Effect of self-monitoring of blood glucose on glycaemic outcome among type 2 diabetic patients


S Afr Fam Pract
ISSN 2078-6190   EISSN 2078-6204

© 2017 The Author(s)

RESEARCH

South African Family Practice 2017; 59(6):208–213
http://dx.doi.org/10.1080/20786190.2017.1340250

Open Access article distributed under the terms of the
Creative Commons License [CC BY-NC 3.0]
http://creativecommons.org/licenses/by-nc/3.0

South African Family Practice is co-published by Medpharm Publications, NISC (Pty) Ltd and Informa UK Limited  
[trading as the Taylor & Francis Group]

Effect of self-monitoring of blood glucose on glycaemic outcome among type 2 
diabetic patients
Oluwajimi Olanrewaju Sodipoa*  , Ayoade Adedokuna and Adedeji Adejumo Olusolab

a Department of Family Medicine, Lagos State University Teaching Hospital, Ikeja, Lagos State
b Department of Community Health and Primary Health Care, Lagos State University Teaching Hospital, Lagos, Nigeria
*Corresponding author, email: olujimiso@gmail.com  

Background: Diabetes mellitus is a chronic metabolic disorder which leads to complications especially when not properly 
managed. The role of self-monitoring of blood glucose (SMBG) in type 2 diabetic patients using oral hypoglycaemic agents has 
been a source of controversy.
Objective: The objective was to study the effect of SMBG on glycaemic outcome among type 2 diabetics in a primary care setting.
Methodology: A randomised control study was conducted between March 2013 and November 2013 at the General Outpatient 
Clinic of the Family Medicine Department (FMD) in Lagos State University Teaching hospital. A total of 120 diabetic patients were 
randomised into intervention and control groups; 107 patients (55 in the intervention and 52 in the control group) completed 
the study. Intention-to-treat analysis was done. Chi-square, Students t- and paired t-test were used to determine variables 
significantly associated with SMBG.
Results: More than three-quarters (77.5%) of the participants were aware of SMBG prior to commencement of the study. Both 
the SMBG (8.7% vs. 7.2%; p-value < 0.001) and non-SMBG (8.7% vs 7.7%; p-value < 0.001) groups had a significant improvement 
in HbA1c at the end of the study. Similarly there was a significant improvement in FBG among both groups (SMBG 153 mg/dl vs. 
123 mg/dl; p-value < 0.001 and non-SMBG (158 mg/dl vs. 137 mg/dl; p-value 0.022).
The HbA1c at the end of the study was 7.2% for the SMBG vs 7.7% for the non-SMBG group with no statistical difference (p-value 
0.174).
Conclusion: The use of SMBG among type 2 DM patients did not result in better glycaemic control compared with patients who 
did not practise SMBG. It could be due to close follow-up and education of both groups.

Keywords: diabetes mellitus, fasting blood glucose, glycosylated haemoglobin, self-monitoring of blood glucose

Introduction
Diabetes mellitus (DM) can be defined as a syndrome of chronic 
hyperglycaemia characterised by insulin deficiency, insulin 
resistance or both.1,2 In 2011 there were 366 million diabetics 
with a further 230 million at risk due to the evolving obesity 
pandemic and it is projected that by 2030, there will be 522 
million diabetics worldwide and 398 million at risk.2

Currently the global prevalence of DM is 2%.2 In 2013, the 
International Diabetes Federation (IDF) reported a prevalence of 
4.2% for the African region.2 The burden of diabetes is increasing 
in low- and middle-income countries like Nigeria with more 
money being spent on complications due to poorly controlled 
diabetes.3,4 Nigeria has a reported prevalence rate of 2.2% with 
regional differences.4

Self-monitoring of blood glucose (SMBG) is defined as the 
collection by diabetic patients of detailed information about 
their blood glucose levels at many time points during the day on 
a day-to-day basis in order to aid adjustments in therapy and 
lifestyle activities and ultimately improve glycaemic control and 
prevent diabetes-related complications.5 It is said to be structured 
SMBG when the blood glucose data are gathered according to a 
defined regimen, interpreted, and then utilised to make 
appropriate pharmacologic and/or lifestyle adjustments.5

In Africa as in most developing countries, the practice of 
SMBG is poor. SMBG is still not practised widely in Nigeria 

despite an increasing awareness.7 A study in Port Harcourt 
reported only 27% of diabetic patients practised SMBG 
despite 96% of them being aware of its existence.7 The 
multicentre diabetes care study, which was carried out across 
seven tertiary health centres in Nigeria to evaluate the quality 
of care of diabetics, reported that 72.8% of patients did not 
practise SMBG.3

Other studies from Nigeria have also reported a variation in the 
practice of SMBG between urban and rural settings with rates of 
3.4% in rural areas to 73% in urban areas in Nigeria.3,7

Some of the reasons for the low use of glucometers includes 
cost, denial as patients do not want to know, doctors do not 
recommend or promote SMBG, results are not acted upon and 
pain.8

Various studies have been carried out in Nigeria to determine the 
glycaemic control of DM patients using HbA1c. During more 
than 12 years of using HbA1c for monitoring of glycaemic control 
among patients at Nigerian hospitals, the mean glycosylated 
haemoglobin ranged from 7.9% to 8.3% with most patients (63% 
to 68%) having poor glycaemic control.9

The reasons for poor glycaemic control among Nigerian diabetic 
patients are multi-factorial and include low level of literacy/
health education, and poor drug and medication adherence 
amongst others.10

http://orcid.org/0000-0002-5667-3656
mailto:olujimiso@gmail.com
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209 South African Family Practice 2017; 59(6):208–213

The role of SMBG in assisting the achievement of glycaemic 
control by type 2 diabetic patients using oral hypoglycaemic 
agents has not been clearly defined.1,11,12

Randomised control trials such as DiGEM, DINAMIC and 
ESMON reported no difference in levels of glycaemic control 
amongst type 2 DM patients who either practised or did not 
practise SMBG.13–15 These trials did not use structured SMBG 
and only assessed HbA1c as treatment endpoint without 
checking for other benefits such as reduction in glycosylated 
haemoglobin.

Other randomised control trials which have used a study design 
incorporating structured SMBG testing have, however, showed 
benefit in greater mean reduction of glycosylated haemoglobin 
in type 2 DM patients who practised SMBG.16

There are only a few studies in Africa, including Nigeria, on the 
efficacy of SMBG among type 2 DM patients. A cross-sectional 
study carried out in Sudan concluded that SMBG did not improve 
glycaemic control in type 2 DM patients.17 A recent study in 
South Africa on the effect of SMBG, however, reported benefits 
regarding glycaemic control following the introduction of 
glucometers alongside patient education.18

The aim of this study was to assess the effect of SMBG on 
glycaemic outcome among type 2 diabetics with a view to 
instituting its use to improve glycaemic control among type 2 
DM patients.

Methods and materials

Study area
This study was carried out at the General Outpatient Clinic of the 
Family Medicine Department of Lagos State University Teaching 
Hospital, Ikeja, Lagos. The hospital is situated in the south-western 
part of Nigeria. Lagos is estimated to have a population of 21 
million people.19 The annual GOPD attendance is about 40 000 
with a monthly average of 2 900 and daily attendance of 300–400 
patients. There are about 15–20 DM patients who visit the clinic 
daily with an overwhelming majority being type 2 DM patients.

Study design
This was a randomised control trial of eight months’ duration 
conducted at the family medicine GOP clinic of the Lagos State 
University Teaching Hospital to assess the effect of self-
monitoring of blood glucose on glycaemic outcome among 
Type 2 DM patients in a primary care setting.

Inclusion criteria
The study consisted of patients with type 2  DM who were on 
antidiabetic medications seeking medical care at the family 
medicine (GOP) clinic of the Lagos State University Teaching 
Hospital (LASUTH), Ikeja, Lagos State.

Exclusion criteria
Diabetic patients with emergencies, chronic complications such 
as nephropathy, neuropathy etc., those already using glucometer 
and < 18 years of age were excluded.

Sample size determination
The sample size was determined using the following formula for 
sample size with 2 means and normal distribution:20 

n =
(Z�+Z�)

2
×(�1+�2)

2

d
2

n is minimum sample size for each group; Zα is the probability of 
falsely rejecting a true null hypothesis (α) = 1.96; Z β is the 
probability of failing to reject a false null hypothesis (β) = 0.84; σ1 
is the standard deviation of glycosylated haemoglobin difference 
practising SMBG from a previous study21 = 1.1; σ2 is the standard 
deviation of glycosylated haemoglobin difference not practising 
SMBG from a previous study21 = 0.9; d is the size of the effect that 
is clinically worthwhile to detect clinical standardised 
difference = 0.9/1.1 = 0.819 = 0.82;

To adjust for attrition, an estimated dropout rate of 20% was 
assumed (because of duration of the study) and sample size 
calculated as21:

Where N″  =  corrected sample size; N = initial sample size;  
q = estimated attrition rate (20% = 0.2); N�� = 47

1−0.2
= 58.29 = 60;

A sample size of 120 was used comprising 60 patients in each 
group (those practising SMBG and those not practising SMBG)

Recruitment and sampling technique
A total of 120 type 2 DM patients seeking medical care at the 
family medicine department who had met the inclusion criteria 
were consecutively recruited into the study after obtaining their 
consent, until the required sample size was attained. An average 
of 3–5 diabetic patients were recruited at every clinic visit.

A simple randomisation scheme with the toss of a coin was used to 
allocate participants into the intervention group (given glucometers 
to practise SMBG) and the control group (not to practise SMBG). 
Figure 1 shows the distribution of the study sample.

Study procedure
Patients in the intervention group were provided with a 
glucometer (which is a standardized autocoding blood glucose 
monitoring machine) and 25 fine test glucometer strips every 
month for three months. They were trained in the appropriate use 
of the glucometer. They were also required to write down their 
glucose reading, which was reviewed at their monthly clinic visits. 
Patients in both groups were given an initial structured education 
programme on diabetes and its complications by the researcher.

The participants in the intervention group (SMBG group) 
checked their blood glucose before and after meals (pre- and 
post-prandial) 3  days a week for 12 weeks in the following 
‘structured’ manner:

(a) Day 1: Breakfast (pre- and 2 hours post-prandial);

(b) Day 2: Afternoon (pre- and 2 hours post-prandial);

(c) Day 3: Night (pre- and 2 hours post-prandial).

Both groups were seen in the clinic by the researcher monthly 
and had fasting and two hours post-prandial glucose 
measurement taken at each visit with and appropriate treatment 
changes made based on the results. The patients were educated 
to have at least eight hours’ fast before the fasting blood glucose 
sample was taken. In a bid to prevent bias and reduce attrition 
among the study participants there was allocation concealment 
as each group was given separate days for its follow-up.

n =
(1.96 + 0.84)

2
× (1.1 + 0.9)

2

0.82
2

= 46.64 = 47.

N
��
=

N

1 − q



Effect of self-monitoring of blood glucose on glycaemic outcome among type 2 diabetic patients 210

Participants were advised not to take medications apart from 
those prescribed by the researcher and also to present to the 
clinic if they had any complaints. Blood samples were taken for 
glycosylated haemoglobin at the beginning (initial visit) and the 
end of the study (12th week).

In total, each participant had 4 clinic visits (0, 4  weeks, 8  weeks 
and 12 weeks).

Instruments
A structured pretested questionnaire was used to obtain 
information on the patient’s biodata, average monthly income, 
knowledge of their care including the date of diagnosis, type of 
medication and adherence to medication use. Information on 
knowledge concerning self-monitoring of blood glucose and 
knowledge of glycaemic targets was also obtained.

Ethical considerations
Approval was obtained from the Health Research and Ethics 
Committee of LASUTH. Written informed consent was obtained 
from each participant after offering a detailed explanation of the 
purpose of the study.

Definition of outcome variables

(1)  Glycaemic control was assessed as follows: good control 
was HbA1c of < 7% (< 53.3 mmol/mol) or FBG < 110mmg/
dl (< 6.1 mmol/l) while poor control was HbA1c of ≥ 7% 
(53.3 mmol/mol) or FBG ≥ 110 mg/dl (> 6.1 mmol/l).1

(2)  Medication adherence was assessed by asking the partic-
ipants if they used their medications and checking the 
empty foils of used drugs.

(3)  The glycaemic control was assessed using glycosylated 
haemoglobin and fasting blood glucose levels.

(4)  The glycosylated haemoglobin was assessed using the 
DCCT aligned Clover A1c Analyser (Infopia Co. Ltd, Korea) 
with a test range of 4–14%. Daily calibration of the ma-
chine was done using check cartridges with lot number 
LK13G10. The Clover HbA1c machine is on the list of 
NGSP certified methods for assessing glycosylated 
haemoglobin.22

Data analysis
Data were entered and analysed using Epi info 6 (CDC, Atlanta, 
GA, USA). Percentages, mean and standard deviation of 
numerical variables were determined. Student’s t-test and paired 
t-test were used to compare numerical variables. A chi-square 
test and Fisher’s exact test were used to compare categorical 
variables as appropriate. For all statistical tests, the confidence 

Figure 1: Distribution of the study population.

Table 1: Socio-demographic and clinical characteristics of the 
respondents (pre-intervention)

Note: N = 90.
*Fisher’s exact test; **t-test.

Variables Control non-
SMBG, n = 60 

N (%)

Intervention 
SMBG), n = 60 

N (%)

χ2 p-value

Age (years) 

< 40 years old 2 (25.0) 6 (75%) 2.143 0.143*

> 40 years old 58 (51.8%) 54 (49.5%)

Mean age 59 ± 
10.95 years

60.55 ± 10.16 57.3 ± 12.29 1.58 0.116**

Gender

Male 20 (46.5) 23 (53.5) 0.32 0.288

Female 40 (51.9) 37 (48.1)

Educational status

No education 5 (62.5) 3 (37.5) 0.53 0.25*

Some education 55 (49.1) 57 (50.95)

Duration of diabetes

Less than 3 years 35 (51.5) 33 (48.5) 0.358 0.136

Greater than 3 
years

25 (48.1) 27 (51.9)

Number of antidiabetics used 

One drug 15 (51.7) 14 (48.3) 0.045 0.41

More than one 
drug

45 (49.5) 46 (50.5)

Use of drugs as prescribed

Yes 49 (49.5) 50 (50.5) 0.058 0.41

No 11 (52.4) 10 (47.6)

Monthly income

Low (< 50 000 
naira)

54 (52.4) 49 (49.6) 1.71 0.102

Middle and high 
(> 50 000 naira)

6 (35.3) 11 (64.7)



211 South African Family Practice 2017; 59(6):208–213

The HbA1c at the end of the study was 7.2% (55.2 mmol/mol) for 
the SMBG and 7.7% (58.5  mmol/mol) for the non-SMBG group 
with no statistical difference (p-value 0.174). Similarly the FBG for 
the SMBG group and non-SMBG group at the end of the study was 
123.2  mg/dl (6.83  mmol/l) and 137.6  mg/dl (7.64  mmol/l) 
respectively with no statistical difference (p-value 0.087) (see Table 
3).

The reduction in HbA1c for SMBG and Non-SMBG groups at the 
end of the study was 1.5% and 1% respectively (see Table 3). The 
reduction in FBG of the SMBG and non-SMBG groups at the end of 
the study was 31 mg/dl and 12.4 mg/dl respectively (see Table 3).

interval was set at 95%. Intention-to-treat analysis was done. 
Statistical tests were considered significant if p-value was less 
than 0.05. Microsoft Excel (Microsoft Corp, Redmond, WA, USA) 
was used to draw charts.

Results
A total of 120 respondents divided into 2 equal groups were 
recruited for the study. In all, 107 respondents (52 in the control 
group and 55 in the intervention group) completed the study.

The age, gender, educational and other clinical parameters of the 
SMBG and non-SMBG groups were similar (p-value  >  0.05) as 
shown in Table 1.

Three-quarters (90; 75.0%) of the respondents had co-morbid 
conditions with 48 (40.0%) respondents in the SMBG group and 
42 (35.0%) in the non-SMBG group. Hypertension was the most 
common co-morbidity as shown in Figure 2.

The majority (93; 77.5%) of the respondents were aware of SMBG; 
there was no significant difference in the proportion of subjects 
that were aware in the SMBG and non-SMBG group at 
commencement of the study (p > 0.05), as shown in Table 2.

About half (51; 42.5%) of the respondents were aware of their 
glycaemic targets with no difference in knowledge among the 
two groups of respondents at commencement of the study (p > 
0.05) as shown in Table 2.

The HbA1c of the SMBG and non-SMBG groups (pre-intervention) 
was 8.7% (71.6  mmol/mol), which was similar. The FBG was 
150  mg/dl (8.33  mmol/l) for the non-SMBG and 154  mg/dl 
(8.55 mmol/l) mg/dl for the SMBG group at the commencement of 
the study, which were similar (p-value 0.711) as shown in Table 3. 

Figure 2: Co-morbid conditions of the respondents.

Table 2: Awareness of SMBG and glycaemic targets

Note: N =120.

Variable Control (non-
SMBG), n = 60 

N (%) 

Intervention 
(SMBG), n = 60 

N (%) 

χ2 p-value

Are you aware of SMBG 

Yes 45 (48.4%) 48 (51.6%) 0.43 0.26

No 15 (55.6%) 12 (44.4%)

Awareness of glycaemic targets

Yes 23 (45.1) 28 (54.9) 0.85 0.18

No 37 (53.6) 32 (46.4)

Table 3: Change in HbA1c and FBG of the intervention and control 
groups

Note: N = 120.
*= 107 (52 control and 55 in intervention group who completed the study).

Variable Intervention 
(SMBG)

Control (non-
SMBG)

t p

Mean ± SD Mean ± SD

Pre-intervention 
FBG (mg/dl)

154.0 ± 55.8 150 ± 65.6 0.372 0.711

Post-intervention 
FBG* (mg/dl)

123.2 ± 35.1 137.6 ± 50.1 1.729 0.087

Pre-intervention 
HbA1c (%)

8.7 ± 2.3 8.7 ± 2.6 0.019 0.985

Post-intervention 
HbA1c* (%)

7.2 ± 2.0 7.7 ± 2.0 1.369 0.174

Table 4: HbA1c and FBG before and after intervention in the two groups

Notes: N = 107 (52 in control and 55 in the intervention group who completed the 
study).

Group Before 
intervention

After 
intervention

Paired t 
test

p

Mean ± SD Mean ± SD

HbA1c (%)

Intervention 
(SMBG)

8.7 ± 2.3 7.2  ±  2.0 5.022 < 0.001

Control (non-
SMBG)

8.5 ± 2.4 7.7 ± 2.0 3.922 < 0.001

FBG (mg/dl)

Intervention 
(SMBG)

153.0 ± 56.4 123.2 ± 35.1 3.838 < 0.001

Control 
(non-SBMG)

151.7 ± 66.9 137.6 ± 50.1 2.372 0.022



Effect of self-monitoring of blood glucose on glycaemic outcome among type 2 diabetic patients 212

Conclusion
In conclusion, this study highlights the importance of proper 
education of patients on diabetes mellitus medication 
intensification and close follow-up; the results cast doubt on the 
usefulness of SMBG among type 2 diabetics not using insulin. 
This is particularly important in resource-poor settings in Africa 
where the cost of glucometers and strips may be prohibitive for 
the average diabetic patient. There will, however, be a need for 
further studies of longer duration to assess the long-term 
benefits or otherwise of using glucometers.

ORCID
Oluwajimi Olanrewaju Sodipo    http://orcid.org/0000-0002-
5667-3656

References
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3.  Chinenye S, Young E. Diabetes care in Nigeria. The Nigerian Health 
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5.  Leszek C, Laszlo B, Svetlana B, et al. Self-monitoring of blood glucose 
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10.  Oghagbon EK. Improving persistently elevated HbA1c in diabetes 
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12.  VA/DoD clinical practice guideline for the management of diabetes 
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13.  O’Kane MJ, Bunting B, Copeland M. Efficacy of self monitoring of 
blood glucose in patients with newly diagnosed type 2 diabetes 
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https://doi.org/10.1136/bmj.39534.571644.BE

14.  Barnett AH, Krentz AJ, Strojek K. The efficacy of self-monitoring 
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A multicentre, randomized, parallel-group, 6-month evaluation 
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15.  Farmer A, Wade A, Goyder E. Impact of self monitoring of blood 
glucose in the management of patients with non-insulin treated 
diabetes: open parallel group randomised trial. BMJ. 2007;335:132. 
https://doi.org/10.1136/bmj.39247.447431.BE

16.  Parkin CG, Buskirk A, Hinnen DA, et al. Results that matter: 
structured vs. unstructured self- monitoring of blood glucose 
in type 2 diabetes. Diabetes Res Clin Pract. 2012;97:6–15. 
https://doi.org/10.1016/j.diabres.2012.03.002

17.  Abdulquadir M, Elbagir M, Elton M. The Influence of glucose self 
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At the end of the study, both the SMBG and non-SMBG groups 
had a statistically significant improvement in their HbA1c (p-
value  <  0.001) and FBG (intervention < 0.001, control p-value 
0.022) as shown in Table 4.

Discussion
This study found that 77.5% of participants were aware of SMBG. 
A study in Port Harcourt on SMBG reported that 96% of diabetic 
patients were aware of SMBG.7 Studies in Nigeria have reported 
knowledge and practice of SMBG ranging from 3.4–73% in rural 
and urban areas respectively.8

The majority of the participants were not aware of their glycaemic 
targets prior to commencement of the study. A study among 
diabetics being managed in healthcare facilities in Imo state, 
Nigeria similarly reported that a majority of diabetics had poor 
knowledge about their management.23 It is important that 
diabetic patients have a good knowledge of their care in order to 
utilise results obtained from SMBG in making decisions about 
their diet, exercise and medication use as well as to better 
manage their illness.

There was a significant improvement in HbA1c and FBG of the 
non-SMBG and SMBG groups, with no difference in glycaemic 
control between the two groups at the end of the study. This is in 
keeping with previous studies such as the ESMON, DiGEM, 
DINAMIC Swedish primary care studies, and King Drew Medical 
Centre trial amongst others, which reported no difference in 
glycaemic control among type 2 diabetics who were using oral 
antidiabetic agents, regardless of the practice of SMBG.13–15,24,25 
These studies instead highlighted education of patients and 
aggressive intensification of treatment as being more important 
than SMBG in achieving glycaemic control in type 2 DM.13,14,25 The 
finding in this study differs from reports in trials such as the St 
Carlos study, Kaiser Permantle and a study in South Africa, which 
showed that type 2 diabetic patients using oral antidiabetic 
agents and who practised SMBG had better glycaemic control 
than those who did not.26–29 The fact that both groups had 
education on diabetes mellitus and diet and were followed up 
closely with intensification could account for the finding in this 
study. The duration of follow-up being three months could also 
be responsible. Other factors such as diet and drug adherence 
amongst others could also have played a role.11,16

The SMBG group had an HbA1c reduction of 1.5% while the non-
SMBG group had a reduction of about 1%, though there was no 
statistical difference. A reduction in HbA1c of 1% leads to a 25% 
reduction in diabetes-related deaths, a 7% reduction in all-cause 
mortality, and an 18% reduction in combined fatal and non-fatal 
myocardial infarction.1 The UKPDS study also reported that a 
1.0% reduction in mean HbA1c was associated with a 37% 
decline in microvascular complications, as measured by reduced 
rates of laser therapy and cataract surgery.1

Limitations of the study
The use of point-of-care machines for monitoring glycosylated 
haemoglobin could cause variability in the results. However, the 
machine is on the National Glycosylated Haemoglobin 
Standardisation Program (NGSP) list of validated point-of-care 
machines.22 The packed cell volume and genotype of the patients 
were also not known, which could also affect the glycosylated 
haemoglobin, though the patients did not have any clinical 
features of anaemia or haemoglobinopathy.

http://orcid.org
http://orcid.org/0000-0002-5667-3656
http://orcid.org/0000-0002-5667-3656
http://www.idf.org/diabetesatlas
http://www.idf.org/diabetesatlas
http://www.idf.org
http://www.healthquality.va.gov
http://www.healthquality.va.gov


213 South African Family Practice 2017; 59(6):208–213

25.  Davidson MB, Castellanos M, Kain D. The effect of self monitoring 
of blood glucose concentrations on glycated hemoglobin levels in 
diabetic patients not taking insulin: a blinded, randomized trial. Am J 
Med. 2005;118:422–5. https://doi.org/10.1016/j.amjmed.2004.12.006

26.  Bonomo K, De Salve A, Fiora E, et al. Evaluation of a simple policy for 
pre- and post-prandial blood glucose self-monitoring in people with 
type 2 diabetes not on insulin. Diabetes Res Clin Pract. 2010;87(2):246–
51. https://doi.org/10.1016/j.diabres.2009.10.021

27.  Duran A, Martin P, Runkle I, et al. Benefits of self-monitoring blood 
glucose in the management of new-onset Type 2 diabetes mellitus: 
the St. Carlos Study, a prospective randomized clinic-based 
interventional study with parallel groups. J Diabetes. 2010;2(3):203–11. 
https://doi.org/10.1111/jdb.2010.2.issue-3

28.  Karter AJ, Parker MM, Moffet HH. Longitudinal study of new and 
prevalent use of self-monitoring of blood glucose. Diabetes Care. 
2006;29:1757–63. https://doi.org/10.2337/dc06-2073

29.  Polonsky WH, Fisher L, Schikman CH, et al. Structured self-monitoring 
of blood glucose significantly reduces A1C levels in poorly controlled, 
noninsulin-treated type 2 diabetes: results from the Structured 
Testing Program study. Diabetes Care. 2011;34(2):262–7. https://doi.
org/10.2337/dc10-1732

Received: 15-02-2017 Accepted: 06-06-2017

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5491.2011.03268.x

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https://doi.org/10.1080/16089677.2016.1198112
https://doi.org/10.1080/16089677.2016.1198112
http://www.lagosstate.gov.ng/pagelinks.php?p
https://doi.org/10.1111/j.1464-5491.2011.03268.x
https://doi.org/10.1111/j.1464-5491.2011.03268.x
http://www.ngsp.org/docs/methods.pdf

	Introduction
	Methods and materials
	Study area
	Study design
	Inclusion criteria
	Exclusion criteria
	Sample size determination
	Recruitment and sampling technique
	Study procedure
	Instruments
	Ethical considerations
	Definition of outcome variables
	Data analysis

	Results
	Discussion
	Limitations of the study
	Conclusion
	References