Diabetes mellitus is a medical disorder characterized by varying or persistent hyperglycemia (elevated blood sugar levels), especially after eating. All types of diabetes mellitus share similar symptoms and complications at advanced stages. Hyperglycemia itself can lead to dehydration and ketoacidosis. Longer-term complications include cardiovascular disease (doubled risk), chronic renal failure (it is the main cause for dialysis), retinal damage with eventual blindness, nerve damage and eventual gangrene with risk of amputation of toes, feet, and even legs. The most important forms of diabetes are due to decreased production of insulin (diabetes mellitus type 1, the first recognized form), or decreased sensitivity of body tissues to insulin (diabetes mellitus type 2, the more common form). The former requires insulin injections, while the latter is generally managed with oral medication and only requires insulin if the tablets are ineffective. Patient understanding and participation is vital as blood glucose levels change continuously, while successfully keeping blood sugar within normal limits has been compellingly shown to reduce or prevent development of some of the complications of diabetes. Other risk factors that can require addressing to reduce complications are: cessation of smoking, optimizing cholesterol levels, maintaining a stable body weight, controlling high blood pressure and engaging in regular exercise. In 2004, according to the World Health Organization, more than 150 million people worldwide suffer from diabetes. Its incidence is increasing rapidly, and it is estimated that by the year 2025 this number will double. Diabetes mellitus occurs throughout the world, but is more common (especially type 2) in the more developed countries. The greatest increase in prevalence rate is, however, expected to occur in Asia and Africa, where most of the diabetic patients will be seen by 2025. The increase in incidence of diabetes in the developing countries follows the trend of urbanisation and life style changes. Diabetes is in the top 10, and perhaps the top 5, of the most significant diseases in the developed world, and is gaining in significance (see big killers). For at least 20 years, diabetes rates in North America have been increasing substantially. In 2002 there were about 18.2 million diabetics in the United States alone. The Centers for Disease Control has termed the change an epidemic. The National Diabetes Information Clearinghouse estimates that diabetes costs $132 billion in the United States alone every year. Mechanism of insulin release in normal pancreatic beta cells (ie, glucose dependence). Insulin production doesn't depend on blood glucose levels; insulin is stored pending release Since insulin is the principal hormone that regulates uptake of glucose into cells (primarily muscle and fat cells) from the blood, deficiency of insulin or its action plays a central role in all forms of diabetes. Most of the carbohydrates in food are rapidly digested to glucose, the principal sugar in blood. Insulin is produced by beta cells in the pancreas in response to rising levels of glucose in the blood, as occurs after a meal. Insulin makes it possible for most body tissues to remove glucose from the blood for use as fuel, for conversion to other needed molecules, or for storage. Insulin is also the principal control signal for conversion of glucose (the basic sugar unit) to glycogen for storage in liver and muscle cells. Lowered insulin levels result in the reverse conversion of glycogen to glucose when glucose levels fall -- though only in the liver not muscle tissue. Higher insulin level increase many anabolic ("building up") processes such as cell growth, cellular protein synthesis, and fat storage. Insulin is the principal signal in converting many of the bidirectional processes of metabolism from a catabolic to an anabolic direction. If the amount of insulin produced is insufficient, if cells respond poorly to the effects of insulin (insulin insensitivity or resistance), or if the insulin itself is defective, glucose is not handled properly by body cells (about 2/3 require it) nor stored appropriately in the liver and muscles. The net effect is persistent high levels of blood glucose, poor protein synthesis, and other metabolic derangements. Type 1 diabetes is most commonly diagnosed in children and adolescents, but can occur in adults as well. It is an autoimmune disorder, in which the body's own immune system attacks the beta cells in the Islets of Langerhans of the pancreas, destroying them or damaging them sufficiently to reduce insulin production. The autoimmune attack may be triggered by reaction to an infection, for example by one of the viruses of the Coxsackie virus family. A subtype of type 1 (identifiable by the presence of antibodies against beta cells) develops slowly and so is often confused with Type 2. In addition, a small proportion of type 1 cases has the hereditary condition maturity onset diabetes of the young (MODY). Some poisons (e.g. certain rat poisons) work by selectively destroying certain types of cells, including pancreatic beta cells, thus producing "artificial" type 1 diabetes. Other pancreatic problems including trauma, pancreatitis or tumors (either malignant or benign) can also lead to loss of insulin production. Currently, type 1 is treated with insulin injections, lifestyle adjustments, and careful monitoring of blood glucose levels using blood test kits. Insulin delivery is also available by an insulin pump, which allows the infusion of insulin 24 hours a day at preset levels, and the ability to program push doses (bolus) of insulin as needed at meal times. The treatment must be continued indefinitely. Experimental replacement of beta cells (by transplant) is being investigated in several research programs and may become clinically available in the future. About 5-10% of all North American cases of diabetes are Type 1 diabetics. The fraction of type 1 diabetics in other parts of the world differs; this is likely due to both differences in the rate of type 1 and differences in the rate of other types, most prominently type 2. Most of this difference is not currently understood. Formerly, type 1 diabetes was called "childhood" or "juvenile" diabetes or "insulin dependent" diabetes. Each term is a misnomer, especially since the obesity epidemic in recent years has led to increased incidence of type 2 diabetes in children and adolescents in the USA, and insulin is used in some type 2 cases. Type 2 diabetes is characterized by "insulin resistance" as body cells do not respond appropriately when insulin is present. This is a more complex problem than type 1, but is sometimes easier to treat, since insulin is still produced, especially in the initial years. Type 2 may go unnoticed for years in a patient before diagnosis, since the symptoms are typically milder (no ketoacidosis) and can be sporadic. However, severe complications can result from unnoticed type 2 diabetes, including renal failure, and coronary artery disease. Type 2 diabetes was formerly known by a variety of partially misleading names, including "adult-onset diabetes", "obesity-related diabetes", "insulin-resistant diabetes", or "non-insulin-dependent diabetes" (NIDDM). It may be caused by a number of diseases, such as hemochromatosis and polycystic ovary syndrome, and can also be caused by certain types of medications (e.g. long-term steroid use). About 90-95% of all North American cases of diabetes are type 2, and about 20% of the population over the age of 65 is a type 2 diabetic. The fraction of type 2 diabetics in other parts of the world varies substantially, almost certainly for environmental and lifestyle reasons. There is also a strong inheritable genetic connection in type 2 diabetes: having relatives (especially first degree) with type 2 is a considerable risk factor for developing type 2 diabetes. The majority of patients with type 2 diabetes mellitus are obese - chronic obesity leads to increased insulin resistance that can develop into diabetes, most likely because adipose tissue is a (recently identified) source of chemical signals (hormones and cytokines). Other research shows that type 2 diabetes causes obesity. Type 2 is initially treated by changes in diet and through weight loss. This can restore insulin sensitivity, even when the weight lost is modest e.g. around 5 kg (10 to 15 lb). The next step, if necessary, is treatment with oral antidiabetic drugs: the sulphonylureas, metformin, or (if these are insufficient) thiazolidinediones. When these have failed, insulin therapy may be necessary to maintain normal glucose levels. Type 2 diabetes almost always has a slow onset (often years), but in type 1, particularly in children, onset may be quite fast (weeks or months). Early symptoms of type 1 diabetes are often polyuria (frequent urination) and polydipsia (increased thirst, and consequent increased fluid intake). There may also be weight loss (despite normal or increased eating), increased appetite, and irreduceable fatigue. These symptoms may also manifest in Type 2 diabetes in patients who present with frank poorly controlled diabetes. Thirst develops because of osmotic effects — sufficiently high glucose (above the 'renal threshold') in the blood is excreted by the kidneys but this requires water to carry it and causes increased fluid loss, which must be replaced. The lost blood volume will be replaced from water held inside body cells, causing dehydration. Another common presenting symptom is altered vision. Prolonged high blood glucose causes changes in the shape of the lens in the eye, leading to blurred vision and, perhaps, a visit to an optometrist. All unexplained quick changes in eyesight should force a fasting blood glucose test. These are now quick (less than 5 minutes total), inexpensive (materials less than US$1), and can be safely performed by almost anyone with trivial training. Especially dangerous symptoms in diabetics include the smell of acetone on the patient's breath (a sign of ketoacidosis), Kussmaul breathing (a rapid, deep breathing), and any altered state of consciousness or arousal (hostility and mania are both possible, as is confusion and lethargy). The most dangerous form of altered consciousness is the so-called "diabetic coma" which produces unconsciousness. Early symptoms of impending diabetic coma include polyuria, nausea, vomiting and abdominal pain, with lethargy and somnolence a later development, progressing to unconsciousness and death if untreated. The diagnosis of type 1 diabetes and many cases of type 2 is usually prompted by recent-onset symptoms of excessive urination (polyuria) and excessive thirst (polydipsia), often accompanied by weight loss. These symptoms typically worsen over days to weeks; about 25% of people with new type 1 diabetes have developed a degree of diabetic ketoacidosis by the time the diabetes is recognized. The diagnosis of other types of diabetes is made in many other ways. The most common are (1) health screening, (2) detection of hyperglycemia when a doctor is investigating a complication of longstanding, unrecognized diabetes, and less commonly (3) new signs and symptoms attributable to the diabetes. 1. Diabetes screening is recommended for many types of people at various stages of life or with several different risk factors. The screening test varies according to circumstances and local policy and may be a random glucose, a fasting glucose and insulin, a glucose 2 hours after 75 g of glucose, or a formal glucose tolerance test. Many health care recommendations for adults recommend universal screening at age 40 or 50 years, and sometimes occasionally thereafter. Earlier screening is recommended for those with risk factors such as obesity, family history of diabetes, high risk ethnicity (Hispanic [Latin American], American Indian, African American, Pacific Island, and South Asian ancestry). 2. Many medical conditions are associated with a higher risk of various types of diabetes and warrant screening. A partial list includes: high blood pressure, elevated cholesterol levels, coronary artery disease, past gestational diabetes, polycystic ovary syndrome, chronic pancreatitis, hepatic steatosis (fatty liver), cystic fibrosis, several mitochondrial neuropathies and myopathies, myotonic dystrophy, Friedreich's ataxia, some of the inherited forms of neonatal hyperinsulinism and many others. Risk of diabetes is higher with chronic use of several medications, including high dose glucocorticoids, some chemotherapy agents (especially L-asparaginase), and some of the antipsychotics and mood stabilizers (especially phenothiazines and some atypical antipsychotics). 3. Diabetes is often detected when a person suffers a problem frequently caused by diabetes, such as a heart attack, stroke, neuropathy, poor wound healing or a foot ulcer, certain eye problems, certain fungal infections, or delivering a baby with macrosomia or hypoglycemia. Diabetes mellitus is characterized by recurrent or persistent hyperglycemia, and is diagnosed by demonstrating any one of: See also the more detailed articles diabetic ketoacidosis and diabetic coma Diabetic ketoacidosis (DKA) is an acute, dangerous complication and is always a medical emergency. Without prompt proper treatment, diabetic ketoacidosis leads to death. DKA occurs more commonly in type 1 diabetes because the insulin deficiency is more severe, though it can occur rarely in type 2 diabetes. In about a quarter of young people who develop type 1 diabetes, the insulin deficiency and hyperglycemia lead to ketoacidosis before the disease is recognized and treated. This can occur at the onset of type 2 diabetes as well, especially in young people. When a person is known to have diabetes and is being adequately treated, DKA usually results from omission of insulin, mismanagement of acute gastroenteritis (the "flu"), or an overwhelming new health problem (e.g., bacterial infection, myocardial infarction). Insulin deficiency switches many aspects of metabolic balance in a catabolic direction. The liver becomes a net producer of glucose by way of gluconeogenesis and glycogenolysis. Fat in adipose tissue is reduced to triglycerides and fatty acids by lipolysis. Muscle is degraded to release amino acids for gluconeogenesis. The rise of fatty acid levels is accompanied by a rise of ketones (acetone, acetoacetate and beta-hydroxybutyrate). As the ketosis worsens, it produces a metabolic acidosis, with anorexia, abdominal distress, and eventually vomiting. The rising level of glucose increases the volume of urine produced by the kidneys (an osmolar diuresis). The high volume of urination (polyuria) also produces increased losses of electrolytes, especially sodium, potassium, chloride, phosphate, and magnesium. Reduced fluid intake from vomiting combined with amplified urination produce dehydration. As the metabolic acidosis worsens, it induces obvious hyperventilation (termed Kussmaul respiration). On presentation to hospital, the patient in DKA is typically dehydrated and breathing both fast and deeply. Abdominal pain is common and may be severe. The level of consciousness is normal until late in the process, when obtundation may progress to coma. The dehydration can become severe enough to cause shock. Laboratory tests typically show hyperglycemia, metabolic acidosis, normal or elevated potassium, and severe ketosis. Many other tests can be affected. At this point the patient is urgently in need of intravenous fluids. The basic principles of DKA treatment are: Hyperosmotic diabetic coma is another acute problem associated with improper management of diabetes mellitus. It has some symptoms in common with DKA, but a different cause, and requires different treatment. In anyone with very high blood glucose levels (usually considered to be above 300 mg/dl) water will be osmotically driven out of cells into the blood. The kidneys will also be "dumping" glucose into the urine, resulting in concomitant loss of water, causing an increase in blood osmolality. The osmotic effect of high glucose levels combined with the loss of water will eventually result in such a high serum osmolality that the body's cells may become directly affected as water is drawn out from them. Electrolyte imbalances are also common. This combination of changes, especially if prolonged, will result in symptoms similar to ketoacidosis, including loss of consciousness. As with DKA, urgent medical treatment is necessary. This is the diabetic coma to which type 2 diabetics are prone; it is less common in type 1 diabetics. Hypoglycemia in diabetic patients almost always arises as a result of poor management of the disease either from too much or poorly timed insulin or oral hypoglycemics or too much exercise, not enough food, or poor timing of either. If blood glucose levels are low enough, the patient may become agitated, sweaty, and have many symptoms of sympathetic activation of the autonomic nervous system - they may experience feelings similar to dread and immobilized panic. Consciousness can be altered, or even lost, in extreme cases, leading to coma and/or seizures or even death and brain damage. Experienced diabetics can often recognise the symptoms early on - all diabetics should always carry something sugary to eat or drink as these symptoms can be rapidly reduced if treated early enough. In the case of children, this can be a type of candy disliked by the patient, to prevent concerns about unnecessary use. Other ways of treating hypoglycemia include an injection of glucagon which causes the liver to convert its internal stores of glycogen to be released as glucose into the blood. Oral or intravenous dextrose can also be given. In most cases, recovery is rapid and troublefree. Longstanding hypoglycemia may require hospital admission to allow supervised recovery and adjustment of diabetic medications. Among the major risks of the disorder are chronic problems affecting multiple organ systems which will eventually arise in patients with poor glycemic control. Many of these arise from damage to the blood vessels. These illnesses can be divided into those arising from large blood vessel diseases, macroangiopathy, and those arising from small blood vessel disease, microangiopathy. Interestingly, small vessel disease is minimized by tight blood glucose control, but large vessel disease is unaffected by tight blood glucose control. Diabetes mellitus is the most common cause of adult kidney failure worldwide. It also the most common cause of amputation in the US, usually toes and feet, often as a result of gangrene, and almost always as a result of peripheral vascular disease. Retinal damage (from microangiopathy) makes it the most common cause of blindness among non-elderly adults in the US. Diabetes is a chronic disease with no cure (except experimentally in type 1 diabetics) as of 2004. Management of this disease may include lifestyle modifications such as achieving and maintaining proper weight, diet, exercise and foot care. The most important is the hypoglycemic treatment with either oral hypoglycemics and/or insulin therapy. Nowadays, the goal for diabetics is to avoid or minimize chronic diabetic complications, as well as to avoid acute problems of hyperglycemia or hypoglycemia. Adequate control of diabetes leads to a lower risk of the complications of uncontrolled diabetes which include kidney failure (requiring dialysis or transplant), blindness, heart disease and limb amputation. Recent studies show that use of statins might be needed in primary and secondary prevention of cardiovascular complications and mortality. Ideal control of hypertension plays a pivotal role in preventing both diabetic nephropathy and cardiovascular disease. There is emerging solid evidence that full-blown diabetes mellitus type 2 can be evaded in those with only mildly impaired glucose tolerance. Patients with type 1 diabetes mellitus require direct injection of insulin as their bodies cannot produce enough (or even any) insulin. As of 2004, there is no other clinically available form of insulin administration other than injection for patients with type 1: injection can be done by insulin pump, by jet injector, or any of several forms of hypodermic needle. There are several insulin application mechanisms under experimental development as of 2004. There have also been proposed vaccines for type I using glutamic acid decarboxylase (GAD), but these are currently not being tested by the pharmaceutical companies that have sublicensed the patents to them. For type 2 diabetics, diabetic management consists of a combination of diet, exercise, and weight loss, in any achievable combination depending on the patient. Patients who have poor diabetic control after lifestyle modifications are typically placed on oral hypoglycemics. Some Type 2 diabetics eventually fail to respond to these and must proceed to insulin therapy. Patient education and compliance with treatment is very important in managing the disease. Improper use of medications and insulin can be very dangerous causing hypo- or hyper-glycemic episodes. Insulin therapy requires close monitoring and a great deal of patient education, as improper administration is quite dangerous. For example, when food intake is reduced, less insulin is required. A previously satisfactory dosing may be too much if less food is consumed causing a hypoglycemic reaction if not intelligently adjusted. In addition, exercise decreases insulin requirements as exercise increases glucose uptake by body cells whose glucose uptake is controlled by insulin. And vice versa. In addition, there are available several types of insulin with varying times of onset and duration of action. An older style portable blood glucose meter. A blood sample is applied to an inserted strip (see image below) and color changes caused by reaction with blood glucose are measured by the meter. Optimal management of diabetes involves patients measuring and recording their own blood glucose testing at home. By keeping a diary of their own blood glucose measurements and noting the effect of food and exercise, patients can modify their lifestyle to better control their diabetes. For patients on insulin, patient involvement is important in achieving effective dosing and timing. Relying on their own perceptions of symptoms of hyperglycemia or hypoglycemia is usually unsatisfactory as mild to moderate hyperglycemia causes no obvious symptoms in nearly all patients. Other considerations include the fact that, while food takes several hours to be digested and absorbed, insulin administration can have glucose lowering effects for as little as 2 hours or 24 hours or more (depending on the nature of the insulin preparation used and individual patient reaction). In addition, the onset and duration of the effects of oral hypoglycemic agents vary from type to type and from patient to patient. A useful test that can be done in a doctor's clinic is the measurement of blood HbA1C levels. This is the ratio of glycosylated red blood cells in relation to the total number of red blood cells. Persistent raised plasma glucose levels causes the proportion of these cells to go up. This is a test that measures the average amount of diabetic control over a period of about 3 months (the average red blood cell lifetime). In the non-diabetic, the HbA1C level ranges from 4.0-6.4%; patients with diabetes mellitus who manage to keep their HbA1C level below 7.0% are considered to have good glycaemic control. Regular blood testing especially more so in type 1 diabetics is essential to keep a tight reign on the symptoms of the disease. There are many (at least 20+) different types of blood monitoring devices available on the market today, not every meter suits all patients and it is a specific matter of choice for the patient to find a meter that they personally find comfortable to use. The principle of the devices is the virtually the same, a small blood sample is collected by the patient by self-production using a lancing device (a sterile pointed needle) the blood is usually collected at the end point to a test strip. This test strip contains various chemicals which when the blood is applied creates a small electrical charge between two contacts. This charge will vary dependent on the glucose levels within the blood and its effect on the chemicals contained within the strip. In older glucose meters, the drop of blood is placed on top of a strip. A chemical reaction occurs and the strip changes color. The meter then measures the color of the strip optically. It is this level that is measured and a result in either mg/dL (milligrams per deciliter in the USA) or mmol/L (millimoles per litre in Europe) of blood. The average normal person should have a glucose level of around 4.5 to 7.0 mmol/L (80 to 125 mg/dL). In the diabetic patient, more specifically type 2 patients, it is important to maintain good glucose control, with a before meal level of <6.1> A level of <3.8> Levels greater than 13-15 mmol/L (230-270 mg/dL) should be monitored closely and the patient is advised to seek urgent medical attention as soon as possible if this continues to rise after 2-3 tests. Hyperglycaemia is not as easy to detect as hypoglycaemia and usually happens over a period of days rather than hours or minutes. If left untreated this can result in diabetic coma and death. A blood glucose test strip for an older style (ie, optical color sensing) monitoring system Prolonged and elevated levels of glucose in the blood, which is left unchecked and untreated will, over time, result in serious diabetic complications and sometimes even death. It is therefore highly important that a diabetic patient checks their blood levels either daily or every few days to see what levels they are achieving over a given period of time. There is also computer software for the PC which is available from blood testing manufacturers which can display results and trends over time. Type 1 patients will have to check on a more regular daily basis due to insulin therapy which is a fine art to master. The US Food and Drug Administration has also approved a non-invasive blood glucose monitoring device. This allows checking blood glucose levels, while puncturing the skin as little as twice a day. Once calibrated with a blood sample, it pulls body fuilds from the skin using small electrical currents, taking six readings an hour for as long as thirteen hours. It has not proven to be reliable enough, or convenient enough to be used in lieu of conventional blood monitoring. Other non-invasive methods like radiowaves, ultrasound and energy waves are also being tested. These results are especially useful for the diabetic to present to their doctor or physician in the monitoring and control of the disease. Failure to maintain a strict regimen of testing can accelerate symptoms of the condition, and it is therefore imperative that any diabetic patient strictly monitor their glucose levels regularly.Diabetes Statistics
Causes and types of Diabetes
Type 1 diabetes mellitus
Type 2 diabetes mellitus
Signs and symptoms of Diabetes
Diagnostic approach
Criteria for diagnosis
Diabetic ketoacidosis and coma
Hyperosmotic diabetic coma
Hypoglycemia
Long-term complications
Management of the disease
Monitoring
Thursday, April 8, 2010
Labels: Diabetes
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