Diabetes mellitus (DM) is a multisystem disease with both biochemical and anatomical consequences. It is a chronic disease of carbohydrate, fat, and protein metabolism caused by the lack of insulin. In type 1 diabetes, insulin is functionally absent because of the destruction of the beta cells of the pancreas. Type 1 DM occurs most commonly in juveniles but can occur in adults, especially in those in their late 30s and early 40s. Unlike people with type 2 DM, those with type 1 DM generally are not obese and may present initially with diabetic ketoacidosis (DKA).
Pathophysiology
Type 1 DM is a catabolic disorder in which circulating insulin is very low or absent, plasma glucagon is elevated, and the pancreatic beta cells fail to respond to all insulin-secretory stimuli. Patients need exogenous insulin to reverse this catabolic condition, prevent ketosis, decrease hyperglucagonemia, and normalize lipid and protein metabolism.
Type 1 DM is an autoimmune disease. The pancreas shows lymphocytic infiltration and destruction of insulin-secreting cells of the islets of Langerhans, causing insulin deficiency. Approximately 85% of patients have circulating islet cell antibodies, and the majority also have detectable anti-insulin antibodies before receiving insulin therapy. Most islet cell antibodies are directed against glutamic acid decarboxylase (GAD) within pancreatic B cells.
One theory regarding the etiology of type 1 DM is that it results from damage to pancreatic beta cells from an infectious or environmental agent. It triggers the immune system in a genetically susceptible individual to develop an autoimmune response against altered pancreatic beta cell antigens or molecules in beta cells that resemble a viral protein. Currently, autoimmunity is considered the major factor in the pathophysiology of type 1 DM. Prevalence is increased in patients with other autoimmune diseases, such as Graves disease, Hashimoto thyroiditis, and Addison disease. Approximately 95% of patients with type 1 DM have either human leukocyte antigen (HLA)-DR3 or HLA-DR4. HLA-DQs are considered specific markers of type 1 DM susceptibility.
Environmental agents that have been hypothesized to induce an attack on beta cell function include viruses (eg, mumps, rubella, Coxsackie B4), toxic chemicals, exposure to cow's milk in infancy, and cytotoxins.
Recent evidence suggests a role for vitamin D in the pathogenesis and prevention of diabetes mellitus.
Frequency
United States
Roughly 5-15% of all cases of diabetes are type 1 DM. It is the most common metabolic disease of childhood, with a yearly incidence of 15 cases per 100,000 people younger than 18 years. Approximately 1 million Americans have type 1 DM, and physicians diagnose 10,000 new cases every year.
According to the American Diabetes Association, there are 20.8 million children and adults in the United States, or 7% of the population, who have diabetes. While an estimated 14.6 million have been diagnosed, unfortunately, 6.2 million people (or nearly one-third) are undiagnosed. Fifty-four million people are prediabetes status. In people younger than 20 years, 176,500 cases, or 0.22% of all people in this age group, have diabetes. About one in every 400-600 children and adolescents has type 1 DM. Two million adolescents (or 1 in 6 overweight adolescents) aged 12-19 years have prediabetes status. In people aged 20 years or older, 1.5 million new cases of diabetes were diagnosed in 2005.
International
Scandinavia has the highest prevalence rates for type 1 DM (ie, approximately 20% of the total number of people with DM), while China and Japan have the lowest prevalence rates, with less than 1% of all people with diabetes. Some of these differences may relate to definitional issues and the completeness of reporting.
Mortality/Morbidity
Type 1 DM is associated with a high morbidity and premature mortality due to complications. The annual financial cost from diabetes overall exceeds $100 billion, almost $1 of every $7 dollars of US health expenditures in terms of medical care and loss of productivity. Advances in treatment that permit tight glycemic control and control of comorbidities (hyperlipidemia) can greatly reduce the incidence of microvascular and macrovascular complications.
As a result of these complications, people with diabetes have an increased risk of developing ischemic heart disease, cerebral vascular disease, peripheral vascular disease with gangrene of lower limbs, chronic renal disease, reduced visual acuity and blindness, and autonomic and peripheral neuropathy.
Race
Type 1 DM is more common among non-Hispanic whites, followed by African Americans and Hispanic Americans. It is comparatively uncommon among Asians.
Sex
Type 1 DM is more common in men than in women.
Age
Type 1 DM usually starts in children aged 4 years or older, with the peak incidence of onset at age 11-13 years, coinciding with early adolescence and puberty. Also, a relatively high incidence exists in people in their late 30s and early 40s, when it tends to present in a less aggressive manner, ie, early hyperglycemia without ketoacidosis and gradual onset of ketosis.
Read more HERE
Showing posts with label Diabetes Mellitus type 1. Show all posts
Showing posts with label Diabetes Mellitus type 1. Show all posts
Friday, 1 August 2008
Thursday, 31 July 2008
Diabetes Mellitus, Type 1 (pedia)
Diabetes mellitus (DM) is a chronic metabolic disorder caused by an absolute or relative deficiency of insulin, an anabolic hormone. Insulin is produced by the beta cells of the islets of Langerhans located in the pancreas, and the absence, destruction, or other loss of these cells results in type 1 diabetes (insulin-dependent diabetes mellitus [IDDM]). Most children with diabetes have IDDM and a lifetime dependence on exogenous insulin.
Type 2 diabetes (non–insulin-dependent diabetes mellitus [NIDDM]) is a heterogeneous disorder. Most patients with NIDDM have insulin resistance, and their beta cells lack the ability to overcome this resistance. Although this form of diabetes was previously uncommon in children, in some, countries 20% or more of new patients with diabetes in childhood and adolescence have NIDDM, a change associated with increased rates of obesity. Other patients may have inherited disorders of insulin release leading to maturity onset diabetes of the young (MODY).
This chapter addresses only IDDM.
Pathophysiology
Insulin is essential to process carbohydrates, fat, and protein. Insulin reduces blood glucose levels by allowing glucose to enter muscle cells and by stimulating the conversion of glucose to glycogen (glycogenesis) as a carbohydrate store. Insulin also inhibits the release of stored glucose from liver glycogen (glycogenolysis) and slows the breakdown of fat to triglycerides, free fatty acids, and ketones. It also stimulates fat storage. Additionally, insulin inhibits the breakdown of protein and fat for glucose production (gluconeogenesis) in both liver and kidneys.
Hyperglycemia (ie, random blood glucose concentration more than 200 mg/dL or 11 mmol/L) results when insulin deficiency leads to uninhibited gluconeogenesis and prevents the use and storage of circulating glucose. The kidneys cannot reabsorb the excess glucose load, causing glycosuria, osmotic diuresis, thirst, and dehydration. Increased fat and protein breakdown leads to ketone production and weight loss. Without insulin, a child with IDDM wastes away and eventually dies from diabetic ketoacidosis (DKA).
An excess of insulin prevents the release of glucose into the circulation and results in hypoglycemia (blood glucose concentrations of <60 mg/dL or 3.5 mmol/L). Glucose is the sole energy source for erythrocytes, kidney medulla, and the brain.
Frequency
United States
Overall incidence is approximately 15 cases per 100,000 individuals annually and probably increasing. An estimated 3 children out of 1000 develop IDDM by age 20 years.
International
DM exhibits wide geographic variation in incidence and prevalence. Annual incidence varies from 0.61 cases per 100,000 persons in China, to 41.4 cases per 100,000 in Finland. Substantial variations exist between nearby countries with differing lifestyles, such as Estonia and Finland, and between genetically similar populations such as those in Iceland and Norway. Even more striking are the differences in incidence between mainland Italy (8.4/100,000) and the Island of Sardinia (36.9/100,000). These variations strongly support the importance of environmental factors in the development of IDDM. Most countries report that incidence rates have at least doubled or more in the last 20 years. Incidence appears to increase with distance from the equator.
Mortality/Morbidity
Information on mortality rates is difficult to ascertain without complete national registers of childhood diabetes, although age-specific mortality is probably double that of the general population. Particularly at risk are children aged 1-4 years who may die with DKA at the time of diagnosis. Adolescents are also a high-risk group. Most deaths result from delayed diagnosis or neglected treatment and subsequent cerebral edema during treatment for DKA, although untreated hypoglycemia also causes some deaths. Unexplained death during sleep may also occur.
IDDM complications are comprised of 3 major categories: acute complications, long-term complications, and complications caused by associated autoimmune diseases.
Acute complications reflect the difficulties of maintaining a balance between insulin therapy, dietary intake, and exercise. Acute complications include hypoglycemia, hyperglycemia, and DKA.
Long-term complications arise from the damaging effects of prolonged hyperglycemia and other metabolic consequences of insulin deficiency on various tissues. While long-term complications are rare in childhood, maintaining good control of diabetes is important to prevent complications from developing in later life. The likelihood of developing complications appears to depend on the interaction of factors such as metabolic control, genetic susceptibility, lifestyle (eg, smoking, diet, exercise), pubertal status, and gender.Long-term complications include the following:
Retinopathy
Cataracts
Hypertension
Progressive renal failure
Early coronary artery disease
Peripheral vascular disease
Neuropathy, both peripheral and autonomic
Increased risk of infection
Associated autoimmune diseases are common with IDDM, particularly in children who have the human leukocyte antigen DR3 (HLA-DR3). Some conditions may precede development of diabetes; others may develop later. As many as 20% of children with diabetes have thyroid autoantibodies.
Race
Different environmental effects on IDDM development complicate the influence of race, but racial differences clearly exist.
Whites have the highest reported incidence of IDDM; Chinese have the lowest.
IDDM is 1.5 times more likely to develop in American whites than in American blacks or Hispanics.
Current evidence suggests that when immigrants from an area with low incidence move to an area with higher incidence, their IDDM rates tend to increase toward the higher level.
Sex
The influence of sex varies with the overall incidence rates.
Males are at greater risk in regions of high incidence, particularly older males, whose incidence rates often show seasonal variation.
Females appear to be at a greater risk in low-incidence regions.
Age
Generally, incidence rates increase with age until mid-puberty then decline after puberty, but IDDM can occur at any age. Onset in the first year of life, though unusual, can occur and must be considered in any infant or toddler, because these children have the greatest risk for mortality if diagnosis is delayed. Their symptoms may include the following:
Severe monilial diaper/napkin rash
Unexplained malaise
Poor weight gain or weight loss
Increased thirst
Vomiting and dehydration, with a constantly wet napkin/diaper
Where prevalence rates are high, a bimodal variation of incidence has been reported that shows a definite peak in early childhood (ie, 4-6 y) and a second, much greater peak of incidence during early puberty (ie, 10-14 y).
Read further HERE
Type 2 diabetes (non–insulin-dependent diabetes mellitus [NIDDM]) is a heterogeneous disorder. Most patients with NIDDM have insulin resistance, and their beta cells lack the ability to overcome this resistance. Although this form of diabetes was previously uncommon in children, in some, countries 20% or more of new patients with diabetes in childhood and adolescence have NIDDM, a change associated with increased rates of obesity. Other patients may have inherited disorders of insulin release leading to maturity onset diabetes of the young (MODY).
This chapter addresses only IDDM.
Pathophysiology
Insulin is essential to process carbohydrates, fat, and protein. Insulin reduces blood glucose levels by allowing glucose to enter muscle cells and by stimulating the conversion of glucose to glycogen (glycogenesis) as a carbohydrate store. Insulin also inhibits the release of stored glucose from liver glycogen (glycogenolysis) and slows the breakdown of fat to triglycerides, free fatty acids, and ketones. It also stimulates fat storage. Additionally, insulin inhibits the breakdown of protein and fat for glucose production (gluconeogenesis) in both liver and kidneys.
Hyperglycemia (ie, random blood glucose concentration more than 200 mg/dL or 11 mmol/L) results when insulin deficiency leads to uninhibited gluconeogenesis and prevents the use and storage of circulating glucose. The kidneys cannot reabsorb the excess glucose load, causing glycosuria, osmotic diuresis, thirst, and dehydration. Increased fat and protein breakdown leads to ketone production and weight loss. Without insulin, a child with IDDM wastes away and eventually dies from diabetic ketoacidosis (DKA).
An excess of insulin prevents the release of glucose into the circulation and results in hypoglycemia (blood glucose concentrations of <60 mg/dL or 3.5 mmol/L). Glucose is the sole energy source for erythrocytes, kidney medulla, and the brain.
Frequency
United States
Overall incidence is approximately 15 cases per 100,000 individuals annually and probably increasing. An estimated 3 children out of 1000 develop IDDM by age 20 years.
International
DM exhibits wide geographic variation in incidence and prevalence. Annual incidence varies from 0.61 cases per 100,000 persons in China, to 41.4 cases per 100,000 in Finland. Substantial variations exist between nearby countries with differing lifestyles, such as Estonia and Finland, and between genetically similar populations such as those in Iceland and Norway. Even more striking are the differences in incidence between mainland Italy (8.4/100,000) and the Island of Sardinia (36.9/100,000). These variations strongly support the importance of environmental factors in the development of IDDM. Most countries report that incidence rates have at least doubled or more in the last 20 years. Incidence appears to increase with distance from the equator.
Mortality/Morbidity
Information on mortality rates is difficult to ascertain without complete national registers of childhood diabetes, although age-specific mortality is probably double that of the general population. Particularly at risk are children aged 1-4 years who may die with DKA at the time of diagnosis. Adolescents are also a high-risk group. Most deaths result from delayed diagnosis or neglected treatment and subsequent cerebral edema during treatment for DKA, although untreated hypoglycemia also causes some deaths. Unexplained death during sleep may also occur.
IDDM complications are comprised of 3 major categories: acute complications, long-term complications, and complications caused by associated autoimmune diseases.
Acute complications reflect the difficulties of maintaining a balance between insulin therapy, dietary intake, and exercise. Acute complications include hypoglycemia, hyperglycemia, and DKA.
Long-term complications arise from the damaging effects of prolonged hyperglycemia and other metabolic consequences of insulin deficiency on various tissues. While long-term complications are rare in childhood, maintaining good control of diabetes is important to prevent complications from developing in later life. The likelihood of developing complications appears to depend on the interaction of factors such as metabolic control, genetic susceptibility, lifestyle (eg, smoking, diet, exercise), pubertal status, and gender.Long-term complications include the following:
Retinopathy
Cataracts
Hypertension
Progressive renal failure
Early coronary artery disease
Peripheral vascular disease
Neuropathy, both peripheral and autonomic
Increased risk of infection
Associated autoimmune diseases are common with IDDM, particularly in children who have the human leukocyte antigen DR3 (HLA-DR3). Some conditions may precede development of diabetes; others may develop later. As many as 20% of children with diabetes have thyroid autoantibodies.
Race
Different environmental effects on IDDM development complicate the influence of race, but racial differences clearly exist.
Whites have the highest reported incidence of IDDM; Chinese have the lowest.
IDDM is 1.5 times more likely to develop in American whites than in American blacks or Hispanics.
Current evidence suggests that when immigrants from an area with low incidence move to an area with higher incidence, their IDDM rates tend to increase toward the higher level.
Sex
The influence of sex varies with the overall incidence rates.
Males are at greater risk in regions of high incidence, particularly older males, whose incidence rates often show seasonal variation.
Females appear to be at a greater risk in low-incidence regions.
Age
Generally, incidence rates increase with age until mid-puberty then decline after puberty, but IDDM can occur at any age. Onset in the first year of life, though unusual, can occur and must be considered in any infant or toddler, because these children have the greatest risk for mortality if diagnosis is delayed. Their symptoms may include the following:
Severe monilial diaper/napkin rash
Unexplained malaise
Poor weight gain or weight loss
Increased thirst
Vomiting and dehydration, with a constantly wet napkin/diaper
Where prevalence rates are high, a bimodal variation of incidence has been reported that shows a definite peak in early childhood (ie, 4-6 y) and a second, much greater peak of incidence during early puberty (ie, 10-14 y).
Read further HERE
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