When is HbA_1c useful and what do the numbers mean – do they help or hinder?

SUSAN E MANLEY,^1,2,3 SAMIUL MOSTAFA,^1,2,4 JONATHAN WEBBER,^1,4 KAVITHA D GANAPATHY,⁵ ROY TAYLOR,⁶ RANDIE R LITTLE,⁷ RAJEEV P RAGHAVAN,⁸ CRAIG WEBSTER,⁹ ALISON BARRATT,¹⁰ RACHEL A ROUND,^1,9 IRENE M STRATTON,^1,11,12 ANDREAS KARWATH,^1,13,14,15 JOHN A WILLIAMS,^{1,14,15,16,17} GEORGIOS V GKOUTOS,^{1,13,14,15,18,19,20,21*} GRAHAM A ROBERTS,^1,22,23,24* SANDIP GHOSH,^1,25* on behalf of the Diabetes Translational Research Group (DTRG), Queen Elizabeth Hospital Birmingham and Birmingham University.

https://doi.org/10.15277/bjd.2023.417

Br J Diabetes 2023;23:105-113

Key words: HbA_1c, inpatient diagnosis, gestational diabetes, remission, red blood cells

Abstract

Background: Glycated haemoglobin (HbA_1c) measurement is used for diagnosis, management and remission of type 2 diabetes (T2DM), with measurements comparable worldwide and the World Health Organization listing medical conditions that affect its accuracy. Admission glucose is in the ‘diabetes’ range in 5% of emergency hospital admissions without prior diagnosis, with literature searches indicating inconsistent practice on using HbA_1c to confirm diagnosis. As oral glucose tolerance tests (OGTT) were not possible during the COVID-19 pandemic, guidance was issued by the Royal College of Obstetrics and Gynaecology on using HbA_1c for gestational diabetes mellitus.

Aims: This study explores use of HbA_1c at Queen Elizabeth Hospital Birmingham, a large university hospital serving a multi- ethnic adult population.

Methods: Information is presented on comparability, clinical audits, research studies and current practice, and is illustrated by case reports.

Results: Data from the National Glycohemoglobin Standardization Program show comparability of laboratoryHbA1c and point-of-care testing methods from 1993 to 2023. Although HbA_1c was used to diagnose gestational diabetes during the COVID-19 pandemic, hospitals have reverted to OGTT post pandemic. In contrast, HbA_1c is now being used to assess T2DM remission. Case reports illustrate these scenarios and highlight the complexity of decision-making when the accuracy of the HbA_1c reading is affected by multiple co- morbidities.

Conclusions: This wider use of HbA_1c includes remission of T2DM but the diagnosis of gestational diabetes has reverted to OGTT post pandemic. A pictorial representation of HbA_1c range is presented to aid understanding of this test. It is suitable for diagnosis of diabetes in most people except those with some variant haemoglobins or abnormal red blood cell turnover.

Introduction

Measurement of glycated haemoglobin (HbA_1c), a surrogate marker of average blood glucose reflects its non-enzymatic binding to haemoglobin over the previous two to three months, the lifespan of red blood cells. HbA_1c is widely used now for the diagnosis,¹ management,² and definition of remission of type 2 diabetes (T2DM).³ It was included in the Diabetes Control and Complications Trial (DCCT),⁴ and the UK Prospective Diabetes Study (UKPDS).⁵ In the 1990s, these randomised controlled clinical trials reported that lower HbA_1c was associated with fewer of the complications caused by type 1 diabetes (T1DM) and T2DM, respectively. Findings from the UKPDS, first presented by Professor Robert Turner in Barcelona, included what is now an iconic graph illustrating the relationship between updated HbA_1c and complications of T2DM (Figure 1). This graph has been cited more than 12,100 times,⁶ and highlighted the need for international standardisation. In 2002, the DCCT defined the relationship between 24-hour snapshot glucose profiles and HbA_1c for T1DM.⁷

Laboratory methods for HbA_1c testing are certified now by the National Glycohemoglobin Standardization Program (NGSP),⁸ that also confirmed UKPDS Bio-Rad HPLC methods as equivalent to the DCCT when the UKPDS results were reported. Comparability of routine HbA_1c measurement has much improved since then due to upgrades in laboratory methods and equipment (Figure 2 [note DCCT units %]). After production of a suitable reference standard for HbA_1c, the International Federation of Clinical Chemistry and Laboratory Medicine (IFCC) reference method was introduced at the manufacturer level for standardisation of all routine methods in 2011. IFCC units (mmol/mol) were adopted for reporting HbA_1c results in the UK and some other countries but DCCT units were retained in the US.⁹ Some point-of-care testing (POCT) devices, advantageous from a wider perspective, are NGSP certified. However, the American Diabetes Association does not recommend using them for diagnosis of T2DM at sites where the required education, training and oversight of performance are not in place.¹ Similarly, constraints apply for this purpose in the UK, with confirmation of a possible POCT diabetes diagnosis required from the laboratory using a venous sample. With laboratory tests, a second HbA_1c test should be requested if the patient is asymptomatic.¹⁰

HbA_1c for diagnosis of T2DM

In 2011, the World Health Organisation (WHO) adopted the recommendation from an expert committee to use HbA_1c for diagnosis of T2DM in the community.¹¹ The HbA_1c workload at Queen Elizabeth Hospital Birmingham (QEHB) laboratory increased markedly, with a consequent reduction in glucose requests.¹² OGTTs are rarely requested now, mainly in circumstances when HbA_1c measurement is precluded or questionable, and when fasting glucose is impaired. Some variant haemoglobins negate actual HbA_1c measurement and other conditions alter red blood cell turnover, affecting its accuracy (Table 1).¹³

Data on OGTT and HbA_1c from the QEHB diabetes clinic have shown >97.5% agreement in sensitivity and specificity between diagnoses on OGTT and HbA_1c when HbA_1c >57 mmol/mol.¹⁴ Therefore, some people can be diagnosed with T2DM by HbA_1c but not OGTT and vice versa, as the tests do not represent the same short- or longer-term glycaemic profiles. Clinicians are advised to accept the diagnosis from either test unless conditions are present that compromise the accuracy of HbA_1c or its suitability, and to use glucose instead (Table 1). More recently, HbA_1c has been suggested for diagnosis of diabetes in hospital patients with blood glucose concentrations in ‘at risk’ or ‘diabetes’ ranges on admission,^1,15 but this strategy has not yet been adopted systematically in the UK.¹⁶

High HbA_1c results

Laboratory alerts for very high (>150 mmol/mol) HbA_1c identified South Asian males in their 20s who had not accessed medical services previously in relation to the disease being diagnosed with diabetes on admission to QEHB. This resulted in a laboratory survey showing approximately one in 200 HbA_1c results were >120 mmol/mol, with 20% possibly new diagnoses of diabetes. In addition to young male South Asians, patients with diabetic ketoacidosis or pancreatitis, and patients on steroids or antipsychotic drugs were identified.^17,18 One of the highest HbA_1c results reported before the pandemic was 203 mmol/mol, equivalent to 30.3 mmol/L when expressed as estimated average glucose (eAG). A result of 234 mmol/mol, or 34.8 mmol/L eAG, has been reported elsewhere in Birmingham.

As very high HbA_1c reflects poor glucose control over the previous few months, it can also be associated with physical symptoms as well as metabolic conditions.¹⁹ Recently, a patient who presented to QEHB with ballistic movements was found to have extremely high HbA_1c, Case 1.²⁰

In general, HbA_1c is measured at 3-monthly intervals but in certain circumstances it can be measured more often after consideration of the half-life of red blood cells. For assessment of changes in glycaemia over time periods shorter than three months, glucose or fructosamine measurement is recommended.

Higher than normal HbA_1c relative to glucose has also been reported for a patient with alpha-1-antitrypsin disorder,²¹ and in patients with certain, but not all, thalassaemias; this inaccuracy may be caused by longer red blood cell half-life.²²

HbA_1c testing on admission to hospital

Admission glucose was in the ‘diabetes’ range in 5% of White European and 8% South Asian emergency admissions without a prior diagnosis of diabetes,²³ (Figure 3) but literature searches show inconsistent practice on the use of HbA_1c for this purpose.¹⁶ Additional testing with HbA_1c in hospital patients can confirm pre-existing T2DM but their medical background should be considered. Multiple medical conditions may be present with various drug regimens involved in the patient’s care, Case 2. Inadequate understanding of HbA_1c can lead to acute presentations of dysglycaemia: clinical assessment and triangulation are key to the management of patients in these circumstances.

Accuracy of HbA_1c

Which tests should be requested to assess glycaemia when a patient is admitted to the hospital, and which factors need to be considered? For most cases of people identified at QEHB with HbA_1c below the reference range (<20 mmol/mol), there was a medical or scientific explanation. They were either on ribavirin,^21,24 or dapsone,^25,26 they had macrocytic red blood cells or haematological disorders, or in a few people malnourishment or end-of-life scenarios. In addition, HbA_1c was depressed by 28 mmol/mol across the range of glucose in an audit of 27 outpatients with cirrhosis pre-transplant but elevated relative to glucose in one outpatient whose cirrhosis was caused by alpha- 1-antitrypsin disorder.²¹ This depression was associated with the presence of macrocytic red blood cells, fewer cells and higher mean cell volume, but not in the patient with alpha-1-antitrypsin related liver disease whose HbA_1c was elevated relative to glucose.

Hypoglycaemia causes acute situations requiring medical attention but there is little relationship between HbA_1c and severe hypoglycaemia in modern practice. However, in the presence of some thalassaemias and other red cell disorders, HbA_1c may be higher than normal relative to glucose, causing severe hypoglycaemia when inaccurate HbA_1c results are used for management of blood glucose.²⁷ This issue was illustrated in a case presented at the Diabetes UK professional conference in 2023, when an additional hypoglycaemic agent was added but the HbA_1c was artificially high due to β-thalassaemia undetected by the HbA_1c high performance liquid chromatography method.²⁸ Glucose testing is required to assess these situations. Case 3 from another hospital in the West Midlands also illustrates this problem and highlights the need for electronic systems for flagging, taking background information into account and consistent communication between those providing medical care.

No difference was found between the relationship of HbA_1c and fructosamine in a small study of heterozygous patients with AD or AS haemoglobins but there is wide scatter around the linear regression lines.²⁹ Any drugs, including anti-retrovirals, which reduce erythrocyte lifespan can potentially lower HbA_1c by increasing the proportion of younger cells in the blood, and these have less exposure of haemoglobin to glucose than normal red blood cells. Laboratory glucose estimation is the only option for the diagnosis of T2DM in these circumstances,³⁰ as fructosamine representing glycated plasma proteins is not validated for this purpose.

Ethnicity can also influence how HbA_1c relates to glucose. In Birmingham, HbA_1c levels were 10% higher relative to admission glucose levels in South Asians and Afro-Caribbeans than in White Europeans.³¹ This may reflect haematological differences affecting red blood cell lifespan. Questions have been raised as to whether HbA_1c cut-offs for diagnostic purposes should be determined by ethnicity.^32,33

HbA_1c during the COVID-19 pandemic

Hyperglycaemia causes excess morbidity and mortality in hospital patients with COVID-19.³⁴ Unusual manifestations of ketoacidosis with very high HbA_1c have been reported for people admitted with COVID-19.^28,35 The virus particularly affects people with additional medical problems, and those who present for inpatient treatment of the viral illness may not be representative of all the people with diabetes who become infected. There is insufficient evidence/research to establish whether the virus directly affects the glycation of haemoglobin.

HbA_1c in pregnancy and gestational diabetes

Before the emergence of COVID-19, routine HbA_1c testing was not advised during pregnancy for diagnostic purposes or glucose control,³⁶ as HbA_1c falls to a modest extent in normal pregnancy due to decreased fasting blood glucose and reduced erythrocyte lifespan.³⁷ HbA_1c will most likely only be raised in the first half of pregnancy in those with pre-existing diabetes because in gestational diabetes mellitus (GDM) glucose levels start to rise in the second half of pregnancy, Case 4.

Adjustment of glycaemic regimens has relied primarily on home blood glucose monitoring although longer-term measurement of HbA_1c is valuable for some individuals.^38,39 Recently, continuous blood glucose monitoring has been introduced as data relating pregnancy outcome to measures such as time in range become available for various glycaemic situations.^40,41

GDM, defined as glucose intolerance identified for the first time during a pregnancy, is associated with adverse outcomes such as shoulder dystocia, birth injury, increased caesarean section rate and neonatal hypoglycaemia, with a much- increased risk of subsequent T2DM. Pre-COVID NICE guidelines for screening specify a 75g OGTT at 24 to 28 weeks’ gestation for high-risk women (BMI ≥30 kg/m2 at booking, ethnicity with high prevalence or first-degree relative with T2DM), with cut-offs for fasting glucose ≥5.6 mmol/L and 2-hour glucose ≥7.8 mmol/L.36 However, as this strategy entails large numbers of OGTTs, it was not feasible to perform them in many areas of England during the pandemic.

Temporary guidance on the diagnosis of GDM unsupported by research or guidelines was issued in 2020 by the Royal College of Obstetrics and Gynaecology (RCOG) for logistic reasons and was widely adopted.⁴² The guidance advised screening at the booking visit for pre-existing T2DM with HbA_1c, i.e. when HbA_1c ≥48 mmol/mol or random plasma glucose ≥11.1mmol/L, with the provision of appropriate treatment. An HbA_1c result between 41 and 47 mmol/mol or random plasma glucose 9 to 11 mmol/L indicated possible GDM. Repeat tests were required at 24 to 28 weeks’ gestation in high-risk women whose earlier results were normal. If the resulting HbA_1c was ≥39mmol/mol, fasting plasma glucose ≥5.6 mmol/L or random plasma glucose ≥9 mmol/L, they should be also treated for GDM, Case 5.

It was not known whether these temporary RCOG guidelines would alter the prevalence of GDM or change the outcomes. A recent paper based on screening for GDM in one Dublin hospital for three months in 2019 and the same period in 2020 reported a decreased prevalence and concluded that OGTT should be maintained as the gold-standard test where possible.⁴³ It has been debated whether the population identified would differ from those identified using OGTT but no significant differences in clinical outcomes were observed in this small study. There was increased use of medication (metformin and insulin) for those diagnosed with GDM using HbA_1c, the assumption being that they had higher glucose levels than those identified by OGTT.

Although HbA_1c measurement was useful during the pandemic, clinicians have reverted to OGTT for GDM screening due to a significant fall in diagnoses using HbA_1c ≥39 mmol/ mol.⁴⁴ But HbA_1c testing was advantageous at booking to diagnose T2DM earlier. There is a strong case for screening with HbA_1c on booking for high-risk women given the increasing prevalence of T2DM in the background population in Birmingham and elsewhere in the UK. At present, many of these women would only have been identified as having diabetes when presenting with highly abnormal OGTT results at 24 to 28 weeks’ gestation.

HbA_1c in remission of T2DM

Remission of T2DM can occur if people achieve substantial weight loss when placed on a very low-calorie diet, and oral anti-diabetic medication such as metformin and gliclazide can be withdrawn safely.⁴⁵ HbA_1c measurement is included in protocols introduced for this purpose in the UK in 2016,⁴⁶ and in a 2019 UK consensus report.^47,48 They define remission as lowering HbA_1c to below the diagnostic level for diabetes (<48 mmol/mol) and off all hypoglycaemic drugs for a minimum of six months. An international consensus confirmed this practice in 2021,³ Case 6.

The average weight loss over eight weeks in the Counterpoint study (n=11) was 15.3(1.2) kg, mean (SE), with 15% of initial body weight lost overall.⁴⁹ This amounted to 3.9(0.2) kg over the first week, 5.7(0.6) kg for weeks 1 to 4 and 5.7(0.7) kg for weeks 4 to 8. Fasting plasma glucose decreased in the first week from 9.2(0.4) mmol/L to 5.9(0.4) mmol/L, p=0.003, (not different from the control group without diabetes, 5.3(0.1) mmol/L, p=0.18) and remained stable for the next eight weeks at 5.7(0.5) mmol/L. Correspondingly, HbA_1c dropped from 57±3 mmol/mol to 55±3 mmol/mol, p=<0.001, after the first week, was 47±3 mmol/mol, p=<0.001, by week 4 and 42±2 mmol/mol, p=<0.001, by week 8. HbA_1c data are also available for patients in the DiRECT study at 12 months but not at 6 months.⁵⁰ Weight loss of 15 kg or more was reported for 24% of participants in the intervention group, remission was achieved in 46% and HbA_1c was <48 mmol/mol in 49% of participants. Remission of T2DM is more likely in people diagnosed for less than six years, although remission remains possible but less likely for many years following diagnosis of T2DM. In any situation, the degree of weight loss is the absolute determinant.⁵⁰

Conclusions

Appropriate interpretation of results for HbA_1c is essential as a diagnosis of diabetes is life-changing and given that results are used to adjust potentially life-threatening medication and make other clinical decisions. The clinical cases presented here highlight the complexity of decision-making, with additional clinical information and laboratory data required for patients with multiple co-morbidities or on certain drugs or with variant haemoglobins that affect red blood cell turnover.⁵¹ A paper from 2020 involving randomly selected adults from the National Health and Nutrition Examination Survey (NHANES) has also highlighted the lack of concordance of HbA_1c and OGTT glucose for diagnosis of T2DM when HbA_1c <57 mmol/mol,⁵² as demonstrated in Birmingham.¹⁴ Although laboratory HbA_1c results are available on primary and secondary care information systems, no prompts to exercise caution when interpreting them or requesting tests are available when details of medical conditions/drugs that affect their accuracy are recorded there. Systems management with timely decision prompts could link pertinent clinical and laboratory information so that patients can be managed safely in non-diabetes specialist areas of healthcare. Previous haematology reports of abnormal haemoglobin or red blood cell count and morphology could be flagged on electronic patient records to alert requesters when HbA_1c is not accurate. There is an urgent need for more effective, personalised health care given the risks associated with hyperglycaemia/ hypoglycaemia and undiagnosed T2DM, poorer outcomes with COVID-19 in people with diabetes or metabolic syndrome, and advantages of remission. Recent initiatives in digital medicine support these objectives and when introduced will overcome the various hurdles now apparent.^53-55

Currently, HbA_1c is used routinely for diagnosis of diabetes in the community in the UK and is advised for hospital ad- missions with hyperglycaemia but not widely implemented.^16,56,57 HbA_1c measurement was introduced in pregnancy for diagnosis of GDM during the COVID-19 pandemic. This usage has reverted to OGTT post-pandemic, but HbA_1c screening of high-risk patients in the first trimester should be considered. International guidelines published in 2021 specify that HbA_1c testing is required to confirm remission of T2DM.³

There is increasing public awareness in recent years regarding HbA_1c use in diagnosis of T2DM and pre-diabetes, and availability of POCT A1c testing, given routine screening in the over-40 age group and the introduction of the National Diabetes Prevention Program.⁵⁸ Information on the definition of HbA_1c as an indication of blood glucose over the previous 2 to 3 months and its overall range is presented in a pictorial format in Figure 4. Careful evaluation of HbA_1c results is even more necessary now that the test features in so many on-going diabetes prevention programmes and strategies for facilitating the remission of T2DM. In routine clinical practice at tertiary centres such as QEHB, clinicians come across a wide variety of conditions that underline the unsuitability of HbA_1c on its own as a surrogate glycaemic marker. Whilst no laboratory test is ideal for everyone, HbA_1c is only inappropriate in a very small proportion of the population and it is widely applicable. We hope this review will help to update decision-makers on the wider use of HbA_1c as a surrogate marker of blood glucose, and its pitfalls.

Conflict of interest
SEM, SM, JW, KDG, RRL, CW, AB, RAR, IMS, AK, GVG, GAR and SG have no conflicts of interest to declare in relation to this paper. RT has received lecture fees from Lilly, Janssen and Novartis and is author of the book ‘Life Without Diabetes’. RPR has received consultation and/or lecture fees or unrestricted travel grants from Novo Nordisk, Eli Lilly, Boehringer Ingelheim, AstraZeneca, Takeda, NAPP and Abbott Diabetes. JAW is an employee of Eisai Inc. Eisai Inc had no role in study design or funding.

Funding
The DTRG acknowledges support from the GA Roberts Research Fund and University Hospitals Birmingham Charity. AK acknowledges support from the UK Medical Research Council (MRC grant MR/S003991/1; GVG acknowledges support from the NIHR Birmingham ECMC, NIHR Birmingham SRMRC, Nanocommons H2020- EU (731032), MAESTRIA (Grant agreement ID 965286), HYPERMARKER
(Grant agreement ID 101095480), PARC (Grant Agreement No 101057014) and the MRC Heath Data Research UK (HDRUK/CFC/01), an initiative funded by UK Research and Innovation, Department of Health and Social Care (England) and the devolved administrations, and leading medical research charities. The funding organisations had no role in the design of this study, data collection, analysis or interpretation, or preparation of the manuscript, and did not approve or disapprove of, or delay, publication of the work.

Acknowledgements
Drs Susan Manley and Andreas Karwath attended the Clinical Advisory Committee Meeting of the National Glycohemoglobin Standardization Program in New Orleans in 2023, as did Dr Sandip Ghosh in 2018.
Dr Susan Manley is a member of the Joint British Diabetes Societies Inpatient Committee and the National Advisory Panel for Care Home Diabetes.
Dr Jonathan Webber is a Consultant Diabetologist based in Birmingham. Dr Kavitha Ganapathy is a specialty registrar in Diabetes and Endocrine, West Midlands.
Professor Roy Taylor is Emeritus Professor of Medicine and Metabolism, previous Honorary Consultant Physician to Newcastle Hospitals NHS Foundation Trust, with special interest in adult diabetes and pregnancy diabetes. He was a member of the International Consensus Group on Remission of Type 2 Diabetes.
Dr Randie Little is a Research Professor at the University of Missouri School of Medicine and is the network coordinator for the National Glycated Hemoglobin Standardization Program (NGSP).
Craig Webster is a consultant clinical scientist at University Hospitals Birmingham NHS Foundation Trust.
Alison Barratt is a freelance graphic designer, illustrator and lecturer. Irene Stratton is a member of the Diabetes UK
Acute Care Study Group. Professor Georgios Gkoutos is the director of the Health Data Science Centre, associate Director of Health Data Research UK Midlands and member of the Diabetes UK Acute Care Study Group.
Dr Sandip Ghosh is a consultant endocrinologist in the UAE, founder member of DTRG, University Hospitals Birmingham and has attended Joint British Diabetes Societies inpatient meetings.
The authors are grateful for support and encouragement from Janet Smith, previously head of Clinical Biochemistry, University Hospitals Birmingham NHS Foundation Trust, and the laboratory for the Birmingham UKPDS centre.

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