The World Health Organization defines anaemia as a haemoglobin level of less than 12 g per dL (120 g per L) in women and less than 13 g per dL (130 g per L) in men [1]. Anaemia was estimated to be present in one-third of the global population in 2010 [2]. Anaemia in older persons is likely to contribute significantly to the global burden of disease as it is independently associated with increased morbidity and mortality [3, 4]. Even mild anaemia can affect the quality of life in older persons [5].
Anaemia in the older person is often unrecognized due to its nonspecific symptoms of weakness and lethargy, which are often mistaken for the ageing process. Anaemia is associated with increasing age and chronic diseases including kidney diseases and diabetes mellitus and is more common in hospitalized individuals [6]. Gaskell et al. 2008 found an association between anaemia with gender and ethnicity, with African Americans and Asians being more likely to develop anaemia than Caucasians. Different ethnicities have varying cultural or religious beliefs, which in turn influence the choices of food, especially iron-rich food such as meat [7]. A previous Malaysian study on racial variations in anaemia among pregnant mothers reported that those of Indian ethnicity were found to have a higher prevalence of anaemia compared to other ethnic groups in Malaysia. Factors associated with anaemia were not identified in this study [8].
The relationship between ethnicity and anaemia has yet to be determined within the Malaysian population. Malaysia is a multiethnic nation, where its population is comprised of three major Asian ethnic groups with a large, heterogeneous indigenous population. This study aims at identifying the potential differences in susceptibility to anaemia among the three major ethnic groups in Malaysia. In addition, using available demographic and medical information, we aimed to identify potential mediators of these differences. An understanding of ethnic differences will facilitate further understanding of the potential influences of cultural practices, dietary factors, and genetic differences on anaemia in older adults.
2. Methods
This study was conducted using data from the National Health and Morbidity Survey (NHMS) 2015, a nationwide, cross-sectional survey evaluating the overall health status, health needs, and health expenditure in the Malaysian population. It is a household survey conducted by the Institute for Public Health, Ministry of Health Malaysia in 4 yearly cycles, with the main aim of monitoring noncommunicable diseases and their risk factor burden. Data collection was carried out from March 2015 until May 2015.
Ethical approval for this study was obtained from the Medical Research and Ethics Committee (MREC), Ministry of Health, Malaysia. Written consent was obtained from all respondents. The methodology of this study has been described in the technical report of the NHMS 2015 [9]. Anaemia was included as a topic together with other common health problems among the adult population.
2.1. Population and Sampling
The geographical location was stratified into 15 states to ensure national representativeness during the sampling procedure. Multistage random selection was conducted based on enumeration blocks and living quarters provided by the Department of Statistics, Malaysia. For the purpose of this study, only data obtained from individuals aged 60 years and above were included.
2.2. Sociodemographic and Clinical Characteristics
The sociodemographic variables of age, ethnicity, education level, marital status, and household income quintiles were included in this study. Respondents were also asked whether they had been admitted to hospital over the past 12 months or received any outpatient treatment over the previous 2 weeks.
Capillary blood sample was tested for haemoglobin level using the HemoCue haemoglobinometer (HemoCue Hb 201+ System, Angelhom, Sweden) [10, 11]. Anaemia was defined as blood haemoglobin levels below 12 g/dL for older women and below 13 g/dL for older men [1]. Glucose levels were tested using Cardiochek PA. These point-of-care procedures were carried out by trained health staff. The presence of diabetes was determined based on a fasting blood glucose measurement of 6.1 mmol/l and above or random blood glucose measurement of 11.1 mmol/l and above. Respondents who were previously diagnosed as having diabetes mellitus by a physician or assistant medical officer would report themselves as “known diabetes.”
2.3. Statistical Analysis
IBM SPSS Statistics for Windows, Version 21.0 software, was used for data analysis. Descriptive analysis was conducted to determine the relation between the sociodemographic distribution and anaemia according to the three main ethnic groups: Malays, Chinese, Indians, and a residual “Others” category (which included all Malaysian citizens from indigenous populations). Categorical data were compared with the Chi-squared test while age, which was a continuous variable, was compared using the one-way ANOVA test. Finally, all variables with a p value of 0.20 and above were included in a multivariate logistic regression model. The first model was adjusted with all the sociodemographic variables after adjustment for age. The second model identified the relationship between ethnicity and age, diabetes status, and hospital admission. The findings were presented as adjusted odds ratios (aORs) with 95% confidence intervals (CI), and a p value < 0.05 was considered significant.
For the sake of both clarity and brevity, this paper will henceforth refer to Malaysian citizens of Malay, Chinese, and Indian ethnicities as simply Malays, Chinese, and Indians, respectively. Malaysian citizens of other ethnicities will be referred to as “Others.”
3. Results
The overall response rate for the survey was 86.4%. Out of 3794 older Malaysian citizens, 3556 (93.7%) consented to anaemia screening. The mean age was 68 (±7) years. The respondents consisted of 64.0% Malays, 21.6% Chinese, 6.1% Indians, and 8.3% Others. Gender proportions of the respondents were similar. The majority of the Chinese and Indians lived in urban areas while Malays and others were equally distributed between urban and rural areas. Out of the total population, 11.2% had hospital admissions in the past 12 months while 13.4% had outpatient attendances. Diabetes was present in 38.1% and was most common among the ethnic Indians. Table 1 summarizes the sociodemographic characteristics of the population according to the four groups.
Sociodemographic profiles of the respondents 4 major ethnicities in Malaysia.
Variables
Overall (n=3794)
Malay (n=2,429)
Chinese (n=818)
Indian (n=232)
Others (n=315)
n (%)
n (%)
n (%)
n (%)
n (%)
Age Mean (SD)
68.56 (7.11)
68.30 (6.89)
69.17 (7.39)
68.80 (7.50)
68.82 (7.65)
Gender
Male
1773 (48.97)
1115 (47.55)
401 (51.96)
98 (44.00)
159 (48.63)
Female
2021 (51.03)
1314 (52.45)
417 (48.04)
134 (56.00)
156 (51.37)
Level of Education
No Formal Education
799 (21.39)
432 (18.60)
150 (15.85)
48 (16.35)
169 (56.66)
Primary
1959 (47.59)
1364 (51.29)
403 (49.54)
92 (39.11)
100 (29.05)
Secondary and higher
1025 (31.02)
627 (30.11)
261 (34.62)
91 (44.54)
46 (14.29)
Marital Status
Married
2558 (68.26)
1641 (67.30)
557 (70.03)
136 (63.77)
224 (69.56)
Currently Not Married
1234 (31.74)
787 (32.70)
260 (29.97)
96 (36.23)
91 (30.44)
Household Income
Q1 (RM0–RM300)
1224 (31.01)
773 (28.13)
259 (32.13)
61 (25.60)
131 (44.24)
Q2 (RM301–RM1100)
879 (20.84)
628 (25.44)
143 (15.29)
44 (17.27)
64 (20.59)
Q3 (RM1101–RM2009)
674 (16.66)
460 (18.99)
116 (15.32)
50 (13.89)
48 (12.05)
Q4 (RM2010–RM4000)
505 (14.70)
293 (13.69)
135 (16.42)
30 (11.70)
47 (15.49)
Q5 (RM4001–RM205690)
512 (16.79)
275 (13.75)
165 (20.84)
47 (31.55)
25 (7.63)
Strata
Urban
1850 (71.99)
922 (59.53)
655 (93.78)
176 (94.84)
97 (40.99)
Rural
1944 (28.01)
1507 (40.47)
163 (6.22)
56 (5.16)
218 (59.01)
Hospitalization
Yes
402 (11.15)
270 (12.84)
69 (9.10)
22 (8.51)
41 (11.93)
No
3388 (88.85)
2158 (87.16)
747 (90.90)
210 (91.49)
273 (88.07)
Out Patient Attendance
Yes
504 (13.38)
317 (13.71)
95 (11.06)
30 (13.24)
62 (19.88)
No
3286 (86.62)
2111 (86.29)
721 (88.94)
202 (86.76)
252 (80.12)
Diabetes Mellitus
Yes
1463 (38.05)
963 (40.88)
274 (34.00)
136 (56.02)
90 (26.99)
No
2327 (61.95)
1465 (59.12)
541 (66.00)
96 (43.98)
225 (73.01)
Table 2 demonstrates the prevalence of anaemia by sociodemography among the elderly population. The mean (±standard deviation) for haemoglobin levels for the ethnic Malays was 12.8 (±1.8) g/dl, the ethnic Chinese 13.0 (±1.8) g/dl, and the ethnic Indians 12.5 (±1.8) g/dl. The mean haemoglobin for the overall population was 12.8 (±1.8) g/dl. The overall prevalence of anaemia among all older persons was 35.3% (95% CI: 33.15, 37.45). The prevalence of anaemia for Malays, Chinese, Indians, and Others was 36.9 (95% CI: 34.0, 39.9), 31.1% (95% CI: 27.4, 35.1), 42.1% (95% CI: 33.9, 50.1), and 36.3% (95% CI: 30.2, 43.0), respectively. Univariate analyses revealed significant ethnic differences in the prevalence of anaemia. In addition, the sociodemographic factors including age, level of education, marital status, hospital admission in the previous 12 months, and diabetes all differed significantly. The prevalence of anaemia increases from 28% among men in the 60 to 64 years’ age group to 64% in men aged 80 years and over. In comparison, 35% of women aged 60–64 years had anaemia while 54% of women aged 80 years and over were anaemic (Figure 1).
Prevalence of anaemia by socio-demo characteristics among elderly (n=3566).
Anaemia
Variables
Yes
No
n
%
95% CI
n
%
95% CI
p value
lower
upper
lower
upper
Malaysia
1311
35.27
33.15
37.45
2245
64.73
62.55
66.85
Age
Mean, (SD)
69.98 (7.89)
-
-
-
67.86 (6.70)
-
-
-
<0.001
Ethnicity
Malays
852
36.92
34.03
39.91
1453
63.08
60.09
65.97
0.035
Chinese
238
31.10
27.37
35.10
483
68.90
64.90
72.63
Indians
101
42.07
33.91
50.69
121
57.93
49.31
66.09
Others
120
36.34
30.17
42.99
188
63.66
57.01
69.83
Gender
Male
581
32.85
30.06
35.77
1071
67.15
64.23
69.94
0.025
Female
730
37.57
34.54
40.70
1174
62.43
59.30
65.46
Level of Education
No Formal Education
315
40.21
35.86
44.72
436
59.79
55.28
64.14
0.010
Primary
688
35.75
32.77
38.85
1159
64.25
61.15
67.23
Secondary and higher
306
31.13
27.37
35.16
649
68.87
64.84
72.63
Marital Status
Married
832
33.36
30.91
35.92
1575
66.64
64.08
69.09
0.010
Currently Not Married
479
39.38
35.48
43.43
670
60.62
56.57
64.52
HH Income Group
Q1 (RM0–RM300)
446
34.69
31.23
38.32
696
65.31
61.68
68.77
0.715
Q2 (RM301–RM1100)
296
35.13
30.77
39.75
534
64.87
60.25
69.23
Q3 (RM1101–RM2009)
236
17.43
14.19
21.22
398
63.09
56.99
68.80
Q4 (RM2010–RM4000)
163
13.75
11.20
16.78
313
67.57
61.82
72.84
Q5 (RM4001–RM205690)
170
37.44
32.21
42.98
304
15.95
13.66
18.54
Strata
Urban
620
35.26
32.56
38.07
1080
64.74
61.93
67.44
0.996
Rural
691
35.28
32.29
38.38
1165
64.72
61.62
67.71
Hospitalization
Yes
188
16.96
13.61
20.94
189
8.23
6.67
10.12
<0.001
No
1122
32.96
30.86
35.13
2056
67.04
64.87
69.14
Out Patient Attendance
Yes
188
37.30
31.91
43.02
292
62.70
56.98
68.09
0.437
No
1122
34.88
32.55
37.28
1953
65.12
62.72
67.45
Diabetes Mellitus
Yes
569
38.64
35.21
42.20
835
61.36
57.80
64.79
0.011
No
742
33.09
30.49
35.79
1410
66.91
64.21
69.51
Bar chart comparing prevalence of anaemia by fiver-year age groups according to gender.
Multivariate analyses revealed that following adjustment for age differences, Malays were significantly more likely to be anaemic than Chinese respondents (adjusted odds ratio, aOR = 1.25; 95% CI = 1.04 to 1.49). Indians were also significantly more likely to be anaemic than Chinese respondents after age adjustment (aOR = 1.72; 95% CI = 1.26 to 2.34) (Model 1). In Model 2, following additional adjustment for hospitalization and diabetes mellitus, the Malays and Indians remained more likely to be anaemic than the Chinese (Table 3).
Multivariate analysis for factors associated with anaemia in Malaysian older adults in relation to ethnicity.
Wald Test
df
Adjusted OR
95% CI
p value
Lower
Upper
Model 1a
Ethnicity
13.06
3
0.005
Chinese
-
-
1.00
-
-
-
Malay
5.76
1
1.25
1.04
1.49
0.016∗
Indians
11.53
1
1.72
1.26
2.34
0.001∗∗
Others
4.03
1
1.33
1.01
1.76
0.045∗
Age
70.98
1
1.04
1.03
1.05
<0.001∗∗∗
Model 2b
Ethnicity
11.31
3
0.010∗
Chinese
-
-
1.00
-
-
-
Malay
4.71
1
1.22
1.02
1.46
0.030∗
Indians
10.00
1
1.66
1.21
2.27
0.002∗∗
Others
3.60
1
1.32
0.99
1.75
0.058
Age
80.82
1
1.05
1.04
1.06
<0.001∗∗∗
Hospitalization
Yes
20.91
1
1.67
1.34
2.08
<0.001∗∗∗
No
-
-
1.00
-
-
-
Diabetes Mellitus
Yes
10.29
1
1.26
1.10
1.46
0.001∗∗
No
-
-
1.00
-
-
-
aAdjusted for ethnicity, age, sex, strata, household income quintile, education and marital status; bAdjusted for ethnicity, age, diabetes, hospitalization, outpatient attendance; ∗p<0.05; ∗∗p<0.005; ∗∗∗p<0.0005.
4. Discussion
Utilizing data from a nationally representative cross-sectional survey, the elderly Malays and Indians were significantly more likely to have anaemia according to international criteria than the elderly Chinese. This study is continuation from the previous published article regarding anaemia in Malaysian adult population [12].
This was the first study to report ethnic differences in the prevalence of anaemia in an Asian population. Racial differences in anaemia prevalence have been reported in high income general populations or younger populations [13]. A previous study conducted in Singapore had included ethnicity as a variable in their study evaluating anaemia in patients with chronic kidney disease but found no ethnic differences in the prevalence of anaemia among the Chinese, Indian, and Malay populations [14]. However, this study was conducted among hospital patients and in a comparatively smaller population. A recent report on anaemia from the National Health and Nutritional Examination Survey (NHANES) in the United States revealed a much higher prevalence of anaemia among non-Hispanic blacks [15]. Anaemia in older adults, therefore, remains poorly characterized, with much more work being required before effective measures can be considered for this condition, which is likely to pose an increasing burden on society with the rapidly ageing population worldwide.
The prevalence of anaemia in the different ethnic groups in our older population was comparatively higher than that reported in the published literature. A previous systematic review had suggested an overall prevalence of 12% among community-dwelling older adults [6]. The prevalence of 31% to 46% among the different ethnic groups in Malaysia appears to be many folds higher than that reported in studies involving other older populations [16, 17]. The apparently higher prevalence of anaemia in our older population is therefore likely to reflect the higher prevalence of comorbidities especially diabetes mellitus and chronic kidney disease in our older population [9, 18]. In addition, the Asian ethnic groups are also far more likely to have inherited haemoglobinopathies such as thalassaemia minor which may escape clinical detection throughout life and with no known adverse effects on life expectancy [19]. The exact contribution of thalassaemia traits to anaemia in our population is yet to be established.
The higher prevalence of anaemia among our older Indian population is supported by the findings of a study on anaemia prevalence conducted within the Indian subcontinent [20], which utilized the hospital database at a single centre. Their estimated prevalence of over 50% for women of all ages and men aged over 60 years is, however, not comparable to that of our community-based sample. Normocytic anaemia was commonest among their older population suggesting that anaemia could be due to causes other than iron deficiency in their older population. Nevertheless, iron deficiency anaemia has been previously found to be associated with Indian ethnicity as many Hindu devotees are traditionally vegetarians [21, 22]. The bioavailability of vitamin B12 is known to be poor in the traditional Indian vegetarian diet [23].
In terms of nutritional deficiency, in addition to cultural beliefs and religious prohibitions, socioeconomic factors also contribute to nutritional intake as a high socioeconomic status is associated with food diversity and a healthier diet [24]. In general, anaemia is patterned by socioeconomic factors especially by household income whereby those living in the lowest wealth quintiles were found to have 25% higher than among those from the highest quintile [25]. A study done in China reported that a relatively lower risk of anaemia was associated with greater health awareness and a higher household income status [26]. A Singaporean study observed a higher risk of developing iron deficiency anaemia among non-Chinese ethnicities [27]. The aetiology underlying the ethnic differences in anaemia in our population could not be established in this cross-sectional survey. Previous reports have suggested that anaemia in older adults are more likely to occur due to chronic illness than nutritional deficiencies [28]. Following adjustment for hospitalization and the presence of diabetes in our study, however, the ethnic differences in anaemia status remained statistically significant. There is an established relationship between B12 deficiency and diabetes mellitus [27]. In addition, we consider hospitalization as a marker of frailty and medical illness and diabetes as an indicator of chronic disease [29]. Anaemia may also be more likely among those with diabetes due to the increased risk of renal disease [30, 31]. Both Malay and Indian ethnicities were strong independent risk factors for anaemia after the above adjustments, suggesting that the increased risk of anaemia among Indians is not explained by hospitalization nor diabetes. In a previous study involving diabetics in California, the presence of chronic disease accounted for one-third of cases of anaemia and ethnicity remained an independent predictor for anaemia in their diabetic population, for which underlying factors were yet to be established [32]. The absence of any mediators of anaemia in our study population therefore brings into question the likelihood of genetic predilection for anaemia. However, the prevalence of the commonest inherited blood dyscrasia among Asians, beta-thalassemia, has been evaluated among large populations in both China and India with similar prevalence of beta-thalassaemia status of around 3% [33, 34].
As this was a cross-sectional survey, causative relationships could not be established. Haemoglobin in this study was based on point-of-care screening which may lead to a falsely high haemoglobin result by 0.1 g/dL [35]. However, point-of-care screening provides fast and mostly valid results and was felt to be the most appropriate choice to allow for measurement of haemoglobin in remote settings [36]. As a consequence of our choice of measurement tool, there were no associated measurements on cell counts, mean corpuscular volume, haematocrit, or iron studies available. Therefore, it was not possible to determine the type of anaemia in our study population. In addition, as anaemia was assessed as part of a larger national health survey, it was not possible to also accurately assess coexisting medical illness, renal function, or use of medications in our study population. The low percentage of Indian in our population may reduce the accuracy of detection of anaemia in our population. Future studies should now evaluate further the rationale behind the increased risk of anaemia among the older Indians, the relatively higher prevalence of anaemia overall among our older population compared to other population studies, and aim to identify strategies to lower the burden of anaemia among our population, possibly through appropriate chronic disease management. To improve the characterization of anaemia in the ethnic Indians, a stratified sampling method should also be considered.
5. Conclusions
Our cross-sectional survey conducted in a multiethnic Asian population has found that both Indian and Malay ethnicities were independent predictors of the presence of anaemia. The differences in prevalence of anaemia in both ethnic Malays and Indians compared to the ethnic Chinese remain significant after adjustment for presence of diabetes and hospitalization in the past 12 months. Our study has identified a high prevalence of anaemia among all ethnic groups, as well as potential modifiable factors to reduce the burden of anaemia among our older population. Further studies should attempt to identify the underlying causes of this common condition among our older population.
Conflicts of Interest
All authors do not have any conflicts of interest.
Authors’ Contributions
All authors have participated actively in this study.
Acknowledgments
The authors wish to thank the Director General of Health Malaysia for his permission to publish this study. The authors also would like to acknowledge the NHMS steering committee for their technical support. Our appreciation is further extended to all staff involved throughout the study.
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