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ISSN: 2155-6156
Journal of Diabetes & Metabolism
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Classification, Pathophysiology, Diagnosis and Management of Diabetes Mellitus

Habtamu Wondifraw Baynest*

University of Gondar, Ethopia

*Corresponding Author:
Habtamu Wondifraw Baynes
Lecturer Clinical Chemistry
University of Gondar, Gondar
Amhara 196, Ethiopia
Tel: +251910818289
E-mail: habtamuw97@gmail.com

Received date: March 16, 2015; Accepted date: April 27, 2015; Published date: April 30, 2015

Citation: Baynes HW (2015) Classification, Pathophysiology, Diagnosis and Management of Diabetes Mellitus. J Diabetes Metab 6:541. doi:10.4172/2155-6156.1000541

Copyright: © 2015 Baynes HW. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Visit for more related articles at Journal of Diabetes & Metabolism

Abstract

Diabetes Mellitus (DM) is a metabolic disorder characterized by the presence of chronic hyperglycemia either immune-mediated (Type 1 diabetes), insulin resistance (Type 2), gestational or others (environment, genetic defects, infections, and certain drugs). According to International Diabetes Federation Report of 2011 an estimated 366 million people had DM, by 2030 this number is estimated to almost around 552 million. There are different approaches to diagnose diabetes among individuals, The 1997 ADA recommendations for diagnosis of DM focus on fasting Plasma Glucose (FPG), while WHO focuses on Oral Glucose Tolerance Test (OGTT). This is importance for regular follow-up of diabetic patients with the health care provider is of great significance in averting any long term complications.

Keywords

Diabetes mellitus; Epidemiology; Diagnosis; Glycemic management

Abbreviations

DM: Diabetes Mellitus; FPG: Fasting Plasma Glucose; GAD: Glutamic Acid Decarboxylase; GDM: Gestational Diabetes Mellitus; HDL-cholesterol: High Density Lipoprotein cholesterol; HLA: Human Leucoid Antigen; IDDM: Insulin Dependent Diabetes Mellitus; IFG: Impaired Fasting Glucose; IGH: Increased Glycated Hemoglobin; IGT: Impaired Glucose Test; NIDDM: Non- Insulin Dependent Diabetes Mellitus; OGTT: Oral Glucose Tolerance Test

Introduction

Diabetes Mellitus (DM) is a metabolic disorder characterized by the presence of chronic hyperglycemia accompanied by greater or lesser impairment in the metabolism of carbohydrates, lipids and proteins. DM is probably one of the oldest diseases known to man. It was first reported in Egyptian manuscript about 3000 years ago [1]. In 1936, the distinction between type 1 and type 2 DM was clearly made [2]. Type 2 DM was first described as a component of metabolic syndrome in 1988 [3].

The origin and etiology of DM can vary greatly but always include defects in either insulin secretion or response or in both at some point in the course of disease. Mostly patients with diabetes mellitus have either type 1 diabetes (which is immune-mediated or idiopathic) Type 2 DM (formerly known as non-insulin dependent DM) is the most common form of DM characterized by hyperglycemia, insulin resistance, and relative insulin deficiency [4].

Type 2 DM results from interaction between genetic, environmental and behavioral risk factors [5,6]. Diabetes also can be related to the gestational hormonal environment, genetic defects, other infections, and certain drugs [7].

Epidemiology

The application of epidemiology to the study of DM has provided valuable information on several aspects of this disease such as its natural history, prevalence, incidence, morbidity and mortality in diverse populations around the world. Identification of the cause of the disease and the possible preventive measures that could be instituted to arrest or delay the onset of this disease which has reached epidemic proportions in both the developed and the developing nations [8]. Unfortunately, the improvement in outcomes for individual patients with diabetes has not resulted in similar improvements from the public health perspective.

The worldwide prevalence of diabetes has continued to increase dramatically. Globally, as of 2011, an estimated 366 million people had DM, with type 2 making up about 90% of the cases [9,10]. The number of people with type 2 DM is increasing in every country with 80% of people with DM living in low- and middle-income countries. Literature search has shown that there are few data available on the prevalence of type 2 DM in Africa as a whole. Studies examining data trends within Africa point to evidence of adramatic increase in prevalence in both rural and urban setting, and affecting both gender proportionally [11]. According to the World Fact book report in 2008, in Africa the prevalence of diabetes mellitus was 3.2%, and 40,895 persons (2.0%) was in Ethiopia [12].

Although T2DM is widely diagnosed in adults, its frequency has markedly increased in the pediatric age group over the past two decades. Depending on the population studied, T2DM now represents 8-45% of all new cases of diabetes reported among children and escent [13]. The prevalence of T2DM in the pediatric population is higher among girls than boys, just as it is higher among women than men [14].

The mean age of onset of T2DM is 12-16 years; this period coincides with puberty, when a physiologic state of insulin resistance develops. In this physiologic state, T2DM develops only if inadequate beta-cell function is associated with other risk factors (e.g. obesity) [15].

Certain literatures also stated that T1DM is the most common form of diabetes in most part of the world. Wide variations exist between the incidence rates of different populations, incidence is lowest in China (0.1 per 105 per year) and highest in Finland (37 per 105 per year).In most populations girls and boys are equally affected. In general, the incidence increases with age, the incidence peak is at puberty. After the pubertal years, the incidence rate significantly drops in young women, but remains relatively high in young adult males up to the age 29-35 years [16].

Presently as many as 50% of people with diabetes are undiagnosed. Since therapeutic intervention can reduce complications of the disease, there is a need to detect diabetes early in its course. The risk of developing Type 2 diabetes increases with age, obesity, and lack of physical activity. Its incidence is increasing rapidly, and by 2030 this number is estimated to almost around 552 million [17,5]. Diabetes mellitus occurs throughout the world, but is more common (especially type 2) in the more developed countries, where the majority of patients are aged between 45 and 64 years. The greatest increase in prevalence is, however, expected to occur in Asia and Africa, where most patients will probably be found by 2030 [5] (Table 1). It is projected that the latter will equal or even exceed the former in developing nations, thus culminating in a double burden as a result of the current trend of transition from communicable to non-communicable diseases [18].

  2000  2030
Ranking Country People with
Diabetes (millions)
Country People with
diabetes (millions)
1
2
3
4
5
6
7
8
9
10
India
China
U.S.
Indonesia
Japan
Pakistan
Russian Federation
Brazil
Italy
Bangladesh
31.7
20.8
17.7
8.4
6.8
5.2
4.6
4.6
4.3
3.2
India
China
U.S.
Indonesia
Pakistan
Brazil
Bangladesh
Japan
Philippines
Egypt
79.4
42.3
30.3
21.3
13.9
11.3
11.1
8.9
7.8
6.7

Table 1: List of countries with the highest numbers of estimated cases of diabetes for 2000 and 2030. Adapted from Wild S [5].

Classification of Diabetes Mellitus

If any characteristic can define the new intentions for DM classification, it is the intention to consolidate etiological views concerning DM. The old and confusing terms of insulin-dependent (IDDM) or non-insulin-dependent (NIDDM) which were proposed by WHO in1980 and 1985 have disappeared and the terms of new classification system identifies four types of diabetes mellitus: type 1, type 2, “other specific types” and gestational diabetes [6]. The etiologic classifications of diabetes mellitus are listed in (Table 2).

I. type 1Diabetes mellitus
A. Autoimmune
B. Idiopathic
II. type 2 Diabetes mellitus
Ranges from relative insulin deficiency to disorders
of insulin secretion and insulin resistance
III. Other specific types of diabetes mellitus
A. Genetic defects in β-cell function
1. Chromosome 12, HNF-1α (MODY 3)
2. Chromosome 7, glycosidase (MODY 2)
3. Chromosome 20, HNF-4α (MODY 1)
4. Mitochondrial DNA
5. Monogenic diabetes
B. Genetic defects in insulin action
1. Type A insulin resistance
2. Leprechaunism
3. Rabson-Mendenhall syndrome
4. Lipotrophic diabetes
C. Disease of the exocrine pancreas
1. Pancreatitis
2. Pancreatectomy/trauma
3. Neoplasia
4. Cystic fibrosis
5. Hemochromatosis
6. Fibrocalcificpancreatopathy
D. Endocrinopathies
1. Acromegaly
2. Cushing syndrome
3. Glucagonoma
4. Pheochromocytoma
5. Hyperthyroidism
6. Somatostatinoma
7. Aldosteronoma
i. Pharmacologically or chemically induced
1. Vacor
2. Pentamidine
3. Nicotinic acid
4. Glucocorticoids
5. Thyroid hormones
6. Diazoxide
7. β-adrenergic agonists
8. Tiazides
9. Dilantin
10. α interferon
ii. Infections
1. Congenital rubeola
2. Cytomegalovirus
iii. Infrequent forms of autoimmune diabetes
1. Stiff-man syndrome)
2. Antibodies against insulin receptors
iv. Other syndromes occasionally associated with diabetes
1. Down syndrome
2. Klinefelter syndrome
3. Turner syndrome
4. Wolfram syndrome
5. Friedreich ataxia
6. Huntington’s chorea
7. Lawrence-Moon-Biedel syndrome
8. Myotonic dystrophy
9. Porphyria
10. Prader-Willi syndrome
IV. Gestational diabetes mellitus
Occurs in mostly in women during gestation.

Table 2: Etiologic Classification of Diabetes Mellitus. Adapted from WHO and ADA [6,19].

Type 1 diabetes mellitus

Type 1 diabetes mellitus (juvenile diabetes) is characterized by beta cell destruction caused by an autoimmune process, usually leading to absolute insulin deficiency [20]. Type 1 is usually characterized by the presence of anti–glutamic acid decarboxylase, islet cell or insulin antibodies which identify the autoimmune processes that lead to beta cell destruction. Eventually, all type1 diabetic patients will require insulin therapy to maintain normglycemia.

Type 2 diabetes mellitus

The relative importance of defects in insulin secretion or in the peripheral action of the hormone in the occurrence of DM2 has been and will continue to be cause for discussion. DM2 comprises 80% to 90% of all cases of DM. Most individuals with Type 2 diabetes exhibit intra-abdominal (visceral) obesity, which is closely related to the presence of insulin resistance. In addition, hypertension and dyslipidemia (high triglyceride and low HDL-cholesterol levels; postprandial hyperlipidemia) often are present in these individuals. This is the most common form of diabetes mellitus and is highly associated with a family history of diabetes, older age, obesity and lack of exercise. It is more common in women, especially women with a history of gestational diabetes, and in Blacks, Hispanics and Native Americans.

Gestational Diabetes Mellitus (GDM)

Gestational diabetes mellitus is an operational classification (rather than a pathophysiologic condition) identifying women who develop diabetes mellitus during gestation. Women who develop Type 1 diabetes mellitus during pregnancy and women with undiagnosed asymptomatic Type 2 diabetes mellitus that is discovered during pregnancy are classified with Gestational Diabetes Mellitus (GDM). In most women who develop GDM; the disorder has its onset in the third trimester of pregnancy.

Other specific type (Monogenic diabetes)

Types of diabetes mellitus of various known etiologies are grouped together to form the classification called “Other Specific Types”. This group includes persons with genetic defects of beta-cell function (this type of diabetes was formerly called MODY or maturity-onset diabetes in youth) or with defects of insulin action; persons with diseases of the exocrine pancreas, such as pancreatitis or cystic fibrosis; persons with dysfunction associated with other endocrinopathies (e.g. acromegaly); and persons with pancreatic dysfunction caused by drugs, chemicals or infections and they comprise less than 10% of DM cases.

Clinical Features of Diabetes Mellitus

General symptoms

Most of the symptoms are similar in both types of diabetes but they vary in their degree and develop more rapidly in type 1 diabetes and more typical.

Clinical features of type I diabetes

Some of the symptoms include weight loss, polyurea, polydipsia, polyphagia, constipation fatigue, cramps, blurred vision, and candidiasis [21]. Long lasting type 1 DM patients may susceptible to microvascular complications; [22-24] and macrovascular disease (coronary artery, heart, and peripheral vascular diseases) [25].

Clinical features of Type II diabetes

Most cases are diagnosed because of complications or incidentally. Carries a high risk of large vessel atherosclerosis commonly associated with hypertension, hyperlipidaemia and obesity. Most patients with type 2 diabetes die from cardiovascular complications and end stage renal disease. Geographical variation can contribute in the magnitude of the problems and to overall morbidity and mortality [26-28] (Table 3).

Characteristic Type 1 Type 2 Monogenic
Genetics Polygenic Polygenic Monogenic
Age of onset 6 months to young adulthood Usually pubertal (or later)   Often post pubertal except Glucokinase and neonatal diabetes
Clinical presentation
Most often acute, rapid  

Variable; from slow, mild (often insidious) to severe
Variable (may be incidental in glucokinase)
Associations
Autoimmunity
Ketosis
Yes
Common  
No
Uncommon  
No
Common in neonatal diabetes, rare in other forms
Obesity
Population
Increased frequency Population frequency
Acanthosis nigricans
Frequency
(% of all diabetes
in young people)
Parent with diabetes
No Usually 90%+ 2-4% Yes Most countries 80% No 1-3% 90%

Table 3: Clinical characteristics of type 1 diabetes, type 2 diabetes and monogenic diabetes in children and adolescents. Adapted from Craig ME [29].

Pathogenesis and Pathophysiology of Diabetes Mellitus

There is a direct link between hyperglycemia and physiological & behavioral responses. Whenever there is hyperglycemia, the brain recognizes it and send a message through nerve impulses to pancreas and other organs to decrease its effect [30].

Type 1 diabetes mellitus

Type 1 Diabetes is characterized by autoimmune destruction of insulin producing cells in the pancreas by CD4+ and CD8+ T cells and macrophages infiltrating the islets [31]. Several features characterize type 1 diabetes mellitus as an autoimmune disease [32]:

1. Presence of immuno-competent and accessory cells in infiltrated pancreatic islets;

2. Association of susceptibility to disease with the class II (immune response) genes of the major histocompatibility complex (MHC; human leucocyte antigens HLA);

3. Presence of islet cell specific autoantibodies;

4. Alterations of T cell mediated immunoregulation, in particular in CD4+ T cell compartment;

5. The involvement of monokines and TH1 cells producing interleukins in the disease process;

6. Response to immunotherapy and;

7. Frequent occurrence of other organ specific auto- immune diseases in affected individuals or in their family members.

Approximately 85% of patients have circulating islet cell antibodies, and the majorities 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 [33].

The autoimmune destruction of pancreatic β-cells, leads to a deficiency of insulin secretion which results in the metabolic derangements associated with T1DM. In addition to the loss of insulin secretion, the function of pancreatic α-cells is also abnormal and there is excessive secretion of glucagons in T1DM patients. Normally, hyperglycemia leads to reduced glucagons secretion, however, in patients with T1DM, glucagons secretion is not suppressed by hyperglycemia [34]. The resultant inappropriately elevated glucagons levels exacerbate the metabolic defects due to insulin defi-ciency. Although insulin deficiency is the primary defect in T1DM, there is also a defect in the administration of insulin. Deficiency in insulin leads to uncontrolled lipolysis and elevated levels of free fatty acids in the plasma, which suppresses glucose metabolism in peripheral tissues such as skeletal muscle [34]. This impairs glucose utilization and insulin deficiency also decreases the expression of a number of genes necessary for target tissues to respond normally to insulin such as glucokinase in liver and the GLUT 4 class of glucose transporters in adipose tissue [34] explained that the major metabolic derangements, which result from insulin deficiency in T1DM are impaired glucose, lipid and protein metabolism.

Type 2 diabetes mellitus

In type 2 diabetes these mechanisms break down, with the consequence that the two main pathological defects in type 2 diabetes are impaired insulin secretion through a dysfunction of the pancreatic β-cell, and impaired insulin action through insulin resistance [35]. In situations where resistance to insulin predominates, the mass of β-cells undergoes a transformation capable of increasing the insulin supply and compensating for the excessive and anomalous demand. In absolute terms, the plasma insulin concentration (both fasting and meal stimulated) usually is increased, although “relative” to the severity of insulin resistance, the plasma insulin concentration is insufficient to maintain normal glucose homeostasis. Keeping in mind the intimate relationship between the secretion of insulin and the sensitivity of hormone action in the complicated control of glucose homeostasis, it is practically impossible to separate the contribution of each to the etiopathogenesis of DM2 [20].

Insulin resistance and hyperinsulinemia eventually lead to impaired glucose tolerance [36]. Except for maturity onset diabetes of the young (MODY), the mode of inheritance for type 2 diabetes mellitus is unclear. MODY, inherited as an autosomal dominant trait, may result from mutations in glucokinase gene on chromosome 7p. MODY is defined as hyperglycemia diagnosed before the age of twenty-five years and treatable for over five years without insulin in cases where islet cell antibodies (ICA) are negative [26].

Insulin resistance

The primary events are believed to be an initial deficit in insulin secretion and in many patients relative insulin deficiency in association with peripheral insulin resistance [37]. Resistance to the action of insulin will result in impaired insulin mediated glucose uptake in the periphery (by muscle and fat), incomplete suppression of hepatic glucose output and impaired triglyceride uptake by fat. To overcome the insulin resistance, islet cells will increase the amount of insulin secreted. Endogenous glucose production is accelerated in patients with type 2 diabetes or impaired fasting glucose. Because this increase occurs in the presence of hyper insulinemia, at least in the early and intermediate disease stages, hepatic insulin resistance is the driving force of hyperglycemia of type 2 diabetes (Figure 1- 7).

diabetes-metabolism-Physiologic-Behavioral

Figure 1: Physiologic and Behavioral response of hyperglycemia. Adapted from Cryer [30].

diabetes-metabolism-Pathogenesis-type

Figure 2: Pathogenesis of type 1 diabetes.

diabetes-metabolism-Hyperglycemia-increased

Figure 3: Pathophysiology of Hyperglycemia and increased circulating fatty acids in type 2 Diabetes. Adapted from Pittas [26].

diabetes-metabolism-stimulating-alpha-cell

Figure 4: Panel A shows the physiological effect of a decrease in insulin coupled with a low glucose concentration in stimulating alpha-cell glucagon secretion, and Panel B shows the pathophysiological effect of beta-cell failure and the resulting loss of a decrease in insulin secretion and loss of an increase in alpha-cell glucagon secretion, despite a low glucose concentration. Adapted from Cryer [39].

diabetes-metabolism-screening-patients

Figure 5: Suggested approach to screening patients at risk for diabetes. Adapted from Salomaa and Diabetes Care [36,48].

diabetes-metabolism-Adapted-Josephine

Figure 6: Schematic overview of the major areas contributing to diabetic complications. Adapted from Josephine M [40].

diabetes-metabolism-diabetes-mellitus

Figure 7: General management of diabetes mellitus. Adapted from Riddle MC [63].

Complications of diabetes mellitus

1- Acute complications

1.1 Hypoglycemia

1.2 Hyperglycemic crises

Diabetes Ketoacidosis (DKA)

Hyperglycemic hyperosmolar state (HHS)

2- Chronic complications:

2.1 Micro vascular complications

2.1.1 Diabetic retinopathy

2.1.2 Diabetic nephropathy

2.1.3 Diabetic neuropathy

2.2 Macrovascular disease

3- Other complications and associated conditions

3.1 Impaired growth and development

3.2 Associated autoimmune conditions

3.2.1 Hypothyroidism

3.2.2 Hyperthyroidism

3.2.3 Celiac disease

3.2.4 Vitiligo

3.2.5 Primary adrenal insufficiency (Addison’s disease)

3.3 Lipodystrophy (lipoatrophy and lipohypertrophy)

3.4 Necrobiosis lipoidica diabeticorum

3.5 Non-alcoholic fatty liver disease

3.6 Infections seen in patients with diabetes

3.7 Limited joint mobility

3.8 Edema

Diagnosis of diabetes mellitus

The identification of patients with diabetes or pre-diabetes by screening allows for earlier intervention, with potential reductions in future complication rates, although randomized trials are lacking to definitively show benefit. The patient described in the vignette has risk factors (obesity, hypertension, and a family history of diabetes) and should be screened (Table 4) [38-40]. About 25% of patients with type 2 DM already have microvascular complications at the time of diagnosis suggesting that they have had the disease for more than 5 years at the time of diagnosis [41,42]. As a result there are different approaches to diagnose diabetes among individuals.

1.      Insulin resistance: usually associated with obesity
2.      Family history of T2DM in first- or second-degree relative
3.      Ethnicity: African-American, Hispanic, Pacific Islander, Native American, Canadian First Nation
4.      Small size for gestational age (intrauterine growth restriction)
5.      Maternal gestational diabetes
6.      Insulin resistance of puberty
7.      Lack of physical activity
8.      High-calorie diet

Table 4: Risk factors for T2DM in youth. Adapted from Botero D [38].

The 1997 American Diabetes Association (ADA) recommendations for diagnosis of DM focus on Fasting Plasma Glucose (FPG), while WHO focuses on the Oral Glucose Tolerance Test (OGTT) [43] (Table 5).

Criteria:
*       Overweight and obese children
o       BMI >85th percentile for age and sex
o       Weight for height >85th percentile
o       Weight >120% of ideal for height

Plus any two of the following risk factors:
a. Family history of T2DM in first or second-degree relative
b. Race/Ethnicity
* Native-American                    * Latino
 * African-American                 * Asian American
* Pacific Islander                         
c. Signs of insulin resistance or conditions associated with insulin resistance
* Acanthosis nigricans                  * Hypertension
* Dyslipidemia                              * PCOS
* Small for gestational age birth weight
d. Maternal history of diabetes or GDM during the child's gestation

Age of initiation:  age 10 years or at onset of puberty, if puberty occurs at a younger age

Frequency: every 3 years

Preferred Test: Fasting plasma glucose

Table 5: Modified ADA Guidelines for screening children and youths for T2DM. Adapted from ADA [42].

Diagnosis of both types of diabetes

Random plasma test

• The simplest test and doesn’t require fasting before taking the test.

• If 200 or more than 200 mg/dl of blood glucose it probably indicates diabetes but has to be reconfirmed.

Fasting plasma glucose test:

• There should be eight hours fasting before taking this test. Blood glucose more than 126 mg/dl on two or more tests conducted on different days confirms a diabetes diagnosis [43].

Oral glucose tolerance test

• When random plasma glucose test is 160-200 mg/dl and the fasting plasma test is 110-125 mg/dl, then this test is conducted [7].

• This blood test evaluates body’s response to glucose. This test requires fasting at least eight but not more than 16 hrs.

• Fasting glucose level is determined, and then gives 75 gm of glucose, 100 gm for pregnant women. The blood is tested every 30 minutes to one hr for two or three hrs.

• This test is normal if your glucose level at two hrs is less than 140 mg/dl. A fasting level of 126 mg/dl or greater and two hour glucose level of 200 mg/dl or Higher confirms a diabetes diagnosis [43].

Glycated proteins

Proteins react spontaneously in blood with glucose to form glycated derivatives. The extent of glycation of proteins is controlled by the concentration of glucose in blood and by the number of reactive amino groups present in the protein that are accessible to glucose for reaction. All proteins with reactive sites can be glycated and the concentration of the glycated proteins that can be measured in blood is a marker for the fluctuation of blood glucose concentrations during a certain period. From a clinical diagnostic point glycated proteins with a longer life time in blood are of interest, since they reflect the exposure of these proteins to glucose for longer periods

Glycated hemoglobin

The life span of hemoglobin in vivo is 90 to120 days. During this time glycated hemoglobin A forms, being the ketoamine compound formed by combination of hemoglobin A and glucose. Several subfractions of glycated hemoglobin have been isolated. Of these, glycated hemoglobin A fraction HbA1c is of most interest serving as a retrospective indicator of the average glucose Concentration. HbA1c is recommended as an essential indicator for the monitoring of blood glucose control. The blood HbA1c≥ 6.5% is considered as diabetes [44].

Fructosamine test

Albumin is the main component of plasma proteins. As albumin also contains free amino groups, non-enzymatic reaction with glucose in plasma occurs. Therefore glycated albumin can similarly serve as a marker to monitor blood glucose. Glycated albumin is usually taken to provide a retrospective measure of average blood glucose concentration over a period of 1 to 3 weeks. Reference interval: 205- 285 micro mol/L.

Diagnosis of gestational diabetes mellitus

At least 6 weeks after the pregnancy ends, the woman should receive an oral glucose tolerance test and be reclassified as having diabetes, normal glucose tolerance, impaired

glucose tolerance or impaired fasting glucose (Table 6). Women at high risk (positive family history, history of GDM, marked obesity, and high risk ethnic group) should be screened as soon as feasible. If the initial screening is negative, they should undergo retesting at 24-48 weeks. The diagnosis of GDM is made if two or more of the plasma glucose values in (Table 7) are met or exceeded [32].

Time Plasma Glucose
Fasting ≥95mg/dl(5.3mmol/L)
1-hour ≥180mg/dl(10.0mmol/L)
2-hour ≥155mg/dl(8.6mmol/L)
3-hour ≥140mg/dl(7.8mmol/L)

Table 6: Diagnosis of gestational diabetes.

Measure American Diabetes Association World Health Organization
  Diabetes          Prediabetes                              Diabetes           Impaired          
glucose
Fasting plasma glucose ≥ 126 mg/dl    100-125
mg/dl(IFG)         
≥ 126 mg/dl      110-125
mg/dl     
(IFG)
2-Hr plasma glucose (during
An OGTT with a loading dose
Of 75 g
≥ 200 mg/dl    140-199    
Mg/dl   
(IGT)
≥ 200 mg/dl     140-199
mg/dl     
(IGT)
Casual(random ) plasma glucose
(In a patient with classic hyper
Glycemic symptom)
≥ 200 mg/dl ≥ 200 mg/dl
Glycated hemoglobin ≥ 6.5%           5.7-6.4% ≥ 6.5%               

Table 7: Major diagnostic criteria for diabetes and prediabetic or at-risk states. Data are adapted from the American Diabetes Association. Adapted from Salomaa and Diabetes Care [22,23].

It is unclear whether the risk of complications of diabetes differs according to whether the disease was diagnosed by means of fasting plasma glucose testing only or glycated hemoglobin testing only. Preliminary data from a large, community- based prospective cohort study suggest that the glycated hemoglobin level, which integrates fasting and postprandial glucose levels over a longer period, might be a better predictor of certain complications especially cardiovascular disease [45]. It is also not known whether the risk of diabetes differs between patients identified as having pre-diabetes by means of glycated hemoglobin testing and those identified by means of fasting plasma glucose testing. Such risks probably vary according to which test is used ultimately to make the diagnosis. Ongoing research is assessing the value of risk scores that incorporate not only glycemic measures but also other biomarkers and risk factors to estimate diabetes risk [46,47].

Impaired fasting glucose (IFG) is defined as a fasting plasma glucose (FPG) level of 100 to 125 mg/dl (5.6 to 6.9 mmol/liter). Increased glycated hemoglobin (IGH) is defined as a glycated hemoglobin level of 5.7 to 6.4%. The diagnosis of diabetes is confirmed with a repeat test on a separate day or by the alternative test (i.e. glycated hemoglobin instead of FPG or vice versa) on the same day or a separate day. If the result of the repeat test is in the prediabetic range, the patient should be counseled or treated for pre-diabetes. If the result of the repeat test is entirely normal (which is unlikely), rescreening in 6 months should be considered.

Glycemic Management

One of the biggest challenges for health care providers today is addressing the continued needs and demands of individuals with chronic illnesses like diabetes [49]. The importance of regular follow-up of diabetic patients with the health care provider is of great significance in averting any long term complications. Studies have reported that strict metabolic control can delay or prevent the progression of complications associated with diabetes [50,51]. Results of large randomized trials involving patients with type 1 diabetes or newly recognized or established type 2 diabetes show that control of glycemia delays the onset and slows the progression of micro vascular complications, including nephropathy, retinopathy, and neuropathy [52-54]. The needs of diabetic patients are not only limited to adequate glycemic control but also correspond with preventing complications; disability limitation and rehabilitation. Some of the Indian studies revealed very poor adherence to treatment regimens due to poor attitude towards the disease and poor health literacy among the general public [55,56].

Factors that should be considered in determining glycemic goals, including psychosocial limitation [57]. Glycemic targets in patients with “hypoglycemia unawareness” should be relaxed for prolonged periods, pending the potential reversal of the condition [58,59]. In patients with severe coexisting conditions that could interfere with implementation of the management strategy, the goal is prevention of clinically significant glycosuria, water and electrolyte loss, infections, and the development of non ketotic hyperosmolar coma. Insulin is indicated for type 1 diabetes as well as for type 2 diabetic patients with insulinopenia whose hyperglycemia does not respond to diet therapy either alone or combined with oral hypoglycemic drugs [60]. Controlling blood glucose with insulin has the potential to be the most effective blood glucose-lowering therapy [61]. Many patients with type 2 diabetes will eventually require insulin therapy. Since type 2 diabetes is associated with insulin resistance, insulin requirements can exceed 1 unit/kg/day [62].

Future Challenges

Given that the prevalence of diabetes is high at the population level, it imposes a financial burden on both our healthcare system and the individuals living with the disease. An attempt continues to be discussed; yet as the number of undiagnosed patients continues to grow, the prevalence and impact of the disease on patient quality of life and the overall cost of diabetes to healthcare is also important.

The impact of diabetes is reaches in a crude state, it is essential to each country for implementation of preventive and curative measures. This may include restaurants to provide the caloric content of items on their menus; reduce the availability of high calorie, high-fat foods in school cafeterias; Lifestyle modification will undoubtedly play a key role in the ultimate solution to the problem of diabetes, and more definitive solutions will depend on the ability of basic science to point prevention and treatment in new directions.

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