram 2018, p. 2456.
  97. Devaraj S, Glaser N, Griffen S, Wang-Polagruto J, Miguelino E, Jialal I (March 2006). "Increased monocytic activity and biomarkers of inflammation in patients with type 1 diabetes". Diabetes. 55 (3): 774–779. doi: 10.2337/diabetes.55.03.06.db05-1417 . PMID   16505242.
  98. Granberg V, Ejskjaer N, Peakman M, Sundkvist G (August 2005). "Autoantibodies to autonomic nerves associated with cardiac and peripheral autonomic neuropathy". Diabetes Care. 28 (8): 1959–1964. doi: 10.2337/diacare.28.8.1959 . PMID   16043739.
  99. Huxley RR, Peters SA, Mishra GD, Woodward M (March 2015). "Risk of all-cause mortality and vascular events in women versus men with type 1 diabetes: a systematic review and meta-analysis". The Lancet. Diabetes & Endocrinology. 3 (3): 198–206. doi:10.1016/S2213-8587(14)70248-7. PMID   25660575.
  100. Roy T, Lloyd CE (October 2012). "Epidemiology of depression and diabetes: a systematic review". Journal of Affective Disorders. 142 (Suppl): S8–21. doi:10.1016/S0165-0327(12)70004-6. PMID   23062861.
  101. 1 2 Elfström P, Sundström J, Ludvigsson JF (November 2014). "Systematic review with meta-analysis: associations between coeliac disease and type 1 diabetes". Alimentary Pharmacology & Therapeutics. 40 (10): 1123–1132. doi: 10.1111/apt.12973 . PMID   25270960. S2CID   25468009.
  102. 1 2 See JA, Kaukinen K, Makharia GK, Gibson PR, Murray JA (October 2015). "Practical insights into gluten-free diets". Nature Reviews. Gastroenterology & Hepatology (Review). 12 (10): 580–591. doi:10.1038/nrgastro.2015.156. PMID   26392070. S2CID   20270743. Coeliac disease in T1DM is asymptomatic ...Clinical manifestations of coeliac disease, such as abdominal pain, gas, bloating, diarrhoea, and weight loss can be present in patients with T1DM, but are often attributed to poor control of diabetes, gastroparesis, or diabetic neuropathy
  103. Chen HS, Su LT, Lin SZ, Sung FC, Ko MC, Li CY (January 2012). "Increased risk of urinary tract calculi among patients with diabetes mellitus – a population-based cohort study". Urology. 79 (1): 86–92. doi:10.1016/j.urology.2011.07.1431. PMID   22119251.
  104. James R, Hijaz A (October 2014). "Lower urinary tract symptoms in women with diabetes mellitus: a current review". Current Urology Reports. 15 (10): 440. doi:10.1007/s11934-014-0440-3. PMID   25118849. S2CID   30653959.
  105. 1 2 3 4 "Sexual Dysfunction in Women". Diabetes.co.uk. Diabetes Digital Media Ltd. Archived from the original on 9 November 2014. Retrieved 28 November 2014.
  106. Goswami SK, Vishwanath M, Gangadarappa SK, Razdan R, Inamdar MN (August 2014). "Efficacy of ellagic acid and sildenafil in diabetes-induced sexual dysfunction". Pharmacognosy Magazine. 10 (Suppl 3): S581–S587. doi: 10.4103/0973-1296.139790 . PMC   4189276 . PMID   25298678. ProQuest   1610759650.
  107. Escobar-Morreale HF, Roldán B, Barrio R, Alonso M, Sancho J, de la Calle H, et al. (November 2000). "High prevalence of the polycystic ovary syndrome and hirsutism in women with type 1 diabetes mellitus". The Journal of Clinical Endocrinology and Metabolism. 85 (11): 4182–4187. doi: 10.1210/jcem.85.11.6931 . PMID   11095451.
  108. Codner E, Escobar-Morreale HF (April 2007). "Clinical review: Hyperandrogenism and polycystic ovary syndrome in women with type 1 diabetes mellitus". The Journal of Clinical Endocrinology and Metabolism. 92 (4): 1209–1216. doi: 10.1210/jc.2006-2641 . PMID   17284617.
  109. 1 2 Atkinson et al. 2020, "Other Complications".
  110. Redondo, Steck & Pugliese 2018, "Evidence for the contribution of genetics to type I diabetes".
  111. "What is Type 1 Diabetes?". Centers for Disease Control and Prevention. 11 March 2022. Retrieved 15 February 2023.
  112. "FDA Approves Tzield". Drugs.com. November 2022. Retrieved 15 February 2023.
  113. 1 2 Atkinson et al. 2020, "Immunosuppresion".
  114. von Scholten et al. 2021, "Antigen vaccination".
  115. 1 2 Dayan et al. 2019, "Previous prevention trials".
  116. Chellappan DK, Sivam NS, Teoh KX, Leong WP, Fui TZ, Chooi K, et al. (1 December 2018). "Gene therapy and type 1 diabetes mellitus". Biomedicine & Pharmacotherapy. 108: 1188–1200. doi: 10.1016/j.biopha.2018.09.138 . ISSN   0753-3322. PMID   30372820.
  117. Chen S, Du K, Zou C (2020). "Current progress in stem cell therapy for type 1 diabetes mellitus". Stem Cell Research & Therapy. 11 (1): 275. doi: 10.1186/s13287-020-01793-6 . PMC   7346484 . PMID   32641151.
  118. Vaarala O (2012). "Gut microbiota and type 1 diabetes". The Review of Diabetic Studies: RDS. 9 (4): 251–259. doi:10.1900/RDS.2012.9.251 (inactive 1 November 2024). ISSN   1614-0575. PMC   3740694 . PMID   23804264.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  119. Bluestone JA, Herold K, Eisenbarth G (29 April 2010). "Genetics, pathogenesis and clinical interventions in type 1 diabetes". Nature. 464 (7293): 1293–1300. Bibcode:2010Natur.464.1293B. doi:10.1038/nature08933. ISSN   1476-4687. PMC   4959889 . PMID   20432533.
  120. Isaacs SR, Foskett DB, Maxwell AJ, Ward EJ, Faulkner CL, Luo JY, et al. (2021). "Viruses and Type 1 Diabetes: From Enteroviruses to the Virome". Microorganisms. 9 (7): 1519. doi: 10.3390/microorganisms9071519 . PMC   8306446 . PMID   34361954.
  121. Bone RN, Evans-Molina C (2017). "Combination Immunotherapy for Type 1 Diabetes". Current Diabetes Reports. 17 (7): 50. doi:10.1007/s11892-017-0878-z. PMC   5774222 . PMID   28534310.
  122. Jerram ST, Dang MN, Leslie RD (2017). "The Role of Epigenetics in Type 1 Diabetes". Current Diabetes Reports. 17 (10): 89. doi:10.1007/s11892-017-0916-x. PMC   5559569 . PMID   28815391.
  123. 1 2 Atkinson et al. 2020, "Diagnosis".
  124. Aanstoot HJ, Anderson BJ, Daneman D, Danne T, Donaghue K, Kaufman F, et al. (October 2007). "The global burden of youth diabetes: perspectives and potential". Pediatric Diabetes. 8. 8 (s8): 1–44. doi: 10.1111/j.1399-5448.2007.00326.x . PMID   17767619. S2CID   222102948.
  125. 1 2 "Fast Facts" (PDF). American Diabetes Association. Archived from the original (PDF) on 29 April 2015.
  126. Australian Institute of Health and Welfare (2015). "Incidence of type 1 diabetes in Australia 2000–2013". Archived from the original on 7 October 2016. Retrieved 19 October 2016.
  127. Shaw J (2012). "diabetes: the silent pandemic and its impact on Australia" (PDF). Archived (PDF) from the original on 7 October 2016. Retrieved 19 October 2016.
  128. Weiss A, Donnachie E, Beyerlein A, Ziegler AG, Bonifacio E (22 May 2023). "Type 1 Diabetes Incidence and Risk in Children With a Diagnosis of COVID-19" (PDF). JAMA (Research Letter). 329 (23): 2089–2091. doi:10.1001/jama.2023.8674. PMC   10203966 . PMID   37213115. S2CID   258831851.
  129. 1 2 3 4 5 6 Petschnig R, Wagner T, Robubi A, Baron R (October 2020). "Effect of Strength Training on Glycemic Control and Adiponectin in Diabetic Children". Medicine & Science in Sports & Exercise. 52 (10): 2172. doi:10.1249/MSS.0000000000002356. ISSN   0195-9131. PMID   32301853.
  130. 1 2 3 4 5 6 7 García-Hermoso A, Ezzatvar Y, Huerta-Uribe N, Alonso-Martínez AM, Chueca-Guindulain MJ, Berrade-Zubiri S, et al. (June 2023). "Effects of exercise training on glycaemic control in youths with type 1 diabetes: A systematic review and meta-analysis of randomised controlled trials". European Journal of Sport Science. 23 (6): 1056–1067. doi:10.1080/17461391.2022.2086489. hdl: 2454/43706 . ISSN   1746-1391. PMID   35659492.
  131. 1 2 3 4 The Diabetes Research in Children Network (DirecNet) Study Group (1 January 2006). "The Effects of Aerobic Exercise on Glucose and Counterregulatory Hormone Concentrations in Children With Type 1 Diabetes". Diabetes Care. 29 (1): 20–25. doi:10.2337/diacare.29.1.20. ISSN   0149-5992. PMC   2396943 . PMID   16373890.
  132. 1 2 Atkinson et al. 2020, "Introduction".
  133. Bottazzo GF, Florin-Christensen A, Doniach D (November 1974). "Islet-cell antibodies in diabetes mellitus with autoimmune polyendocrine deficiencies". Lancet. 2 (7892): 1279–1283. doi:10.1016/s0140-6736(74)90140-8. PMID   4139522.
  134. Herold KC, Vignali DA, Cooke A, Bluestone JA (April 2013). "Type 1 diabetes: translating mechanistic observations into effective clinical outcomes". Nature Reviews. Immunology. 13 (4): 243–256. doi:10.1038/nri3422. PMC   4172461 . PMID   23524461.
  135. Johnson L (18 November 2008). "Study: Cost of diabetes $218B". USA Today. Associated Press. Archived from the original on 1 July 2012.
  136. "About JDRF". JDRF. Retrieved 24 March 2024.
  137. "About DRWF". Diabetes Research & Wellness Foundation. Archived from the original on 11 May 2013.
  138. Boughton & Hovorka 2020, "Introduction".
  139. Boughton & Hovorka 2020, "Regulatory Approval of Closed-Loop Systems".
  140. Ramli R, Reddy M, Oliver N (July 2019). "Artificial Pancreas: Current Progress and Future Outlook in the Treatment of Type 1 Diabetes". Drugs. 79 (10): 1089–1101. doi:10.1007/s40265-019-01149-2. hdl: 10044/1/71348 . PMID   31190305. S2CID   186207231.
  141. 1 2 King AJ (2020). Animal models of diabetes: methods and protocols. New York, NY: Humana Press. ISBN   978-1-0716-0385-7. OCLC   1149391907.[ page needed ]
  142. 1 2 3 4 Atkinson et al. 2020, "Animal models".
  143. "NOD/ShiLtJ". The Jackson Laborataory. Retrieved 18 January 2022.
  144. 1 2 3 4 5 6 Pandey S, Dvorakova MC (7 January 2020). "Future Perspective of Diabetic Animal Models". Endocrine, Metabolic & Immune Disorders Drug Targets. 20 (1): 25–38. doi:10.2174/1871530319666190626143832. PMC   7360914 . PMID   31241444.
  145. Chen D, Thayer TC, Wen L, Wong FS (2020). "Mouse Models of Autoimmune Diabetes: The Nonobese Diabetic (NOD) Mouse". In King AJ (ed.). Animal Models of Diabetes. Methods in Molecular Biology. Vol. 2128. New York, NY: Springer US. pp. 87–92. doi:10.1007/978-1-0716-0385-7_6. ISBN   978-1-0716-0384-0. PMC   8253669 . PMID   32180187.
  146. Lenzen S, Arndt T, Elsner M, Wedekind D, Jörns A (2020). "Rat Models of Human Type 1 Diabetes". In King AJ (ed.). Animal Models of Diabetes. Methods in Molecular Biology. Vol. 2128. New York, NY: Springer US. pp. 69–85. doi:10.1007/978-1-0716-0385-7_5. ISBN   978-1-0716-0384-0. PMID   32180186. S2CID   212741496.
  147. Al-Awar A, Kupai K, Veszelka M, Szűcs G, Attieh Z, Murlasits Z, et al. (2016). "Experimental Diabetes Mellitus in Different Animal Models". Journal of Diabetes Research. 2016: 9051426. doi: 10.1155/2016/9051426 . PMC   4993915 . PMID   27595114.
  148. Lenzen S, Tiedge M, Elsner M, Lortz S, Weiss H, Jörns A, et al. (September 2001). "The LEW.1AR1/Ztm-iddm rat: a new model of spontaneous insulin-dependent diabetes mellitus". Diabetologia. 44 (9): 1189–1196. doi: 10.1007/s001250100625 . PMID   11596676.
  149. Lenzen S (October 2017). "Animal models of human type 1 diabetes for evaluating combination therapies and successful translation to the patient with type 1 diabetes". Diabetes/Metabolism Research and Reviews. 33 (7): e2915. doi:10.1002/dmrr.2915. PMID   28692149. S2CID   34331597.
  150. Radenković M, Stojanović M, Prostran M (March 2016). "Experimental diabetes induced by alloxan and streptozotocin: The current state of the art". Journal of Pharmacological and Toxicological Methods. 78: 13–31. doi:10.1016/j.vascn.2015.11.004. PMID   26596652.
  151. Salpea P, Cosentino C, Igoillo-Esteve M (2020). "A Review of Mouse Models of Monogenic Diabetes and ER Stress Signaling". In King AJ (ed.). Animal Models of Diabetes. Methods in Molecular Biology. Vol. 2128. New York, NY: Springer US. pp. 55–67. doi:10.1007/978-1-0716-0385-7_4. ISBN   978-1-0716-0384-0. PMID   32180185. S2CID   212740474.
  152. Chang JH, Gurley SB (2012). "Assessment of Diabetic Nephropathy in the Akita Mouse". In Hans-Georg J, Hadi AH, Schürmann A (eds.). Animal Models in Diabetes Research. Methods in Molecular Biology. Vol. 933. Totowa, NJ: Humana Press. pp. 17–29. doi:10.1007/978-1-62703-068-7_2. ISBN   978-1-62703-067-0. PMID   22893398.
  153. King AJ, Estil Les E, Montanya E (2020). "Use of Streptozotocin in Rodent Models of Islet Transplantation". In King AJ (ed.). Animal Models of Diabetes. Methods in Molecular Biology. Vol. 2128. New York, NY: Springer US. pp. 135–147. doi:10.1007/978-1-0716-0385-7_10. ISBN   978-1-0716-0384-0. PMID   32180191. S2CID   212739708.
  154. Sia C, Weinem M (2005). "The role of HLA class I gene variation in autoimmune diabetes". The Review of Diabetic Studies: RDS. 2 (2): 97–109. doi:10.1900/RDS.2005.2.97 (inactive 1 November 2024). ISSN   1614-0575. PMC   1783552 . PMID   17491685.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  155. 1 2 Todd JA (23 April 2010). "Etiology of type 1 diabetes". Immunity. 32 (4): 457–467. doi:10.1016/j.immuni.2010.04.001. ISSN   1097-4180. PMID   20412756.
  156. Roep BO (March 2003). "The role of T-cells in the pathogenesis of Type 1 diabetes: from cause to cure". Diabetologia. 46 (3): 305–321. doi:10.1007/s00125-003-1089-5. ISSN   0012-186X. PMID   12687328.
  157. Noble JA, Erlich HA (January 2012). "Genetics of type 1 diabetes". Cold Spring Harbor Perspectives in Medicine. 2 (1): a007732. doi:10.1101/cshperspect.a007732. ISSN   2157-1422. PMC   3253030 . PMID   22315720.
  158. Grant SF, Hakonarson H (April 2009). "Genome-wide association studies in type 1 diabetes". Current Diabetes Reports. 9 (2): 157–163. doi:10.1007/s11892-009-0026-5. ISSN   1539-0829. PMID   19323961.
  159. Steck AK, Rewers MJ (2011). "Genetics of Type 1 Diabetes". Clinical Chemistry. 57 (2): 176–185. doi:10.1373/clinchem.2010.148221. PMC   4874193 . PMID   21205883.
  160. Vang T, Miletic AV, Bottini N, Mustelin T (September 2007). "Protein tyrosine phosphatase PTPN22 in human autoimmunity". Autoimmunity. 40 (6): 453–461. doi:10.1080/08916930701464897. ISSN   0891-6934. PMID   17729039.
  161. Garg G, Tyler JR, Yang JH, Cutler AJ, Downes K, Pekalski M, et al. (1 May 2012). "Type 1 diabetes-associated IL2RA variation lowers IL-2 signaling and contributes to diminished CD4+CD25+ regulatory T cell function". Journal of Immunology. 188 (9): 4644–4653. doi:10.4049/jimmunol.1100272. ISSN   1550-6606. PMC   3378653 . PMID   22461703.
  162. Dean L, McEntyre J (7 July 2004), "Genetic Factors in Type 1 Diabetes", The Genetic Landscape of Diabetes [Internet], National Center for Biotechnology Information (US), retrieved 20 October 2024
  163. Leslie RD, Evans-Molina C, Freund-Brown J, Buzzetti R, Dabelea D, Gillespie KM, et al. (November 2021). "Adult-Onset Type 1 Diabetes: Current Understanding and Challenges". Diabetes Care. 44 (11): 2449–2456. doi:10.2337/dc21-0770. ISSN   1935-5548. PMC   8546280 . PMID   34670785.
  164. Xie Z, Chang C, Huang G, Zhou Z (2020). "The Role of Epigenetics in Type 1 Diabetes". Epigenetics in Allergy and Autoimmunity. Advances in Experimental Medicine and Biology. Vol. 1253. pp. 223–257. doi:10.1007/978-981-15-3449-2_9. ISBN   978-981-15-3448-5. ISSN   0065-2598. PMID   32445098.
  165. Esposito S, Toni G, Tascini G, Santi E, Berioli MG, Principi N (2019). "Environmental Factors Associated With Type 1 Diabetes". Frontiers in Endocrinology. 10: 592. doi: 10.3389/fendo.2019.00592 . PMC   6722188 . PMID   31555211.
  166. Mittal R, Camick N, Lemos JR, Hirani K (26 January 2024). "Gene-environment interaction in the pathophysiology of type 1 diabetes". Frontiers in Endocrinology. 15. doi: 10.3389/fendo.2024.1335435 . ISSN   1664-2392. PMC   10858453 . PMID   38344660.
  167. Christoffersson G, Flodström-Tullberg M (2020). "Mouse Models of Virus-Induced Type 1 Diabetes". In King AJ (ed.). Animal Models of Diabetes. Methods in Molecular Biology. Vol. 2128. New York, NY: Springer US. pp. 93–105. doi:10.1007/978-1-0716-0385-7_7. ISBN   978-1-0716-0384-0. PMID   32180188. S2CID   212739248.
  168. King AJ (June 2012). "The use of animal models in diabetes research". British Journal of Pharmacology. 166 (3): 877–894. doi:10.1111/j.1476-5381.2012.01911.x. PMC   3417415 . PMID   22352879.

Works cited