The use of A1C for the identification of persons with undiagnosed diabetes has been
investigated for a number of years (1
–3). A1C better reflects long-term glycemic exposure than current diagnostic tests
based on point-in-time measures of fasting and postload blood glucose (4,5) and has
improved test-retest reliability (6). In addition, A1C includes no requirement for
fasting or for the oral glucose tolerance test's 2-h wait. These advantages should
lead to increased identification and more timely treatment of persons with diabetes.
Recently, an American Diabetes Association (ADA)-organized international expert committee
recommended the adoption of the A1C assay for the diagnosis of diabetes at a cut point
of 6.5% (7). This cut point was primarily derived from a review of studies that examined
the association of A1C values with incident retinopathy, and some of the most influential
data were obtained from recently published prospective studies. Retinopathy was chosen
as the ultimate criterion because it is among the main complications of diabetes.
Identification of the point on the A1C distribution most closely related to future
retinopathy will identify persons in the greatest need of interventions for the prevention
of diabetes complications.
In addition to utility and convenience, A1C could help identify persons at increased
risk of developing diabetes. This is an important public health priority since a structured
lifestyle program or the drug metformin can reduce the incidence of diabetes by at
least 50 and 30%, respectively (8). Ideally, selection of diagnostic cut points for
pre-diabetes would be based on evidence that intervention, when applied to the high-risk
group of interest, results not only in the prevention of diabetes but also later complications.
However, currently there are no trials that can provide data to determine the ideal
method for defining cut points. In the absence of such data, expert committees had
to rely on information about the shape of risk curves for complications such as retinopathy.
Previous expert committees assembled to address this issue have noted that there is
no clear difference in retinopathy risk between different levels of impaired glucose
tolerance (7). We are unaware of published prospective studies of adequate sample
size or duration that have followed people in various pre-diabetic categories across
the full span of time until complications developed. In the absence of informative
trials (as well as prospective studies), the studies that measure A1C at baseline
and incident diabetes may provide the definitions of high-risk states.
To better define A1C ranges that might identify persons who would benefit from interventions
to prevent or delay type 2 diabetes, we carried out a systematic review of published
prospective studies that have examined the relationship of A1C to future diabetes
incidence.
RESEARCH DESIGN AND METHODS
Data sources
We developed a systematic review protocol using the Cochrane Collaboration's methods
(9). We formulated search strategies using an iterative process that involved medical
subject headings and key search terms including hemoglobin A, glycated, predictive
value of tests, prospective studies, and related terms (available from the authors
on request). We searched the following databases between database establishment and
August 2009: MEDLINE, Embase, the Cumulative Index to Nursing and Allied Health Literature
(CINAHL), Web of Science (WOS), and The Cochrane Library.
Systematic searches were performed for relevant reviews of A1C as a predictor of incident
diabetes. Reference lists of all the included studies and relevant reviews were examined
for additional citations. We attempted to contact authors of original studies if their
data were unclear or missing.
Study selection and data abstraction
We searched for published, English language, prospective cohort studies that used
A1C to predict the progression to diabetes among those aged ≥18 years. We included
studies with any design that measured A1C—whether using a cutoff point or categories—and
incident diabetes. Titles and abstracts were screened for studies that potentially
met inclusion criteria, and relevant full text articles were retrieved. X.Z. and W.T.
reviewed each article for inclusion and abstracted, reviewed, and verified the data
using a standardized abstraction template. If A1C measurement was standardized by
the National Glycohemoglobin Standardization Program (NGSP) and both standardized
and unstandardized A1C values were reported, standardized values were used in the
analyses. A sensitivity analysis, however, was conducted using both standardized and
unstandardized A1C values. Relative measures of diabetes incidence including relative
risk, odds ratio, hazard ratio, likelihood ratio, and incidence ratio were examined
and cumulative incidences were converted to annual incidences (10). In studies reporting
no measure of relative incidence, the incidence ratio was estimated as the absolute
incidence in each A1C category divided by the incidence in the lowest A1C category.
Data analysis and synthesis
To summarize the relationship between A1C level and diabetes incidence over these
studies, we modeled A1C as a function of annualized diabetes incidence using the aggregate
study-level data. A1C was treated as an interval censored dependent variable, incidence
as an independent variable, and study as an independent factor. Studies that stratified
results by sex were treated as two separate studies. A1C, rather than diabetes incidence,
was treated as the dependent variable because we were unaware of any method that supported
interval censored independent variables; in many studies, A1C was categorized and
thus was intrinsically censored. We used a Weibull distribution, which fit the data
better than a normal or lognormal distribution (results not shown). Because we did
not know the relationship's correct functional form, we fit a model with non-negative
fractional polynomial terms, which can approximate many functional forms. We reported
the relationship that was the mean over all studies and calculated pointwise 95% confidence
limits for the curve. A sensitivity analysis to assess the lab-to-lab variation in
A1C measurements was conducted and, to determine if any individual study substantially
influenced our results, we refitted the curve, omitting data from each study one study
at a time. Modeling was conducted using SAS (version 9.1.3; SAS Institute, Cary, NC)
PROC LIFEREG.
RESULTS
Description of study participants
In total, 16 studies (11
–26) fulfilled our inclusion criteria (Fig. 1). The reviewed studies included 44,203
total participants (range 27 to 26,563) and the follow-up interval averaged 5.6 years
(range 2.8 to 12 years) (Table 1). Overall, the mean age among 15 studies reporting
baseline age was 53.4 years (SD 7.2) (11
–24,26). One study population was exclusively female (22) and another was exclusively
male (24); other study populations were mixed and contained 69.0% female, on average.
Mean baseline A1C and fasting plasma glucose among the studies were 5.2% (range 4.4
to 6.2%) and 5.4 mmol/l (range 5.1 to 5.7 mmol/l), respectively (11,14
–16,19,21,24).
Figure 1
Study flow chart.
Table 1
Characteristics of study participants
Citation
Sample size
Length of F/U (years)
Age at baseline (years) (means ± SD)
Sex (% female)
Race/ethnicity
Baseline A1C (%) (means ± SD)
Baseline FPG (mmol/l) (means ± SD)
Definition of incident diabetes
Inclusion criteria and sampling method
Droumaguet 2006
2,820
6
47.3 (9.9)
51.0
French
5.4 (0.4)
5.4 (0.5)
FPG ≥ 7.0 mmol/l, or treatment by oral agents or insulin
Volunteers identified as nondiabetes or FPG < 7.0 mmol/l at baseline; persons with
self-reported diabetes and FPG ≥ 7.0 mmol/l were excluded
Edelman 2004
1,253
3
55.0 (6.0)
6.0
69% white
5.6 (0.7)
NR
FPG ≥ 7.0 mmol/l or A1C ≥ 7.0% or self-report
A convenience sample of patients without diabetes who visited clinics; patients with
A1C ≥ 7.0% or FPG ≥ 7.0 mmol/l were excluded
29% black
2% other
Hamilton 2007
27
6
60.2 (14.7)
59.3
NR
5.6 (0.5)
NR
NR
All patients undergoing elective pancreatic surgery with A1C data and without diabetes
Inoue 2007
449
7
45.6 (6.6)
23.8
Japanese
5.2 (0.5)
5.1 (0.5)
FPG ≥ 7.0 mmol/l, or treatment by oral agents or insulin
All employees who participated in annual health screening; persons with self-reported
diabetes or FPG ≥ 7.0 mmol/l were excluded
Ko 2000
208
7
35.0 (7.7)
87.5
Chinese
5.8 (0.8)
5.4 (0.7)
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.0 mmol/l
Randomly recruited from the patients without diabetes; patients with FPG ≥ 7.0 mmol/l
were excluded
Kolberg 2009
632
5
49.9 (1.7)
38.4
Danes
6.0 (0.1)
5.7 (0.2)
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.0 mmol/l
Persons in an “at-risk” subpopulation of randomized sample aged ≥ 39 years, with BMI
≥ 25 and without diabetes; persons with FPG ≥ 7.0 mmol/l were excluded
Lee 2002
504
4
56.0 (NR)
67.3
American Indians
Women:
Women:
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.0 mmol/l
Indians who participated in the Strong Heart Study without diabetes at baseline; persons
with 2-h PG ≥ 11.1 mmol/l in an OGTT were excluded
120: <5.1
193: <5.3
98: 5.1–5.4
199: 5.3–5.7
121: ≥5.5
193: ≥5.8
Men:
Men:
59: <5.2
185: <5.4
50: 5.2–5.5
183: 5.4–5.8
56: ≥5.6
179: ≥5.9
Little 1994
257
6.1
46.7 (12.0)
66.9
Pima Indians
60%:<6.03% 40%:≥6.03%
NR
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.8 mmol/l
Residents who participated in a longitudinal epidemiological study; persons with 2-h
PG ≥ 11.1 mmol/l in an OGTT or used insulin or oral agents were excluded
Narayan 1996
1,108
5
35.3 (9.8)
63.1
Pima Indians
6.2 (0.6)
5.4 (0.6)
2-h PG ≥ 11.1 mmol/l in an OGTT
All residents aged 25–64 years without diabetes; persons with 2-h PG ≥ 11.1 mmol/l
in an OGTT were excluded
Hijpels 1996
158
3
64.2 (2.5)
55.9
Caucasian
Median (25th–75th per.) 5.5 (5.2–5.9) no-converters 5.7 (5.3–6.0) converters
Median (25th–75th per.) 5.9 (5.6–6.4) no-converters 6.1 (5.6–6.6) converters
2-h PG ≥ 11.1 mmol/l in an OGTT
Persons with IGT randomly selected from the registry of Hoorn; persons with 2-h PG
≥ 11.1 mmol/l in an OGTT were excluded
Norberg 2006
468
12
51.7 (7.6)
40.4
Sweden
4.4 (0.3)
5.5 (0.7)
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.8 mmol/l
Community population in the county of Vaesterbotten who participated in an intervention
program; persons with 2-h PG ≥ 11.1 mmol/l in an OGTT were excluded
Pradhan 2007
26,563
10.8
54.6 (7.1)
100.0
NR
5.0 (0.4)
NR
Self-report
Randomized female health professional aged ≥ 45 years without diabetes and missing
baseline BMI; persons with self-reported diabetes were excluded
Preiss 2,009
1,620
2.8
66.0 (12.0)
32.7
NR
6.2 (0.7)
NR
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.8 mmol/l
Participants in CHARM without diabetes; persons with 2-h PG ≥ 11.1 mmol/l in an OGTT
or FPG ≥ 7.0 mmol/l were excluded
Sato 2009
6,804
4
47.7 (4.2)
0
Japanese
5.2 (0.4)
5.4 (0.5)
FPG ≥ 7.0 mmol/l or treatment by oral agents
Participants aged 40–55 years with FPG < 7.0 mmol/l who did not take an oral agent
or insulin; persons with FPG ≥ 7.0 mmol/l were excluded
Shimazaki 2007
513
3
Middle-aged
52.4
Japanese
NR
NR
2-h PG ≥ 11.1 mmol/l in an OGTT or FPG ≥ 7.8 mmol/l
Patients selected from the hospital information system; patients with 2-h PG ≥ 11.1
mmol/l in an OGTT or FPG ≥ 7.0 mmol/l were excluded
Yoshinaga 1996
819
5
52.3 (6.2)
15.9
Japanese
NR
NR
2-h PG ≥ 11.1 mmol/l in an OGTT or FBG ≥ 6.7 mmol/l
Government officials and their spouses with A1C ≥ 6.2%, FBG ≥ 100 mg/dl, and positive
urine sugar; persons with self-reported diabetes and FPG ≥ 7.0 mmol/l were excluded
Mean/Total
44,203
5.6
53.4 (7.2)
69.0
5.2 (0.4)
5.4 (0.5)
Range
27–26,563
2.8–12
35.0–66.0
0–100
4.4–6.2
5.1–5.7
CHARM, the Candesartan in Heart Failure-Assessment of Reduction in Mortality and Morbidity;
FBG, fasting blood glucose; F/U, follow-up; FPG, fasting plasma glucose; IGT, impaired
glucose tolerance; NR, not reported; OGTT, oral glucose tolerant test; per., percentile;
2-h PG, 2-h plasma glucose.
Ten studies (11,12,14,18,20,21,23
–26) reported that A1C was measured by high-performance liquid chromatography, three
(15,19,22) used other methods, and three (13,16,17) did not provide information about
A1C measurement. A1C values in three studies (11,24,25) were standardized by the NGSP,
one (22) by the International Federation of Clinical Chemists, and another (21) by
the Swedish MonoS Standard. The A1C values standardized by the Swedish MonoS Standard
were very low and covered a very narrow range (4.5 to 4.7%) and we did not use data
from this study for statistical modeling.
Incidence of diabetes associated with A1C levels
Among the eight studies that reported A1C categories (11,12,17,21,22,24
–26) (Table 2), the range of A1C from 4.5 to 7.1% was associated with diabetes incidences
ranging from 0.1% per year to 54.1% per year. In general, studies that categorized
A1C across a full range of A1C values (11,12,17,22,24
–26) showed that 1) risk of incident diabetes increased steeply across the A1C range
of 5.0 to 6.5%; 2) both the relative and absolute incidence of diabetes varied considerably
across studies; 3) the A1C range of 6.0 to 6.5% was associated with a highly increased
risk of incident diabetes, frequently 20 or more times the incidence of A1C <5.0%);
4) the A1C range of 5.5 to 6.0% was associated with a substantially increased relative
risk (frequently five times the incidence of A1C <5.0%); and 5) the A1C range of 5.0
to 5.5% was associated with an increased incidence relative to those with A1C <5%
(about two times the incidence of A1C <5.0%).
Table 2
A1C levels and incidence of diabetes
Citation
A1C cut-off point (or category, or percentiles) %
Incidence (95% CI) %
Annualized incidence (95% CI) %
A1C category (or unit of increase in A1C) %
Relative risk (95% CI) (or OR, HR, LR, IR)
Notes
Droumaguet 2006
(From Figure 1
A)
After stratifying on FPG, A1C predicted diabetes only in subjects with IFG (FPG ≥
6.1 mmol/l). The OR for a 1% increase in A1C was 7.2 (95% CI, 3.0–17.0). A1C categories
were incorrect on page 1,622. The correct ones are 4.5–5.0, 5.1–5.5, 5.6–6.0, and
6.1–6.5 (confirmed by authors)
Women:
6-year cumulative
Women:
5.3–5.7
0.4
0.1
5.8
5.0
0.9
5.8–7.1
11.0
1.9
<4.5
OR (95% CI), ref.
Men:
6-year cumulative
Men:
4.5–5.0
0.9 (0.5–1.5)
5.3–5.7
2.6
0.4
5.1–5.5
1.5 (0.7–3.4)
5.8
5.0
0.9
5.6–6.0
5.0 (2.0–12.8)
5.8–7.1
11.5
2.0
6.1–6.5
32.7 (11.5–92.6)
Edelman 2004
≤5.5
Annual, 0.8 (0.4–1.2)
0.8 (0.4–1.2)
Obese patients with A1C 5.6 to 6.0 had an annual incidence of diabetes of 4.1% (95%
CI, 2.2–6.0%)
5.5–6
Annual, 2.5 (1.6–3.5)
2.5 (1.6–3.5)
6.1–6.9
Annual, 7.8 (5.2–10.4)
7.8 (5.2–10.4)
(From Figure 2)
(From Figure 2)
(From Figure 2)
IR*
5.1–5.5
0.9 (SEM, 0.5)
0.9 (SEM, 0.5)
1.0
5.6–6.0
2.5 (1.0)
2.5 (1.0)
2.8
6.1–6.5
6.4 (2.5)
6.4 (2.5)
7.1
6.6–6.9
18.0 (12.0)
18.0 (12.0)
NR
20.0
Hamilton 2007
Baseline mean A1C for those with incident diabetes is 6.3 (0.7), and for nondiabetes
is 5.2 (0.4)
6-year cumulative
5.6 in baseline
37.0
6.2
NR
NR
Inoue 2007
<5.8 with high NFG
Annual, 0.9
0.9
FPG and A1C predicts incidence of diabetes, especially for those with FPG ≥ 5.55 mmol/l
≥5.8 with high NFG
Annual, 3.3
3.3
<5.8 with IFG
Annual, 2.5
2.5
0.5% increase in A1C
OR (95%CI)
≥5.8 with IFG
Annual, 9.5
9.5
3.0 (1.7–5.3)
Ko 2000
LR
The calculation of annual incidence diabetes for category of A1C < 6.1 with FPG >
6.1 mmol/l is incorrect (44.1). The correct one is 54.1 (confirmed by authors)
<6.1 with FPG <6.1
Annual, 8.1
8.1
<6.1 with FPG <6.1
0.6
≥6.1 with FPG <6.1
Annual, 13.7
13.7
≥6.1 with FPG <6.1
0.9
<6.1 with FPG ≥6.1
Annual, 17.4
17.4
<6.1 with FPG ≥6.1
1.1
≥6.1 with FPG ≥6.1
Annual, 54.1
54.1
≥6.1 with FPG ≥6.1
9.3
Kolberg 2009
5-year cumulative
Baseline mean A1C for those with incident diabetes is 6.1 (0.1), and for nondiabetes
is 5.9 (0.1). No-converters were randomly selected in a 3:1 ratio to converters. We
calculated incidence of diabetes using data from whole sample
6.0 in baseline
5.7
1.2
NR
NR
Lee 2002
Women:
4-year cumulative
Women:
Women:
IR
The overall 4-year incidence rate was 19.7% among 1,664 participants without diabetes
in baseline, and average annual Incidence rate 4.9%
120: <5.1
27.4
6.9
120: <5.1
1.0
98: 5.1–5.4
34.7
8.7
98: 5.1–5.4
1.3
121: ≥5.5
47.9
12.0
121: ≥5.5
1.7
Men:
4-year cumulative
Men:
Men:
IR
59: <5.2
30.5
7.6
59: <5.2
1.0
50: 5.2–5.5
32.0
8.0
50: 5.2–5.5
1.0
56: ≥5.6
51.8
13.0
56: ≥5.6
1.7
Little 1994
3.3-year cumulative
A1C was classified as either normal or elevated based on whether it was below or above
the upper limit of the A1C normal range (6.03%)
≤6.03 with NGT
9.7
2.9
>6.03 with NGT
11.1
3.4
≤6.03 with IGT
27.7
8.4
1.0% difference in A1C
OR (95% CI)
>6.03 with IGT
68.4
20.7
6.8 (1.8–25.8)
Narayan 1996
25th percentiles, 5.7
5-year cumulative
25th percentiles, 5.7
HR (95% CI)
The diabetes hazard rate ratio (95% CI) is 1.8 (1.5–2.1) as predicted by A1C percentiles
of 25th and 75th.
75th percentiles, 6.7
13.5
1.6
75th percentiles, 6.7
1.8 (1.5–2.1)
Median (25th–75th percentiles)
Median (25th–75th percentiles)
5.5 (5.2–5.9) for
5.5 (5.2–5.9) for
no-converters
no-converters
Nijpels 1996
5.7 (5.3–6.0) for
3-year cumulative
5.7 (5.3–6.0) for
NR
The incidence density of diabetes was 13.8% per year (95% CI, 3.5–24.0). At baseline,
12% (n = 19) of subjects had A1C > 6.1% of whom 52.6% progressed to diabetes
converters
28.5 (15.0–42.0)
9.5
converters
Norberg 2006
Mean time of 5.4+/−8.4 year cumulative
The combination of A1C, FPG, and BMI are effective for predicting risk of diabetes
Women
Women
Women
<4.5
18.1
3.4
OR for women, ref.
4.5–4.69
35.9
6.6
<4.5
≥4.7
64.3
11.9
4.5–4.69
2.0 (0.5–8.9)
Men
Men
Men
≥4.7
19.6 (2.5–152.4)
<4.5
15.3
2.8
<4.5
OR for men, ref.
4.5–4.69
44.4
8.2
4.5–4.69
1.2 (0.3–5.3)
≥4.7
73.2
13.6
≥4.7
16.0 (2.2–115.3)
Pradhan 2007
<5.0
Annual, 0.1
0.1
<5.0
RR (95%CI), ref.
For diabetes, an increase in risk was noted in each category above 5.0% in both age-adjusted
and multivariable models and after exclusion of cases diagnosed with 2 years or even
5 years of follow-up
5.0–5.4
Annual, 0.5
0.5
5.0–5.4
4.1 (3.5–4.9)
5.5–5.9
Annual, 3.2
3.2
5.5–5.9
25.6 (21.1–30.8)
6.0–6.4
Annual, 9.1
9.1
6.0–6.4
76.7 (59.4–99.1)
6.5–6.9
Annual, 9.3
9.3
6.5–6.9
77.6 (51.4–117.4)
≥7.0
Annual, 22.7
22.7
≥7.0
201.4 (149.7–271.1)
Preiss 2,009
2.8-year cumulative
A1% increase in A1C
OR (95%)
Baseline mean A1C for those with incident diabetes is 6.8 (0.9), and for nondiabetes
is 6.2 (0.7)
6.2 (0.7) in baseline
7.8
2.8
2.3 (1.9–2.8)
Sato 2009
4-year cumulative
Even after stratifying participants by FPG (≤ 99 or ≥ 100 mg/dl), elevated A1C had
an increased risk of type 2 diabetes
≤5.3
3.0
0.7
≤5.3
OR (95%), ref.
5.4–5.7
6.5
1.6
5.4–5.7
2.3 (1.7–3.0)
5.8–6.2
20.6
5.1
5.8–6.2
8.5 (6.4–11.3)
6.3–6.7
41.9
10.5
6.3–6.7
23.6 (16.3–34.1)
≥6.8
69.1
17.3
≥6.8
73.3 (41.3–129.8)
Shimazaki 2007
3-year cumulative
Total sample size is 38,628 with age range from 15 year above. Tables 3 and 4 reported
a subgroup of middle-aged data
<5.6
0.2 (0.1–0.3)
0.1
5.6–6.4
7.5 (3.6–15.7)
2.5
5.6–6.4
HR (95% CI), ref.
≥6.5
30.8 (21.7–43.8)
10.3
≥6.5
7.1 (4.6–10.9)
Yoshinaga 1996
5-year cumulative
IR*
The combination of A1C and OGTT enables more precise prediction of progression to
diabetes in those with glucose intolerance
≤6.3
5.4
1.1
≤6.3
1.0
6.4–6.7
20.3
4.1
6.4–6.7
3.7
≥6.8
52.1
10.4
≥6.8
9.5
*Incidence ratio (IR) was computed by the incidence in each A1C category divided by
the incidence of the lowest A1C category. FPG, fasting plasma glucose; HR, hazard
ratio; IFG, impaired fasting glucose; IGT, impaired glucose tolerance; IR, incident
ratio; LR, likelihood ratio; NFG, normal fasting glucose; NGT, normal glucose tolerance;
NR, nor reported; OGTT, oral glucose tolerance test; OR, odds ratio; ref., reference;
RR, relative risk.
Using data from these seven studies (11,12,17,22,24
–26), we modeled A1C as a function of diabetes incidence (Fig. 2). The curve demonstrated
that A1C was positively associated with the incidence of diabetes with a change-in-slope
occurring at an A1C level of about 5.5%. In other words, when diabetes incidence increased
0.3 to 1.8%, the A1C increased from 5.0 to 5.5%, or on average about a 0.33 percentage
point increase in A1C per 1.0 percentage point increase in incidence. When diabetes
incidence increased from 1.8 to 5.0%, the A1C increased from 5.5 to 6.0%, or about
a 0.16 percentage point increase in A1C per 1.0 percentage point increase in incidence.
Furthermore, when diabetes incidence increased from 5.0 to 9.5%, the A1C increased
from 6.0 to 6.5%, or about a 0.11 percentage point increase in A1C per 1.0 percentage
point increase in incidence. These associations convert to a 5-year incidence of <5
to 9% across A1C of 5.0 to 5.5%, 9 to 25% across the A1C range of 5.5 to 6.0%, and
25 to 50% across the A1C range of 6.0 to 6.5%. We noted that in one very large study
(22) that used Kaplan-Meier curves to depict the relationship between time before
developing diabetes and baseline A1C values, the curves appeared to diverge between
A1C values of 5.0 to 5.4% and 5.5 to 5.9%.
Figure 2
A1C modeled as a function of annualized incidence. The dashed lines are pointwise
95% confidence limits for the fitted curve.
Our sensitivity analyses showed that the omission of studies other than the Edelman
study created little change in the curve. Omission of the Edelman study resulted in
a biologically implausible curve. However, in the range of A1C/incidence discussed
here, the difference between the curves with/without the Edelman study was small.
Thus, while the Edelman study was highly influential in overall curve fitting, its
impact on our study's conclusions was minor.
In addition to the studies examining a full range of A1C values, three additional
studies (14,15,18) evaluated incidence above/below a dichotomous cut point in the
5.8 to 6.1% range. These studies demonstrated incidence estimates two to four times
as great among the higher A1C groups and showed stronger associations between A1C
and subsequent incidence among persons with impaired fasting glucose.
CONCLUSIONS
This systematic review of prospective studies confirms a strong, continuous association
between A1C and subsequent diabetes risk. Persons with an A1C value of ≥6.0% have
a very high risk of developing clinically defined diabetes in the near future with
5-year risks ranging from 25 to 50% and relative risks frequently 20 times higher
compared with A1C <5%. However, persons with an A1C between 5.5 and 6.0% also have
a substantially increased risk of diabetes with 5-year incidences ranging from 9 to
25%. The level of A1C appears to have a continuous association with diabetes risk
even below the 5.5% A1C threshold, but the absolute levels of incidence in that group
are considerably lower.
In light of recent interest in adopting A1C for the diagnosis of diabetes, these findings
may be useful to guide policies related to the classification and diagnosis of persons
at high risk of developing diabetes prior to preventive intervention. The progression
of risk of diabetes with A1C is similar in magnitude and shape as previously described
for fasting plasma glucose and 2-h glucose and suggests that A1C may have a similar
application as an indicator of future risk (27). The ideal decision about what A1C
cut point is used for intervention should ultimately be based on the capacity for
benefit as shown in clinical trials. Our findings suggest that A1C range of 5.5 and
6.5% will capture a large portion of people at high risk, and if interventions can
be employed to this target population, it may bring about significant absolute risk
reduction. Given the current science and evidence of the cost-effectiveness of intensive
interventions conducted in clinical trials (28,29), the use of a threshold somewhere
between 5.5 and 6.0% is likely to ensure that persons who will truly benefit from
preventive interventions are efficiently identified. It is also reassuring that the
mean A1C values of the populations from the Diabetes Prevention Program, the Finnish
Diabetes Prevention Study, and the Indian Diabetes Prevention Program, wherein the
mean A1C was 5.8 to 6.2% and SDs of at least 0.5 percentage points, span the range
from 5.5 to 6.5% (28
–30).
There was considerable variation in the estimates of relative risk and absolute incidence
across studies stemming from several factors. First, there was considerable variation
in the populations studied ranging from relatively young women (15) to older men (23).
Second, the magnitude of relative risk is highly dependent upon the overall risk of
the population and the selection of the referent group; studies with low absolute
risk and the selection of a particularly low-risk referent group will have very high
relative risks across the spectrum of A1C. Third, there was variation in the outcome
definition with almost all studies using fasting glucose of 7.0 mmol/l as the definition
of diabetes, but only approximately half of the studies using the oral glucose tolerance
test. Fourth, there is likely to be some variation in relative risk because of variation
in the calculation of risk statistics; studies reported relative risks, odds ratios,
and incidence ratios, and simple presentations of incidence. Since we lacked original
data, we were unable to optimally convert and standardize risk estimates across groups.
Fifth, A1C assays vary across laboratories. As indicated above, A1C measurement was
standardized by NGSP only in three studies (11,24,25), and only one study (24) reported
both standardized and unstandardized A1C values. When we conducted a sensitivity analysis
in our modeling A1C as a function of incidence using both standardized and unstandardized
A1C values from one study (24), there was the maximum likelihood that continuous curves
did not show any significant difference. Finally, there was variation in the choice
of cutoff points that may have influenced the conclusions. Several studies presented
in our review were not suitable for modeling because they did not examine incidence
of diabetes across a broad range of A1C values. However, the conclusions from these
additional studies were generally consistent with those that examined multiple A1C
categories. For example, studies by Ko et al. (15), Inoue et al. (14), and Little
et al. (18) used dichotomous cut points of 5.8, 6.1, and 6.0, respectively, and found
that persons above the threshold had roughly three times the incidence of those below
the cutoff point.
Several studies found that A1C is particularly predictive of future diabetes after
prior stratification of fasting plasma glucose (11,14,21,24,26). This is consistent
with prior observations that elevated fasting and 2-h glucose in combination indicates
greater risk than either fasting plasma glucose or A1C alone. This improved predictability
may be a function of reducing error variance; in other words, conducting a follow-up
test clarifies the group with more stable hyperglycemia, and is the main reason that
a second test is recommended for a full clinical diagnosis.
Our most important limitation was the lack of original data to model the continuous
association between A1C values and incidence. This lack of original data required
us to use a modeling approach with which many readers are unfamiliar. Nevertheless,
our modeling of average studies resulted in an average incidence value of roughly
1% per year for persons with normal A1C values, an incidence estimate that is consistent
with numerous other estimates of the general population. The lack of access to raw
data also prevented us from conducting formal ROC analyses of A1C cut-off points to
distinguish between eventual cases/noncases or to quantitatively assess the impact
of variation in population characteristics on the relationship between A1C and incidence.
Our findings could also be influenced by the choice of outcome definition. A1C is
more apt to predict diabetes if the outcome is also A1C-based. We did not detect major
differences in the A1C/diabetes incidence association according to the choice of glycemic
test. Since identifying A1C to predict diabetes defined by glycemic indicators is
ultimately circular, future studies should examine the relationship of glycemic markers
and later diabetes risk by using several glycemic markers to define incident diabetes,
as well as to consider morbidity outcomes.
The growth of diabetes as a national and worldwide public health problem, combined
with strong evidence for the prevention of type 2 diabetes with structured lifestyle
intervention and metformin, have placed a new importance on the efficient determination
of diabetes risk. The selection of specific thresholds, however, will ultimately depend
on the interventions likely to be employed and the tradeoffs between sensitivity,
specificity, and positive predictive value. These findings support A1C as a suitably
efficient tool to identify people at risk and should help to advance efforts to identify
people at risk for type 2 diabetes for referral to appropriate preventive interventions.