Glycated hemoglobin

Template:Short description Template:Redirect Template:Infobox diagnostic

Glycated hemoglobin, also called glycohemoglobin, is a form of hemoglobin (Hb) that is chemically linked to a sugar.Template:NoteTag Most monosaccharides, including glucose, galactose, and fructose, spontaneously (that is, non-enzymatically) bond with hemoglobin when they are present in the bloodstream. However, glucose is only 21% as likely to do so as galactose and 13% as likely to do so as fructose, which may explain why glucose is used as the primary metabolic fuel in humans.<ref name="pmid12192669">Template:Cite journal</ref><ref>Template:Cite journal</ref>

The formation of excess sugar-hemoglobin linkages indicates the presence of excessive sugar in the bloodstream and is an indicator of diabetes or other hormone diseases in high concentration Template:Nowrap.<ref>Template:Cite journal</ref> A1c is of particular interest because it is easy to detect. The process by which sugars attach to hemoglobin is called glycation and the reference system is based on HbA1c, defined as beta-N-1-deoxy fructosyl hemoglobin as component.<ref name="pmid16112961">Template:Cite journal</ref>

There are several ways to measure glycated hemoglobin, of which HbA1c (or simply A1c) is a standard single test.<ref name="umich">Elizabeth Weiser Caswell Diabetes Institute. Hemoglobin A1c Fact Sheet. Accessed 2024-07-02.</ref> HbA1c is measured primarily to determine the three-month average blood sugar level and is used as a standard diagnostic test for evaluating the risk of complications of diabetes and as an assessment of glycemic control.<ref name=umich/><ref>Template:Cite book</ref> The test is considered a three-month average because the average lifespan of a red blood cell is three to four months. Normal levels of glucose produce a normal amount of glycated hemoglobin. As the average amount of plasma glucose increases, the fraction of glycated hemoglobin increases in a predictable way. In diabetes, higher amounts of glycated hemoglobin, indicating higher blood glucose levels, have been associated with cardiovascular disease, nephropathy, neuropathy, and retinopathy.<ref name="pmid28760792" />

TerminologyEdit

Glycated hemoglobin is preferred over glycosylated hemoglobin to reflect the correct (non-enzymatic) process. Early literature often used glycosylated as it was unclear which process was involved until further research was performed. The terms are still sometimes used interchangeably in English-language literature.<ref>Template:Cite journal</ref>

The naming of HbA1c derives from hemoglobin type A being separated on cation exchange chromatography. The first fraction to separate, probably considered to be pure hemoglobin A, was designated HbA0, and the following fractions were designated HbA1a, HbA1b, and HbA1c, in their order of elution. Improved separation techniques have subsequently led to the isolation of more subfractions.<ref name="pmid9732983">Template:Cite journal</ref>

HistoryEdit

Hemoglobin A1c was first separated from other forms of hemoglobin by Huisman and Meyering in 1958 using a chromatographic column.<ref>Template:Cite journal</ref> It was first characterized as a glycoprotein by Bookchin and Gallop in 1968.<ref name="pmid4874776">Template:Cite journal</ref> Its increase in diabetes was first described in 1969 by Samuel Rahbar et al.<ref name="pmid5808299">Template:Cite journal</ref> The reactions leading to its formation were characterized by Bunn and his coworkers in 1975.<ref name="pmid1201013">Template:Cite journal</ref>

The use of hemoglobin A1c for monitoring the degree of control of glucose metabolism in diabetic patients was proposed in 1976 by Anthony Cerami, Ronald Koenig, and coworkers.<ref name="pmid934240">Template:Cite journal</ref>

Damage mechanismsEdit

Glycated hemoglobin causes an increase of highly reactive free radicals inside blood cells, altering the properties of their cell membranes. This leads to blood cell aggregation and increased blood viscosity, which results in impaired blood flow.<ref name=":0">Template:Cite journal</ref>

Another way glycated hemoglobin causes damage is via inflammation, which results in atherosclerotic plaque (atheroma) formation. Free-radical build-up promotes the excitation of Fe²⁺-hemoglobin through Template:Nobr into abnormal ferryl hemoglobin (Fe⁴⁺-Hb). Fe⁴⁺ is unstable and reacts with specific amino acids in hemoglobin to regain its Fe³⁺ oxidation state. Hemoglobin molecules clump together via cross-linking reactions, and these hemoglobin clumps (multimers) promote cell damage and the release of Fe⁴⁺-hemoglobin into the matrix of innermost layers (subendothelium) of arteries and veins. This results in increased permeability of interior surface (endothelium) of blood vessels and production of pro-inflammatory monocyte adhesion proteins, which promote macrophage accumulation in blood vessel surfaces, ultimately leading to harmful plaques in these vessels.<ref name=":0"/>

Highly glycated Hb-AGEs go through vascular smooth muscle layer and inactivate acetylcholine-induced endothelium-dependent relaxation, possibly through binding to nitric oxide (NO), preventing its normal function. NO is a potent vasodilator and also inhibits formation of plaque-promoting LDLs (sometimes called "bad cholesterol") oxidized form.<ref name=":0"/>

This overall degradation of blood cells also releases heme from them. Loose heme can cause oxidation of endothelial and LDL proteins, which results in plaques.<ref name=":0"/>

Principle in medical diagnosticsEdit

Glycation of proteins is a frequent occurrence, but in the case of hemoglobin, a nonenzymatic condensation reaction occurs between glucose and the N-end of the beta chain. This reaction produces a Schiff base (Template:Chem2, R=beta chain, CHR'=glucose-derived), which is itself converted to 1-deoxyfructose. This second conversion is an example of an Amadori rearrangement.Template:Cn

When blood glucose levels are high, glucose molecules attach to the hemoglobin in red blood cells. The longer hyperglycemia occurs in blood, the more glucose binds to hemoglobin in the red blood cells and the higher the glycated hemoglobin.<ref name="pmid33806493">Template:Cite journal</ref>

Once a hemoglobin molecule is glycated, it remains that way. A buildup of glycated hemoglobin within the red cell, therefore, reflects the average level of glucose to which the cell has been exposed during its life-cycle. Measuring glycated hemoglobin assesses the effectiveness of therapy by monitoring long-term serum glucose regulation.

A1c is a weighted average of blood glucose levels during the life of the red blood cells (117 days for men and 106 days in women<ref>Template:Cite journal</ref>). Therefore, glucose levels on days nearer to the test contribute substantially more to the level of A1c than the levels in days further from the test.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

This is also supported by data from clinical practice showing that HbA1c levels improved significantly after 20 days from start or intensification of glucose-lowering treatment.<ref>Template:Cite journal</ref>

MeasurementEdit

Several techniques are used to measure hemoglobin A1c. Laboratories may use high-performance liquid chromatography, immunoassay, enzymatic assay, capillary electrophoresis, or boronate affinity chromatography. Point of care (e.g., doctor's office) devices use immunoassay boronate affinity chromatography.<ref name="pmid33806493"/>

In the United States, HbA_1c testing laboratories are certified by the National Glycohemoglobin Standardization Program to standardize them against the results of the 1993 Diabetes Control and Complications Trial (DCCT).<ref>Developing Point of care HbA1c tests for Diabetes monitoring Template:Webarchive, Barry Plant, Originally Published IVDT July/August 2008</ref> An additional percentage scale, Mono S has previously been in use by Sweden and KO500 is in use in Japan.<ref>[Clinical Chemistry 50:1 166–174 (2004)]</ref><ref name=SDA>HbA1c in a new way Template:Webarchive By the Swedish Diabetes Association. Retrieved 2023-02-01.</ref>

Switch to IFCC unitsEdit

The American Diabetes Association, European Association for the Study of Diabetes, and International Diabetes Federation have agreed that, in the future, HbA_1c is to be reported in the International Federation of Clinical Chemistry and Laboratory Medicine (IFCC) units.<ref name="pmid18539643">Template:Cite journal</ref> IFCC reporting was introduced in Europe except for the UK in 2003;<ref name="pmid15209757">Template:Cite journal</ref> the UK carried out dual reporting from 1 June 2009 <ref>Template:Cite press release</ref> until 1 October 2011.

Conversion between DCCT and IFCC is by the following equation:<ref name="DiabetesUK conversion">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

<math> \mathrm{IFCC\ HBA1c}\, \Big(\frac{\text{mmol}}{\text{mol}}\Big)=[\mathrm{DCCT\ HBA1c}\,(\%) - 2.14] \times 10.929 </math>

Interpretation of resultsEdit

Laboratory results may differ depending on the analytical technique, the age of the subject, and biological variation among individuals. Higher levels of HbA_1c are found in people with persistently elevated blood sugar, as in diabetes mellitus. While diabetic patient treatment goals vary, many include a target range of HbA_1c values. A diabetic person with good glucose control has an HbA_1c level that is close to or within the reference range.Template:Citation needed

The International Diabetes Federation and the American College of Endocrinology recommend HbA_1c values below 48 mmol/mol (6.5 DCCT %), while the American Diabetes Association recommends HbA_1c be below 53 mmol/mol (7.0 DCCT %) for most patients.<ref>Template:Cite journal</ref> Results from large trials in Template:Nowrap suggested that a target below 53 mmol/mol (7.0 DCCT %) for older adults with type 2 diabetes may be excessive: Below 53 mmol/mol, the health benefits of reduced A1c become smaller, and the intensive glycemic control required to reach this level leads to an increased rate of dangerous hypoglycemic episodes.<ref>Template:Cite journal</ref>

A retrospective study of 47,970 type 2 diabetes patients, aged 50 years and older, found that patients with an HbA_1c more than 48 mmol/mol (6.5 DCCT %) had an increased mortality rate,<ref>Template:Cite journal</ref> but a later international study contradicted these findings.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Cite journal (Template:ClinicalTrialsGov)</ref><ref>Template:Cite journal</ref>

A review of the UKPDS, Action to Control Cardiovascular Risk in Diabetes (ACCORD), Advance and Veterans Affairs Diabetes Trials (VADT) estimated that the risks of the main complications of diabetes (diabetic retinopathy, diabetic nephropathy, diabetic neuropathy, and macrovascular disease) decreased by about 3% for every 1 mmol/mol decrease in HbA_1c.<ref>Template:Cite journal</ref>

However, a trial by ACCORD designed specifically to determine whether reducing HbA_1c below 42 mmol/mol (6.0 DCCT %) using increased amounts of medication would reduce the rate of cardiovascular events found higher mortality with this intensive therapy, so much so that the trial was terminated 17 months early.<ref name=accord2008>Template:Cite journal</ref>

Practitioners must consider patients' health, their risk of hypoglycemia, and their specific health risks when setting a target HbA_1c level. Because patients are responsible for averting or responding to their own hypoglycemic episodes, their input and the doctors' assessments of the patients' self-care skills are also important.Template:Cn

Persistent elevations in blood sugar (and, therefore, HbA_1c) increase the risk of long-term vascular complications of diabetes, such as coronary disease, heart attack, stroke, heart failure, kidney failure, blindness, erectile dysfunction, neuropathy (loss of sensation, especially in the feet), gangrene, and gastroparesis (slowed emptying of the stomach). Poor blood glucose control also increases the risk of short-term complications of surgery such as poor wound healing.Template:Cn

All-cause mortality is higher above 64 mmol/mol (8.0 DCCT%) HbA1c as well as below 42 mmol/mol (6.0 DCCT %) in diabetic patients, and above 42 mmol/mol (6.0 DCCT %) as well as below 31 mmol/mol (5.0 DCCT %) in non-diabetic persons, indicating the risks of hyperglycemia and hypoglycemia, respectively.<ref name="pmid28760792">Template:Cite journal</ref> Similar risk results are seen for cardiovascular disease.<ref name="pmid28760792"/>

The 2022 ADA guidelines reaffirmed the recommendation that HbA1c should be maintained below 7.0% for most patients. Higher target values are appropriate for children and adolescents, patients with extensive co-morbid illness and those with a history of severe hypoglycemia. More stringent targets (<6.0%) are preferred for pregnant patients if this can be achieved without significant hypoglycemia.<ref name="2022 ADA Guidelines" />

Factors other than glucose that affect A1cEdit

Lower-than-expected levels of HbA_1c can be seen in people with shortened red blood cell lifespans, such as with glucose-6-phosphate dehydrogenase deficiency, sickle-cell disease, or any other condition causing premature red blood cell death. For these patients, alternate assessment with fructosamine or glycated albumin is recommended; these methods reflect glycemic control over the preceding 2-3 weeks.<ref name="Sacks" /> Blood donation will result in rapid replacement of lost RBCs with newly formed red blood cells. Since these new RBCs will have only existed for a short period of time, their presence will lead HbA_1c to underestimate the actual average levels. There may also be distortions resulting from blood donation during the preceding two months, due to an abnormal synchronization of the age of the RBCs, resulting in an older than normal average blood cell life (resulting in an overestimate of actual average blood glucose levels). Conversely, higher-than-expected levels can be seen in people with a longer red blood cell lifespan, such as with iron deficiency.<ref name="Kilpatrick 2009">Template:Cite journal</ref>

Results can be unreliable in many circumstances, for example after blood loss, after surgery, blood transfusions, anemia, or high erythrocyte turnover; in the presence of chronic renal or liver disease; after administration of high-dose vitamin C; or erythropoetin treatment.<ref name="pmid18540046">Template:Cite journal</ref> Hypothyroidism can artificially raise the A1c.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> In general, the reference range (that found in healthy young persons), is about 30–33 mmol/mol (4.9–5.2 DCCT %).<ref>Template:Cite journal</ref> The mean HbA_1c for diabetics type 1 in Sweden in 2014 was 63 mmol/mol (7.9 DCCT%) and for type 2, 61 mmol/mol (7.7 DCCT%).<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> HbA1c levels show a small, but statistically significant, progressive uptick with age; the clinical importance of this increase is unclear.<ref name="Sacks" />

Mapping from A1c to estimated average glucoseEdit

The approximate mapping between HbA_1c values given in DCCT percentage (%) and eAG (estimated average glucose) measurements is given by the following equation:<ref name="pmid18540046"/>

eAG(mg/dL) = 28.7 × A1C − 46.7
eAG(mmol/L) = 1.59 × A1C − 2.59
(Data in parentheses are 95% confidence intervals>)

Normal, prediabetic, and diabetic rangesEdit

The 2010 American Diabetes Association Standards of Medical Care in Diabetes added the HbA_1c ≥ 48 mmol/mol (≥6.5 DCCT %) as another criterion for the diagnosis of diabetes.<ref name="care.diabetesjournals.org">Template:Cite journal</ref>

Indications and usesEdit

Glycated hemoglobin testing is recommended for both checking the blood sugar control in people who might be prediabetic and monitoring blood sugar control in patients with more elevated levels, termed diabetes mellitus. For a single blood sample, it provides far more revealing information on glycemic behavior than a fasting blood sugar value. However, fasting blood sugar tests are crucial in making treatment decisions. The American Diabetes Association guidelines are similar to others in advising that the glycated hemoglobin test be performed at least twice a year in patients with diabetes who are meeting treatment goals (and who have stable glycemic control) and quarterly in patients with diabetes whose therapy has changed or who are not meeting glycemic goals.<ref>Template:Cite journal</ref><ref name="2022 ADA Guidelines" />

Glycated hemoglobin measurement is not appropriate where a change in diet or treatment has been made within six weeks. Likewise, the test assumes a normal red blood cell aging process and mix of hemoglobin subtypes (predominantly HbA in normal adults). Hence, people with recent blood loss, hemolytic anemia, or genetic differences in the hemoglobin molecule (hemoglobinopathy) such as sickle-cell disease and other conditions, as well as those who have donated blood recently, are not suitable for this test.<ref>Template:Cite journal</ref>

Due to glycated hemoglobin's variability, additional measures should be checked in patients at or near recommended goals. People with HbA_1c values at 64 mmol/mol or less should be provided additional testing to determine whether the HbA_1c values are due to averaging out high blood glucose (hyperglycemia) with low blood glucose (hypoglycemia) or the HbA_1c is more reflective of an elevated blood glucose that does not vary much throughout the day. Devices such as continuous blood glucose monitoring allow people with diabetes to determine their blood glucose levels on a continuous basis, testing every few minutes. Continuous use of blood glucose monitors is becoming more common, and the devices are covered by many health insurance plans, including Medicare in the United States. The supplies tend to be expensive, since the sensors must be changed at least every 2 weeks. Another useful test in determining if HbA_1c values are due to wide variations of blood glucose throughout the day is 1,5-anhydroglucitol, also known as GlycoMark. GlycoMark reflects only the times that the person experiences hyperglycemia above 180 mg/dL over a two-week period.Template:Citation needed

Concentrations of hemoglobin A1 (HbA1) are increased, both in diabetic patients and in patients with kidney failure, when measured by ion-exchange chromatography. The thiobarbituric acid method (a chemical method specific for the detection of glycation) shows that patients with kidney failure have values for glycated hemoglobin similar to those observed in normal subjects, suggesting that the high values in these patients are a result of binding of something other than glucose to hemoglobin.<ref>Template:Cite journal</ref>

In autoimmune hemolytic anemia, concentrations of HbA1 is undetectable. Administration of prednisolone will allow the HbA1 to be detected.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> The alternative fructosamine test may be used in these circumstances and it also reflects an average of blood glucose levels over the preceding 2 to 3 weeks.<ref>Template:Cite journal</ref>

All the major institutions such as the International Expert Committee Report, drawn from the International Diabetes Federation, the European Association for the Study of Diabetes, and the American Diabetes Association, suggest the HbA_1c level of 48 mmol/mol (6.5 DCCT %) as a diagnostic level.<ref>Template:Cite journal</ref> The Committee Report further states that, when HbA_1c testing cannot be done, the fasting and glucose-tolerance tests be done. Screening for diabetes during pregnancy continues to require fasting and glucose-tolerance measurements for gestational diabetes at 24 to 28 weeks gestation, although glycated hemoglobin may be used for screening at the first prenatal visit.<ref name = "Sacks">Template:Cite journal</ref>

Modification by dietEdit

Meta-analysis has shown probiotics to cause a statistically significant reduction in glycated hemoglobin in type-2 diabetics.<ref name="pmid26899960">Template:Cite journal</ref> Trials with multiple strains of probiotics had statistically significant reductions in glycated hemoglobin, whereas trials with single strains did not.<ref name="pmid26899960"/>

Standardization and traceabilityEdit

Most clinical studies recommend the use of HbA1c assays that are traceable to the DCCT assay.<ref>Template:Cite journal</ref> The National Glycohemoglobin Standardization Program (NGSP) and IFCC have improved assay standardization.<ref name="Sacks" /> For initial diagnosis of diabetes, only HbA1c methods that are NGSP-certified should be used, not point-of-care testing devices.<ref name = "2022 ADA Guidelines">Template:Cite journal</ref> Analytical performance has been a problem with earlier point-of-care devices for HbA1c testing, specifically large standard deviations and negative bias.<ref name="Sacks" />

Veterinary medicineEdit

HbA1c testing has not been found useful in the monitoring during the treatment of cats and dogs with diabetes, and is not generally used; monitoring of fructosamine levels is favoured instead.<ref name="pmid17422317">Template:Cite journal</ref>

See alsoEdit

• Diabetes mellitus
• Hemoglobin A2
• Prediabetes
• Proteopedia: Structure of glycated hemoglobin

NotesEdit

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ReferencesEdit

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External linksEdit

Template:Sister project Template:Scholia

• Health Information: Diabetes — National Institutes of Health (NIH): National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
  • National Diabetes Information Clearinghouse — NIDDK (old site, archived 2010-02-21)
• Standards of Care in Diabetes, American Diabetes Association Professional Practice Committee
  • Standards of Care in Diabetes — 2024 (pdf), American Diabetes Association Professional Practice Committee

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