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LabCorp

Diabetes Risk Assessment / Prediabetes Screen

$28.00
5054
090400
Only 100 units of this product remain
Phlebotomy (IV Blood Draw)

Screen for prediabetes and diabetes in asymptomatic adults.

Hemoglobin A1c: Any cause of shortened erythrocyte survival will reduce exposure of erythrocytes to glucose with a consequent decrease in Hb A1c (%). Causes of shortened erythrocyte lifetime might be hemolytic anemia or other other hemolytic diseases, homozygous sickle cell trait, pregnancy, or recent significant or chronic blood loss. Glycated Hb F (fetal hemoglobin) is not detected as it does not contain the glycated beta chain that characterizes Hb A1c. Specimens containing high amounts of Hb F(>10%) may result in lower than expected Hb A1c.

Screening for prediabetes and type 2 diabetes is important in all patients 45 years of age and older and others (see below) because both are common and often have a long, pre-symptomatic stage. Additionally, both conditions meet criteria for which early detection is appropriate and advantageous, especially since simple tests are readily available and effective interventions exist.

Current American Diabetes Association (ADA) testing criteria for prediabetes and diabetes in asymptomatic adults includes:

• All patients 45 years of age or older

• Consider in overweight or obese (BMI greater than or equal to 25 kg/m² or greater than or equal to 23 kg/m² in Asian Americans) adults of any age with one or more of the following risk factors:

- 1st degree relative with diabetes

- High risk race/ethnicity (eg, African American, Latino, Native American, Asian American, Pacific Islander)

- History of CVD

- Hypertension or on therapy for hypertension

- HDL-C value < 35 mg/dL and/or triglyceride value > 250 mg/dL

- Polycystic ovary syndrome

- Physical inactivity

- Conditions associated with insulin resistance (eg, severe obesity, acanthosis nigrans)

Fasting plasma glucose (FPG), plasma glucose after 75-gram oral glucose tolerance test (OGTT) and hemoglobin A1c (A1c) are equally appropriate assays for prediabetes and diabetes screening. 2018 ADA standards of medical care mandate that two abnormal test results (ie, both FPG and A1c) are needed for diagnosis unless there is a clear clinical diagnosis (ie, random plasma glucose greater than or equal to 200 mg/dL). A single abnormal test can be repeated using a new blood sample for confirmation.

Hemoglobin A1c: Factors such as duration of diabetes, adherence to therapy, and age of patient should also be considered in assessing the degree of blood glucose control.

FPG: Recent evidence revealed diurnal variation in FPG, with mean FPG higher in the morning than in the afternoon, indicating that many cases of undiagnosed diabetes would be missed in patients seen in the afternoon. Glucose concentrations decrease ex vivo with time in whole blood because of glycolysis. For this reason, samples should be centrifuged promptly. The rate of glycolysis, reported to average 5% to 7% [approximately 0.6 mmol/L (10 mg/dL)] per hour, varies with the glucose concentration, temperature, white blood cell count, and other factors. Glycolysis can be attenuated by inhibition of enolase with sodium fluoride (2.5 mg fluoride/mL of blood) or, less commonly, lithium iodoacetate (0.5 mg/mL of blood). These reagents can be used alone or, more commonly, with anticoagulants such as potassium oxalate, EDTA, citrate, or lithium heparin. Although fluoride maintains long-term glucose stability, the rate of decline of glucose in the first hour after sample collection in tubes with and without fluoride is virtually identical. (Note that leukocytosis will increase glycolysis even in the presence of fluoride if the white cell count is very high). After four hours, the glucose concentration is stable in whole blood for 72 hours at room temperature in the presence of fluoride. In separated, non-hemolyzed, sterile serum without fluoride, the glucose concentration is stable for eight hours at 25°C and 72 hours at 4°C.

Glucose can be measured in serum, or plasma, but plasma is recommended for diagnosis. Glucose concentrations in heparinized plasma are reported to be 5% lower than in serum. The reasons for the latter difference are not apparent, but may be attributable to the shift in fluid from erythrocytes to plasma caused by anticoagulants. The glucose concentrations during an OGTT in capillary blood are significantly higher than those in venous blood [mean of 1.7 mmol/L (30 mg/dL), equivalent to 20% to 25%], but the mean difference in fasting samples is only 0.1 mmol/L (2 mg/dL).

Although methods for glucose analysis exhibit low imprecision at the diagnostic decision limits of 7.0 mmol/L [(126 mg/dL), fasting] and 11.1 mmol/L [(200 mg/dL), post-glucose load], the relatively large intraindividual biological variability (Coefficients of variation of approximately 5% to 7%) may produce classification errors.

American Diabetes Association. Classification and diagnosis of diabetes. Diabetes Care. 2015 Jan;38 Suppl:S8-S16. PubMed 25537714

American Diabetes Association. Summary of revisions for the 2010 Clinical Practice Recommendations. Diabetes Care. 2010 Jan;33 Suppl 1:S3. PubMed 20042773

Berstrom RW, Kelley JR, Ward WK. Fetal hemoglobin alters hemoglobin A1c measurements. Ann Intern Med. 1991 Oct 15;115(8):656. PubMed 1716431

Fairbanks VF, Zimmerman BR. Measurement of glycosylated hemoglobin by affinity chromatography. Mayo Clin Proc. 1983 Nov;58(11):770-773. PubMed 6632974

Holt GS, Wofford JL, Velez R. Hemoglobinopathies affect hemoglobin A1c measurement. Ann Intern Med. 1991 Jul 1;115(1):68-69. PubMed 1760005

Krauss JS, Khankhanian NK. HPLC determination of hemoglobin A1c in the presence of the fast hemoglobin I-Philadelphia. Clin Chem. 1989 Mar;35(3):494-495. PubMed 2920422

Sacks D, Bruns DE, Goldstein DE, Maclaren NK, McDonald JM, Parrott M. Guidelines and recommendations for laboratory analysis in the diagnosis and management of diabetes mellitus. Clin Chem. 2002 Mar;48(3):436-472. PubMed 11861436

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