Faiha Specialized Diabetes, Endocrine and Metabolism Center, Basrah Health Directorate, 1Alzahraa College of Medicine and 2College of Medicine, 
University of Basrah, Basrah, Iraq
*Corresponding Author’s e-mail: ammar.almomin75@gmail.com

Serum Glucose Measurement after Five to Six 
Hours is Comparable to Eight Hours Fasting in 

Ramadan

*Ammar M.S. Almomin,1 Samih A. Odhaib,2 Mahmood T. Altemimi,2 Hussein A. Nwayyir,2 Ibrahim H. Hussein,2 
Haider A.Y. Alidrisi,2 Nassar T.Y. Alibrahim,2 Abbas A. Mansour2

Sultan Qaboos University Med J, February 2022, Vol. 22, Iss. 1, pp. 123–128, Epub. 28 Feb 22
Submitted 23 Oct 20
Revision Req. 10 Dec 20; Revision Recd. 6 Jan 21
Accepted 30 Jan 21

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.5.2021.084

CLINICAL & BASIC RESEARCH

abstract: Objectives: This study aimed to evaluate whether a shorter fasting duration of five to six hours can 
be used as an alternative to the usually recommended eight hours for fasting glucose measurement. Methods: This 
one-month observational, cross-sectional study was conducted during Ramadan (May to June) 2019. It included 
those attending Faiha Specialized Diabetes, Endocrine and Metabolism Center, Basrah, Iraq; all individuals ate 
a pre-dawn meal (suhoor) followed by a complete fast for many hours. Two fasting serum glucose (FSG) venous 
samples were taken; the first was taken five to six hours and the second eight hours after the pre-dawn meal. 
Participants were divided into two groups: individuals with type 2 diabetes mellitus (T2DM) and those with a 
normal glucose level. T2DM patients were further subdivided into three groups: those without treatment, those on 
oral antidiabetic drugs (OAD) and those using insulin and OAD. Results: A total of 200 individuals participated in 
this study. There was no significant difference found between the mean FSG levels in the first and second samples 
for those without T2DM (104.5 ± 21.4 mg/dL versus 104.8 ± 12.6 mg/dL; P = 0.80) as well as those with T2DM 
(235.0 ± 107.0 mg/dL versus 230.0 ± 105.0 mg/dL; P = 0.20). Untreated T2DM patients had non-significant FSG 
readings for the two samples (194.0 ± 151.5 mg/dL versus 193.9 ± 128.9 mg/dL; P = 0.90). Patients on insulin and 
OAD showed a similar pattern of FSG (268.0 ± 111.0 mg/dL versus 269.0 ± 114.0 mg/dL). However, the two FSG 
samples were found to be significantly different among patients on OAD (220.0 ± 78.0 mg/dL versus 207.0 ± 77.0 
mg/dL; P = 0.01). Conclusion: The fasting duration of five to six hours can give a comparable measurement of FSG 
as that obtained after eight hours.

Keywords: Glucose; Fasting; Duration of Therapy; Diabetes Mellitus; Iraq.

Advances in Knowledge
- Fasting five to six hours showed comparable serum glucose measurements to fasting eight hours.

Application to Patient Care
- Shortening the duration of fasting will reduce the waiting time to obtain a valid sample after the last meal.
- Most benefits would be for those who have a limited time for medical services.

Disruption in the typical cyclical pattern of glucose tolerance is the hallmark of type 2 diabetes mellitus (T2DM). Thus, underst- 
anding the normal control of glucose metabolism 
hour-by-hour is critical to achieve optimal diabetes 
care. The current recommendations emphasise the 
standardised measurement of fasting plasma glucose 
(FPG) after overnight fasting for at least eight hours to 
assess the magnitude of basal glucose abnormalities.1–5 
However, the discordance with other diagnostic tests 
and uncertainty regarding the duration of fasting 
reported by some individuals raises a doubt about 
the applicability of the current diagnostic criteria for 
diagnosing diabetes mellitus (DM).6,7

Although plasma is devoid of red and white blood 
cells, they still contain platelets, which consume glucose 
over time. On the other hand, the serum is free from 
any cells and hence, would be suitable for determining 

blood glucose level, especially when there is a time 
delay in the measurement. If assayed immediately, 
blood glucose measured in fluoride plasma correlated 
linearly with blood glucose in the serum; the serum 
value is lower than the corresponding fluoride plasma 
value by 1.15%.8 As this may not be physiologically 
relevant, serum may be used as an alternative for blood 
glucose determination with an error rate of 1.15%.8

Despite wide variations in glucose flux in feeding 
and fasting states, blood glucose is maintained in a 
narrow range; late-night meals can interrupt healthy 
sleep and usually affects glucose control in patients 
with DM. However, the circadian rhythm of cortisol is 
robust and minimally affected.4,9,10

This study aimed to evaluate whether a shorter 
fasting duration of five to six hours can substitute the 
standard glucose measurement after eight hours.

https://creativecommons.org/licenses/by-nd/4.0/


Serum Glucose Measurement after Five to Six Hours is Comparable to Eight Hours Fasting in Ramadan

124 | SQU Medical Journal, February 2022, Volume 22, Issue 1

Methods

A one-month observational, cross-sectional study 
was conducted during the month of Ramadan (May 
to June) in 2019. This study included individuals with 
different demographic characteristics attending Faiha 
Specialized Diabetes, Endocrine and Metabolism 
Center (FDEMC) in Basrah, Iraq. All individuals 
shared the standard behaviour of eating a pre-dawn 
meal, also known as suhoor, at approximately 3 AM 
followed by a complete fast (null by mouth) for many 
hours. Two fasting serum glucose (FSG) samples were 
collected from each participant, the first sample was 
taken five to six hours and the second eight hours after 
the pre-dawn meal. 

The exclusion criteria were as follows: non-fasting 
or incomplete fasting state; patients with type 1 DM; 
fasting without a prior pre-dawn meal; individuals 
who did not have a real pre-dawn meal (i.e. continued 
to eat frequent small meals until fasting time); and 
night-shift workers. 

The participants were divided into two groups: 
individuals with T2DM and individuals without 
T2DM. Individuals with T2DM were subdivided 
according to the modality of treatment into patients 
on only oral antidiabetic (OAD) medications, patients 
on insulin and OAD and patients with no treatment. 
Demographic characteristics, such as gender, age and 
body mass index (BMI), the timing of meals, fasting 
pattern and the type of treatment for T2DM patients 
were collected.

After ensuring a fasting state for five to six hours, 
a venous blood sample of 2–3 mL was collected in 
a plain test tube. The samples were immediately 
transferred to the laboratory and were allowed to be 
clotted then centrifuged prior to the estimation of FSG 
by (COBAS, INTEGRA 400 PLUS, Roche Company, 
Switzerland). This procedure was repeated after eight 
hours of fasting for each individual. 

Data were entered and matched using Microsoft 
Excel (Microsoft Corp., Redmond, Washington, USA); 
subsequently, the different variables were analysed 
using Statistical Package for the Social Sciences (SPSS), 
Version 23.0 (IBM Corp., Chicago, Illinois, USA). The 
study used mean ± standard deviation or frequency for 
data expression. A paired t-test was used to compare 
the difference between the mean FSG readings in 
the two samples. A P value of <0.05 was considered 
statistically significant. 

The study was designed to show the efficacy of 
fasting for only five to six hours to attain a valid fasting 
glucose measurement compared to the standard 
eight-hour fasting. If the mean difference between 
the two samples was less than 6 mg/dL, they would 

be considered equivalent on the assumption that 
variation within this limited range would unlikely 
affect medical decisions in clinical practice. 

All participants were given a detailed explanation 
of the study and written consent was obtained from 
each participant before the day of the examination. 
The FDEMC ethical committee approved the study.

Results 

A total of 200 individuals were included in this study. 
Participants had a mean age of 45.6 ± 14.4 years and 
the majority were male (n = 113, 56.5%). There were 
115 participants (57.5%) had T2DM, which were 
further subdivided according to the type of treatment 
into individuals on OAD (n = 54, 47.0%), individuals on 
insulin and OAD (n = 45, 39.1%) and individuals not 
on any medication for T2DM (n = 16, 13.9%) [Table 1].

The mean FSG after five to six hours for non-
T2DM individuals was 104.5 ± 21.4 mg/dL (5.79 ± 1.18 
mmol/L) compared to the eight-hour sample which 
was 104.8 ± 12.6 mg/dL (5.82 ± 0.70 mmol/L); the 
mean difference was insignificant at -0.2 ± 15.9 mg/
dL (0.01 ± 0.88 mmol/L; P = 0.80). While for T2DM 
patients, the mean FSG was 235.0 ± 107.0  mg/dL 
(13.04 ± 5.94 mmol/L) after five to six hours and 230.0 
± 105.0 mg/dL (12.77 ± 5.83 mmol/L) after eight hours 
of fasting, with a mean insignificant difference of 5.6 ± 
45.6 mg/ dL (0.31 ± 2.53 mmol/L; P = 0.20). According 
to the type of therapy for T2DM, the mean FSG values 
for untreated patients were 194.0 ± 151.5 mg/dL (10.77 
± 8.41 mmol/L) after five to six hours of fasting and 

Table 1: Characteristics of the study’s participants (N = 200)

Characteristic n (%)

Mean age in years 45.6 ± 14.4

Mean BMI ± SD 31.3 ± 6.4

Gender

Male 113 (56.5)

Female 87 (43.5)

Diabetic condition

Non-T2DM 85 (42.5)

T2DM 115 (57.5)

Type of therapy for T2DM patients (n = 115)

No therapy 16 (13.9)

OAD 54 (47.0)

Insulin with OAD 45 (39.1)

SD = standard deviation; BMI = body mass index; T2DM = type 2 
diabetes mellitus; OAD = oral antidiabetic medications.



Ammar M.S. Almomin, Samih A. Odhaib, Mahmood T. Altemimi, Hussein A. Nwayyir, Ibrahim H. Hussein, Haider A.Y. Alidrisi, 
Nassar T.Y. Alibrahim and Abbas A. Mansour

Clinical and Basic Research | 125

193.9 ± 128.9 mg/dL (10.76 ± 7.15 mmol/L) after eight 
hours (P = 0.90). Among T2DM patients on OAD, the 
FSG mean values were 220.0 ± 78.0 mg/dL (12.21 ± 
4.33 mmol/L) after five to six hours and 207.0 ± 77.0 
mg/dL (11.49 ± 4.27 mmol/L) after eight hours of 
fasting with a mean significant difference of 13.1 ± 37.8 
mg/dL (0.73 ± 2.10 mmol/L; P = 0.01). For patients on 
insulin with OAD, the FSG mean values were 268.0 ± 
111.0 mg/dL (14.87 ± 6.16 mmol/L) and 269.0 ± 114.0 
mg/dL (14.93 ± 6.33 mmol/L) at five to six hours and 
after eight hours of fasting, respectively, with a mean 
insignificant difference of -1.4 ± 54.7 mg/dL (0.08 ± 
3.04 mmol/L; P = 0.80) [Table 2 and Figure 1]. 

Discussion

Overnight FPG measurement is a core component of 
glycaemic regulation in T2DM and related disorders. 
However, there is no singular definition of a fasting 
state; the World Health Organization recommends 
an 8–14 hours of fasting while the American Diabetes 
Association defines fasting as no caloric consumption 
for at least eight hours.2,3 In the current study, the 

mean FSG value after five or six hours was similar to 
the value obtained after eight hours as the difference 
being less than 6 mg/dL which seems practically 
irrelevant. 

Moebus et al. measured the hourly decrease in 
FPG since the last nightly meal in healthy individuals. 
They found a non-significant decrease (0.16–0.43 mg/
dL) for each additional fasting hour.4 Unexpectedly, 
they found that three hours of fasting is sufficient to 
give a comparable FPG reading similar to that obtained 
after eight hours.4 These results were ascertained by 
the British Regional Heart Study.11

Glucose homeostasis is never constant.12 The 
human body can maintain normal blood glucose 
levels by modifying insulin response to stimulate 
glucose disposal under the tightly-controlled circadian 
pattern.13,14 However, the relative contribution of the 
circadian versus the behavioural cycle is unclear.15 
Generally, the endogenous hormonal control of 
glucose homeostasis precedes the influential role of 
the suprachiasmatic nucleus (SCN), which occurs 
later throughout the day.16

Table 2: Comparison of fasting serum glucose measurements between five to six hours and eight hours of fasting

Parameters Mean fasting serum glucose in mg/dL ± SD 95% CI for the 
mean difference

t P value

5–6 hours 8 hours Difference

Diabetic condition

Non-T2DM 104.5 ± 21.4 104.8 ± 12.6 -0.2 ± 15.9 -0.37–3.1 -0.1 0.80

T2DM 235.0 ± 107.0 230.0 ± 105.0 5.6 ± 45.6 -2.8–14.0 1.3 0.20

Type of therapy for T2DM patients

No therapy 194.0 ± 151.5 193.9 ± 128.9 0.06 ± 40.1 -21.3–0.9 0.006 0.90

OAD 220.0 ± 78.0 207.0  ± 77.0 13.1 ± 37.8 2.8–23.4 2.5 0.01

Insulin with OAD 268.0 ± 111.0 269.0 ± 114.0 -1.4 ± 54.7 -17.8–15.0 -0.1 0.80

SD = standard deviation; CI = confidence interval; T2DM = type 2 diabetes mellitus; OAD = oral antidiabetic medications.

Figure 1: Boxplots of serum glucose measurements after five to six hours and eight hours fasting among the study’s 
participants.
OAD = oral antidiabetic medications; T2DM = type 2 diabetes mellitus.



Serum Glucose Measurement after Five to Six Hours is Comparable to Eight Hours Fasting in Ramadan

126 | SQU Medical Journal, February 2022, Volume 22, Issue 1

The FPG and plasma insulin maintain a nadir 
overnight in healthy individuals, with a modest, 
transient elevation in insulin secretion rate (ISR) at 
pre-dawn to restrain endogenous glucose production 
(EGP) and prevent hyperglycaemia.17,18 The increased 
insulin requirement at dawn had been attributed to 
either increased insulin clearance that may increase 
almost 2-fold or decreased insulin action and hepatic 
insulin resistance.19 

Morris et al. showed insignificant changes in 
FPG, insulin, ISR and growth hormone (GH) after five 
and eight hours of overnight fasting.15 Healthy humans 
have a time-of-day variation in glucose tolerance with 
highest in the early hours of the day and a trough at 
night;20 however, patients with diabetes show marked 
fluctuations.4,13 

In the current study, which was conducted during 
the early daytime hours, individuals without diabetes 
had FSG readings in the normal upper range after 
eight hours of fasting. The FSG readings did not show 
a significant difference between the 5–6 hour and 
8-hour samples, which matches the cycle of internal 
glucose metabolism.20 On the other hand, patients 
with T2DM had fasting hyperglycaemia according to 
diagnostic guidelines.2,3

The ‘dawn phenomenon’ could explain the early 
morning hyperglycaemia in T2DM patients. This event 
had been observed in patients with diabetes, and even 
in some individuals without diabetes, where glucose 
concentration peaks before the onset of daily activity.7,16,19

When plasma glucose is high before the start of an 
activity, humans seem to be more glucose-tolerant, with 
a preserved glucose homeostasis during the day.16 
Nocturnal elevations in GH and early morning incr- 
eases in cortisol secretion may contribute to this 
phenomenon by stimulating EGP through gluconeo- 
genesis and glycogenolysis.21–24

Van Cauter et al. evaluated individuals for glucose 
and insulin responses after they consumed two low 
caloric mixed meals in the morning and evening. 
They found no difference in FPG levels between five 
and eight hours, while cortisol level peaked after five 
hours and increased slightly more than that after 
eight hours; however, the difference is insignificant. 
Van Cauter et al. suggest the possible contribution of 
cortisol in carbohydrate tolerance, given the failure of 
insulin secretion to increase in proportion to changes 
in post-meal glucose responses.25 The changes in 
cortisol concentration occurred following changes 
in EGP for the control group, while for patients with 
diabetes, EGP increased three hours before a rise in 
cortisol. Moreover, the later decline in cortisol does 

not accompany the fall in EGP and this might be due to 
defective SCN activity in patients with diabetes and/or 
nonlinear personal behaviour.23,25

Many studies found that individuals without 
diabetes have a steady state in terms of glucose 
utilisation, insulin concentration, EGP and glucagon, 
while those with diabetes exhibit a slight increase 
in glucose utilisation after fasting for eight hours 
compared to five hours which reflects the rise in the 
EGP during that time.19,23,26

A Danish study explained the non-linear inverse 
relationship between insulin sensitivity and glucagon 
response and described high fasting glucagon level 
versus lower insulin sensitivity and inadequate 
glucagon suppression after meals.27

Monnier et al. found that OAD does not adeq- 
uately control the prebreakfast hyperglycaemia that 
occurs between 6 AM and 8 AM particularly in the 
presence of dawn phenomenon , even when they are 
given in combination. Sulphonylureas increases the 
risk of developing afternoon or evening hypoglycaemia 
after dose adjustment to counteract the early morning 
hyperglycemia.28,29 Oral incretin-based therapies may 
improve blood glucose in the postprandial but not 
during the fasting period.30 On the contrary, the evening 
administration of basal insulin is effective in abolishing 
the ‘dawn phenomenon’ by restraining EGP and 
lipolysis.17 

The present study shows no significant difference 
in the first and second FSG readings in patients with 
diabetes, as well as in individuals without diabetes. The 
only exception was for those with T2DM using only 
OAD, who showed a significant difference between 
the two fasting readings.

There are several limitations to this study. First, 
this study could not determine whether the FSG 
changes after fasting for five to six and eight hours 
reflected the effect of the duration of prior fasting or 
real circadian modulation. Second, the quality and 
patterns of night sleep that impact FSG levels were 
not assessed. Third, this study did not determine the 
precise timing and amount of last caloric intake, as 
this was self-reported and, therefore, subject to error 
and potential bias. Although, approximate recordings 
of the timing of food intake were collected, it was not 
possible to identify which ingestions were considered 
by the participants as meals. Fourth, the exercise 
effect was not estimated. Lastly, the responses of the 
counter-regulatory hormones and melatonin during 
and after six and eight hours of fasting were not 
measured; this may be a potential topic to be explored 
in future research.



Ammar M.S. Almomin, Samih A. Odhaib, Mahmood T. Altemimi, Hussein A. Nwayyir, Ibrahim H. Hussein, Haider A.Y. Alidrisi, 
Nassar T.Y. Alibrahim and Abbas A. Mansour

Clinical and Basic Research | 127

Conclusion

There was no significant difference in FSG after five 
to six and eight hours fasting in individuals with or 
without T2DM. The minimal fasting duration to 
assess FSG can be shortened to five to six hours and 
there is no need to fast an extra two to three hours. 
This study’s findings support the recommendation of 
standardisation of fasting duration as it is essential 
in clinical studies that deal with glycaemic control. 
Further studies are needed to evaluate the appropriate 
timing and duration of fasting in non-Ramadan fasters, 
as well as the evaluation of the effect of sleep quality 
and the circadian rhythm on the glycaemic pattern.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

a u t h o r s’ c o n t r i b u t i o n 
AMSA designed the study. MTA, HAN and IHH 
planned and supervised the work. AAM was the 
project director. All authors collected the data. HAYA 
and NTYA performed the computational framework 
and analysed the data. SAO drafted the manuscript. 
All authors reviewed and edited the manuscript. All 
authors approved the final version of the manuscript.

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