Health-related quality of life in type 1 and type 2 diabetic patients in a Portuguese central public hospital.

BACKGROUND: Diabetes mellitus is a chronic metabolic disease, the prevalence of which has registered a considerable increase, mainly in adults and elderly. The purpose of this study was to assess the relationship between health-related quality of life in patients with diabetes and sex, body mass index, type of diabetes and treatment regimens (type 1 diabetes: intensive versus conventional treatment; type 2 diabetes: insulin use versus non-insulin use), and duration of diabetes.
METHODS: One hundred and twenty-four patients with diabetes were interviewed. Health-related quality of life was evaluated using the age-adjusted Short-Form 36 dimensions (physical functioning, role-physical, bodily pain, general health, vitality, social functioning, role-emotional, and mental health), and related to demographic and clinical variables. Independent samples t-tests and One-Way Analysis of Variance were used to compare means of independent samples. The degree of association between pairs of variables was measured by Pearson's (r) or Spearman's (rs ) correlation coefficients.
RESULTS: The mean age of the study population was 55.7±16.4 years; 54.8% were male, and 77.4% had type 2 diabetes. Females reported worse quality of life than males in all dimensions of the Short-Form 36, except for role-physical and bodily pain. Obese patients had worse physical functioning than normal weight and overweight patients, and worse vitality than their normal weight counterparts. Type 2 diabetic patients taking insulin had lower physical functioning and vitality than those without insulin therapy. Longer duration of diabetes was associated with lower physical functioning, role-physical, general health, vitality, role-emotional, and mental health.
CONCLUSION: Being female, obese, having type 2 diabetes and taking insulin, and having a longer disease duration are characteristics associated with worse age-adjusted quality of life in patients with diabetes.

Introduction

According to the International Diabetes Federation, the worldwide prevalence of adults with diabetes mellitus (DM) is 8.3%, accounting for approximately 382 million people.1 In the People’s Republic of China, the prevalence of DM in adults aged 20 years or older has increased to 9.7%, accounting for 92.4 million adults with DM.2 With regard to the association between family history risk categories and prevalence of DM in Chinese adults aged 20 years or older and living in the People’s Republic of China, the prevalence has reached 32.7%, 20.1%, and 8.4%, representing at least two generations and one generation of first-degree relatives with DM, and no first-degree relatives with DM, respectively.3

With the same tendency, the prevalence of type 2 DM has also increased sharply among Chinese immigrants in the USA, so a relevant and interesting conceptual model of type 2 DM self-management was designed and developed by a group of researchers from the People’s Republic of China and the USA for this specific group of individuals. This model has seven interrelated factors, ie, sociodemographic characteristics, behavioral and psychological characteristics, social support, linguistic barriers, cultural characteristics, type 2 DM self-management behaviors, and diabetes-related health outcomes (eg, health-related quality of life [HRQoL], HbA1c, blood pressure, and other cardiovascular risk factors), and postulates that the first five components have an influence on type 2 DM self-management, and that all factors except for the latter predict health outcomes.4 In Portugal, the prevalence of DM in people aged between 20 and 79 years has reached a worrying rate of 11.7%.5

HRQoL aggregates the individual’s subjective perception of physical, emotional, and social well-being,6–9 includes a cognitive and emotional component,9 and is becoming increasingly important for those providing health care for diabetic patients.10,11

Concerning the relationship between age, sex, body mass index (BMI), different treatment regimens of type 1 and type 2 patients, disease duration, and HRQoL in patients with DM, the studies have not been consistent, so it is important to evaluate the relationships between these factors and HRQoL.

To our knowledge, the research carried out in Portugal that evaluated the effect of certain demographic and clinical variables on HRQoL in patients with DM did not make the adjustment of HRQoL scores for age, despite the fact that they can mediate some of these relationships. Most studies have found that older age is related to worse HRQoL in DM patients.12–25 However, one study26 reported that older age of diabetic patients was related to better HRQoL, whereas Fal et al7 did not find a relationship between age and HRQoL. Other studies27–29 found that older age in diabetic patients was related to worse and better HRQoL in different dimensions. Diabetic males had better HRQoL12–14,16,21–24,29–32 than females. Nevertheless, some studies7,19,20,25,33 did not find any relationship between sex and HRQoL in diabetic patients.

Concerning the relationship between BMI and HRQoL in DM, most of the studies have shown that patients with higher BMI had worse HRQoL.16,20,21,23,28,34,35 However, Mier et al36 did not find a relationship between BMI and HRQoL in type 2 diabetic patients. As far as we know, there are no studies conducted in Portugal that have evaluated the relationship between HRQoL and BMI in individuals with DM. According to two meta-analyses of randomized controlled trials that studied the effect of weight loss on HRQoL, positive clinical changes in BMI do not always produce a gain in HRQoL.37,38

With regard to the relationship between type of DM and HRQoL, some studies22,39,40 found that type 2 DM was related to worse HRQoL than type 1 DM, while other authors30,41 found no relationship between type of DM and HRQoL. Trief et al27 found that type 2 DM was related to poor and better HRQoL in the different domains than type 1 DM. Another study33 found that patients with type 2 DM reported better HRQoL in one dimension of the Short-Form 36 than patients with type 1 DM, whereas in other dimensions of this generic tool assessing HRQoL, the two groups of patients did not differ.

Results of research on the relationship between treatment regimens in type 2 diabetic patients and HRQoL have found that insulin therapy was related to lower HRQoL.16,18,19,28,34,36,42 Nevertheless, two studies17,26 reported an absence of a relationship between type of therapeutic regimen in type 2 DM and HRQoL, while two studies7,33 found that patients with type 2 diabetes treated with insulin had poor and better HRQoL in the different domains than those receiving oral hypoglycemic agents.

Concerning the relationship between treatment regimens in type 1 DM and HRQoL, one study22 found that type 1 patients on a conventional insulin regimen reported worse HRQoL than those on an intensive insulin regimen. However, other study43 reported no relationship between treatment regimen in type 1 DM and HRQoL.

Finally, some studies looking at the relationship between duration of DM and HRQoL have shown that a longer duration of the disease was related to lower HRQoL;20,22,23,32,36 however, others7,12,16,26,33 found no relationship between diabetes duration and HRQoL, and one43 found that an increased duration of DM was related to better HRQoL.

In summary, studies that have investigated the relationship between demographic and medical variables have used a wide range of methods6 and questionnaires44 to assess HRQoL, and have covered different aspects of HRQoL. These differences may contribute to the discrepancy between study results, and undermines the discussion of our present results.

Given the discrepancies found in the literature, and the lack of studies assessing HRQoL in Portuguese diabetic patients, the aim of this cross-sectional study was to assess the relationship between HRQoL and age, sex, BMI, type of DM and treatment regimens, and duration of DM.

Subjects and methods

A consecutive sample of 124 patients from the Outpatient Department of Endocrinology, Diabetes and Metabolism, Centro Hospitalar São João, Porto, Portugal, was recruited. Patients were included in the study if they had a diagnosis of type 1 or type 2 DM, were at least 18 years old, and were not currently pregnant. The protocol for the study was approved by the Ethics Committee for Health at the Centro Hospitalar São João, and informed consent was obtained from all participants before participation in the study.

BMI was calculated from participants’ self-reported heights and weights. BMI was expressed as weight (in kilograms) divided by the square of height (in meters), and categorized according to the World Health Organization45 as “normal weight” (18.5–24.9 kg/m2), “overweight” (25–29.9 kg/m2), or “obesity” (≥30 kg/m2). Treatment regimens for type 1 DM were classified as “conventional treatment” (one or two daily administrations of insulin) or “intensive treatment” (at least three daily administrations of insulin). Type 2 DM patients were classified as on “oral hypoglycemic agents” or “insulin therapy” (the latter including patients only on insulin therapy or on oral hypoglycemic agents plus insulin therapy). Duration of DM was categorized as “less than 10 years”, “10–19 years”, or “20 years or more”.

One questionnaire was designed to collect demographic and clinical data. General HRQoL was assessed by the Portuguese version of the Medical Outcomes Study 36-Item Short-Form Health Survey (SF-36).46,47 The eight domains used to assess HRQoL in this analysis were: physical functioning, role-physical, bodily pain, general health, vitality, social functioning, role-emotional, and mental health. Raw dimension scores were transformed to scales ranging from 0 to 100, in which higher scores indicate higher HRQoL. Given the relationship between age and HRQoL, we adjusted our SF-36 results to the age of the participants; therefore, all other variables were related to the residuals of simple linear regression models having each dimension as a dependent variable and age as the independent variable. All questionnaires were administered by one of the researchers.

Statistical Package for the Social Sciences version 20.0 for Windows software (IBM Corporation, Armonk, NY, USA) was used for the analysis. Descriptive statistical analysis included calculation of means and standard deviations for cardinal variables, and frequencies for ordinal and nominal variables. Independent samples t-tests and One-Way Analysis of Variance were used to compare means of independent samples; when significant differences were observed using analysis of variance, we performed multiple comparisons for observed means using the Bonferroni correction. The degree of association between pairs of variables was measured by Pearson’s (r) or Spearman’s (r) correlation coefficients. Chi-square tests were used to determine the dependency between pairs of variables. Relationships were considered to be statistically significant at P<0.05.

Results

Demographic and diabetes-related data are presented in Table 1. We interviewed 124 patients with DM aged 18–80 years. Most patients were male, had type 2 DM, had had the disease for 10 years or more, and were overweight or obese. Table 2 summarizes the demographic and clinical characteristics of the patients. Women had the longest duration of DM and a higher prevalence of obesity. Type 2 patients and overweight patients were older than the other patients.

Table 1

Demographic and clinical characteristics of patients

Sex
Male n (%)	68 (54.8)
Female n (%)	56 (45.2)
Age (years)
Whole sample, mean (SD)	55.7 (16.4)
Type 1 DM, mean (SD)	32.8 (13.9)
Type 2 DM, mean (SD)	62.4 (9.6)
Type of treatment regimens
Type 1 DM conventional treatment n (%)	14 (11.3)
Type 1 DM intensive treatment n (%)	14 (11.3)
Type 2 DM without insulin therapy n (%)	50 (40.3)
Type 2 DM on insulin therapy n (%)	46 (37.1)
Duration of DM (years)
<10, n (%)	47 (37.9)
10–19, n (%)	39 (31.5)
≥20, n (%)	38 (30.6)
Body mass index category (kg/m2)
18.5≤BMI,25.0, n (%)	34 (27.4)
25.0≤BMI,30.0, n (%)	46 (37.1)
BMI≥30.0, n (%)	44 (35.5)

Abbreviations: DM, diabetes mellitus; SD, standard deviation.

Table 2

Relationships between demographic and clinical characteristics of patients

	Sex			Age
	Male	Female	P-value	Mean (SD)	P-value
	n (% within sex)	n (% within sex)
Type of treatment regimens
Type 1 DM conventional treatment (n=14)	7 (10.3)	7 (12.5)	0.070	39.5 (14.9)a*	<0.001
Type 1 DM intensive treatment (n=14)	8 (11.8)	6 (10.7)		26.1 (9.0)b*
Type 2 DM without insulin therapy (n=50)	34 (50.0)	16 (28.6)		62.2 (9.8)c*
Type 2 DM on insulin therapy (n=46)	19 (27.9)	27 (48.2)		62.7 (9.5)c*
Duration of DM (years)
<10 (n=47)	34 (50.0)	13 (23.2)	0.009	56.3 (16.3)	0.251
10–19 (n=39)	18 (26.5)	21 (37.5)		52.4 (17.4)
≥20 (n=38)	16 (23.5)	22 (39.3)		58.5 (15.2)
Body mass index (kg/m2)
18.5≤BMI<25.0 (n=34)	19 (27.9)	15 (26.8)	0.013	43.8 (20.7)a*	<0.001
25.0≤BMI<30.0 (n=46)	32 (47.1)	14 (25.0)		60.7 (12.2)b*
BMI≥30.0 (n=44)	17 (25.0)	27 (48.2)		59.8 (11.4)b*

Note:

Presence of the same letter (a,b,c) in superscript indicates absence of significant differences in post hoc tests.

Abbreviations: DM, diabetes mellitus; SD, standard deviation.

The average values obtained by patients in the eight dimensions of the SF-36 are shown in Table 3, as well the relationship between these scores and age. There was an association between age and six of the eight dimensions of the SF-36: increased age was associated with worse HRQoL in terms of physical functioning, role-physical, bodily pain, vitality, social functioning, and role-emotional. Physical functioning was the dimension showing the strongest relationship with age.

Table 3

Health-related quality of life in patients with DM and its association with age

SF-36 dimensions	Percent	Association with age
	Mean (SD)	r (P-value)
Physical functioning	41.9 (37.1)	−0.536 (<0.001)
Role-physical	39.3 (48.6)	−0.286 (0.001)
Bodily pain	45.1 (33.8)	−0.312 (<0.001)
General health	46.6 (17.5)	−0.150 (0.097)
Vitality	46.0 (26.6)	−0.199 (0.027)
Social functioning	57.4 (28.2)	−0.270 (0.002)
Role-emotional	61.8 (48.0)	−0.269 (0.003)
Mental health	51.9 (24.5)	−0.146 (0.105)

Note: r, Pearson’s correlation coefficient.

Abbreviations: DM, diabetes mellitus; SF-36, Medical Outcomes Study 36-Item Short-Form Health Survey; SD, standard deviation.

The age-adjusted scores of HRQoL by sex are shown in Table 4, BMI class in Table 5, and type of DM and treatment regimens in Table 6.

Table 4

Health-related quality of life in patients with diabetes mellitus and their sex

SF-36 dimensions (adjusted for age)	Sex
	Male	Female	P-value
	Mean (SD)	Mean (SD)
Physical functioning	11.2 (33.7)	−13.6 (21.6)	<0.001
Role-physical	6.9 (47.2)	−8.4 (44.8)	0.067
Bodily pain	5.0 (31.9)	−6.1 (31.6)	0.054
General health	3.2 (15.5)	−3.9 (18.6)	0.022
Vitality	6.5 (28.1)	−7.9 (21.0)	0.001
Social functioning	7.2 (25.2)	−8.7 (27.1)	<0.001
Role-emotional	14.1 (43.0)	−17.2 (44.6)	<0.001
Mental health	5.8 (23.5)	−7.0 (23.3)	0.003

Abbreviations: SF-36, Medical Outcomes Study 36-Item Short-Form Health Survey; SD, standard deviation.

Table 5

Health-related quality of life in patients with diabetes mellitus and body mass index

SF-36 dimensions (adjusted for age)	Body mass index category (kg/m2)
	18.5≤BMI<25.0	25.0≤BMI<30.0	BMI≥30.0	P-value
	Mean (SD)	Mean (SD)	Mean (SD)
Physical functioning	7.9 (29.3)a*	8.0 (34.9)a*	−14.4 (23.4)b*	<0.001
Role-physical	1.6 (50.0)	−6.9 (42.1)	−1.8 (47.6)	0.203
Bodily pain	3.6 (29.5)	1.3 (33.7)	−4.2 (32.6)	0.540
General health	1.1 (14.9)	0.9 (17.6)	−1.8 (18.8)	0.703
Vitality	6.9 (26.1)a*	2.3 (25.4)a,b*	−7.8 (25.3)b*	0.034
Social functioning	2.9 (30.1)	3.6 (26.2)	−6.1 (25.2)	0.182
Role-emotional	6.3 (39.1)	2.2 (48.2)	−7.2 (49.3)	0.414
Mental health	6.9 (21.2)	−3.4 (22.9)	−1.8 (27.0)	0.143

Note:

Presence of the same letter (a,b) in superscript indicates absence of significant differences in post hoc tests.

Abbreviations: SF-36, Medical Outcomes Study 36-Item Short-Form Health Survey; SD, standard deviation.

Table 6

Health-related quality of life and type of diabetes mellitus and treatment regimens

SF-36 dimensions (adjusted for age)	Type 1 diabetes mellitus		Type 2 diabetes mellitus		P-value
	Conventional	Intensive	Without insulin	With insulin
	Mean (SD)	Mean (SD)	Mean (SD)	Mean (SD)
Physical functioning	1.0 (36.4)a,b*	10.4 (14.9)a,b*	7.2 (34.2)a*	−11.3 (27.3)b*	0.016
Role-physical	−10.2 (56.0)	12.3 (39.4)	8.2 (48.2)	−9.5 (42.4)	0.163
Bodily pain	4.8 (33.3)	15.1 (20.0)	−1.8 (33.9)	−4.1 (32.1)	0.231
General health	−1.7 (18.1)	8.4 (13.6)	1.7 (17.6)	−4.0 (17.0)	0.093
Vitality	−0.5 (28.7)a,b*	9.4 (23.3)a,b*	6.2 (26.2)a*	−9.4 (23.6)b*	0.012
Social functioning	7.4 (31.1)	7.4 (23.7)	1.4 (25.8)	−6.0 (27.9)	0.214
Role-emotional	11.1 (37.5)	2.9 (28.6)	4.6 (48.1)	−9.2 (50.3)	0.367
Mental health	4.8 (27.6)	8.2 (17.9)	0.6 (23.7)	−4.6 (25.1)	0.282

Note:

Presence of the same letter (a,b) in superscript indicates absence of significant differences in post hoc tests.

Abbreviations: SF-36, Medical Outcomes Study 36-Item Short-Form Health Survey; SD, standard deviation.

Diabetic women had worse HRQoL in terms of physical functioning, general health, vitality, social functioning, role-emotional, and mental health than men, and evidenced a tendency in the same direction in terms of role-physical and bodily pain.

Obese patients had lower HRQoL in terms of physical functioning when compared with normal and overweight patients, and reported worse vitality than normal weight patients.

Type 2 patients on insulin therapy had worse physical functioning and vitality than type 2 patients only on oral hypoglycemic agents. Globally, type 2 patients taking insulin tended to show poorer HRQoL than patients in other treatment regimens, except in terms of role-physical. Intensively treated type 1 patients tended to have better HRQoL than patients on other treatment regimens, except in terms of social functioning and role-emotional.

An increased duration of DM (measured according to the categories presented in Table 1) was associated with lower HRQoL in terms of physical functioning (r =−0.271, P=0.002), role-physical (r =−0.209, P=0.020), general health (r =−0.372, P<0.001), vitality (r =−0.312, P<0.001), role-emotional (r =−0.224, P=0.012), and mental health (r =−0.197, P=0.028). In terms of social functioning, there was a tendency in the same direction; however, it did not reach statistical significance (r =−0.160, P=0.077). Regarding bodily pain dimension, it seemed to exist no relationship with duration of disease (r =−0.045, P=0.621).

Discussion

Demographic and clinical variables in patients with DM were related to HRQoL, regardless of age. Globally, we highlight physical functioning and vitality as the dimensions more related to these variables. The adjustment of SF-36 scores for age may obscure relationships between several clinical variables and HRQoL dimensions that strongly depend on a concomitant relationship with age. Therefore, absolute scores on the SF-36 and their relationship with clinical variables may have clinical usefulness, but to analyze their direct effect on HRQoL, which was our intention, it is recommended that values are adjusted for age.

Our results showed that being female was related to worse HRQoL in terms of physical functioning, general health, vitality, social functioning, role-emotional, and mental health, and a tendency in the same direction in terms of role-physical and bodily pain. These findings are partially in agreement with those of Kleefstra et al, Neves et al, and Papadopoulos et al,21–23 who found that diabetic females reported, respectively: lower HRQoL in all dimensions of SF-36 with the exception of the general health dimension; in physical functioning, bodily pain, vitality, and mental health of SF-36; and in all dimensions of the aforementioned instrument. Conversely, some studies7,19,20,25,33 found no relationship between sex and HRQoL. Different explanations for the worse HRQoL of women with DM have been presented: females have an increased risk of developing cardiovascular disease,48 being hypertensive, obese, having more symptoms related to hyperglycemia,49 presenting higher prevalence rates of depression,31,50 anxiety, having less energy,31 and presenting greater difficulty in doing physical exercise,50 and this factor may lead to worse HRQoL, particularly in some dimensions. An alternative explanation may be the fact that women find themselves overburdened with several competing demands, such as their commitments toward their closest relatives, as well as with their jobs and household activities, whereas men are more concentrated in their paid jobs, which may contribute to greater physical and psychological overload.51 These above-mentioned sex patterns with regard to work roles were observed across countries. It is worth noticing that in our study women showed the longest duration of DM and a higher prevalence of obesity, which may act as confounders contributing to the worse HRQoL. On the other hand, the relationships between age and some clinical variables, namely the type of DM and BMI, highlight the relevance of age-adjustment to the HRQoL scores.

Although Mier et al36 reported no relationship between obesity in type 2 DM and HRQoL, we found that obese patients assessed their HRQoL as being worse than normal and overweight individuals in terms of physical functioning. It was previously shown that an increasing BMI in type 2 DM was related to lower physical functioning,20,21,23,34 as well as in worse HRQoL in other dimensions of the SF-36: role-physical,20,21 bodily pain,21 general health,34 social functioning,21,34 and role-emotional.20 We also emphasize that obese patients had lower vitality than their normal weight counterparts. However, as far as we know, we found no study reporting that obese diabetic patients had worse HRQoL in this particular dimension in comparison with normal and overweight ones. A possible explanation for the worse physical functioning and vitality in obese patients may be related to the coexistence of hypertension or other chronic morbidities in this group of patients.

While Wexler et al and Caldwell et al17,26 did not observe any relationship between treatment regimens in type 2 DM and HRQoL, we observed that insulin therapy in type 2 DM was related to lower scores on the physical functioning dimension compared with those who were on oral hypoglycemic agents, in accordance with previous research.18,19,34 Moreover, Johnson et al19 reported that insulin use in type 2 DM was related to worse HRQoL in terms of role-physical, general health, and social functioning. Interestingly, Fal et al7 observed that patients with type 2 diabetes on insulin therapy had worse HRQoL in the somatic and environmental domains and better HRQoL in the psychological domain than those receiving oral hypoglycemic agents. Additionally, we found that type 2 diabetic patients treated with insulin showed poorer vitality than type 2 patients not treated with insulin therapy. Nevertheless, to our knowledge, there are no studies reporting that insulin use is related to worse HRQoL for this specific dimension in type 2 diabetic patients. Different explanations have been put forward by various authors to explain the lower HRQoL in patients requiring insulin to achieve better metabolic control: the side effects of the medication and its influence on scheduling and organizing their daily activities,7 the fear of weight gain, and concerns about the impact of the insulin regimen on their social environment.52 Alternative explanations for these findings in such patients may be the longer duration of the disease, a sense of frustration after failure of oral medications, or the onset of diabetes-related complications and subsequent necessity to start insulin. Patients commonly held erroneous and irrational beliefs about the relationship of the need of insulin therapy and the development of chronic complications of DM. Subcutaneous insulin injection is also often considered as an intrusive regimen by patients. These hypotheses should be tested in future research, on the one hand using larger samples allowing multivariate analysis, and on the other hand by qualitative studies focusing on the personal representations of different features of treatment regimens.

In our study, there were no differences on any of the HRQoL dimensions between type 1 patients on a conventional regimen and those on an intensive insulin regimen, which is consistent with the results obtained by Eiser et al43 but different from the findings of Neves et al,22 who found better HRQoL in terms of physical functioning and vitality in type 1 patients on an intensive insulin regimen. Eventually, the absence of differences in terms of HRQoL between insulin treatment regimens in type 1 DM may be related to the small number of patients interviewed.

Some studies did not find a relationship between duration of diabetes and HRQoL in type 2 DM7,12,16,26,33 or in type 1 DM,33 and another study43 reported better HRQoL in terms of diabetes satisfaction with increasing duration of the disease in young adults with type 1 DM. In contrast, across both type 1 and type 2 patient groups, we found a negative association between duration of diabetes and HRQoL in terms of physical functioning, role-physical, general health, vitality, role-emotional and mental health, and a tendency in the same direction in terms of social functioning. These results, on one hand, are partially overlapping with the findings of Neves et al,22 since in that study an increased duration of DM was related to lower HRQoL in all dimensions of the SF-36, but on the other hand partially agree with the findings of Kalda et al, Papadopoulos et al, and Mier et al,20,23,36 who found that a longer duration of diabetes was related to worse general health, vitality, social functioning,20,23 bodily pain,23 mental health,20 and physical component.36 Possible explanations for this reduction in HRQoL for diabetic patients with a longer duration of disease may be related to the sharp decrease of energy, vitality, and social relationships, the development of long-term complications of DM in the later stages of the disease, and consequently to the intensification and complexity of the treatment regimen.20 It is worth noticing that, by comparing age-adjusted HRQoL scores, the relationship found between duration of diabetes and HRQoL is not due to the older age of patients, but to the longer duration of DM.

The difference in the results between this study and others may be explained, on the one hand, by the different generic tools used to assess HRQoL, which do not measure exactly the same dimensions, and by the fact that some studies have evaluated only type 1 or type 2 diabetic patients, whereas in the present study both types of patients were included. Given the frequent age difference between patients with type 1 diabetes and those with type 2 diabetes, and due to the fact that not all studies make the age-adjustment of the values of the generic instruments to assess HRQoL for this variable, we highlight the implications for clinical practice when HRQoL is evaluated considering age-adjusted values.

Several limitations of this study should be considered when interpreting its results. The results would be more robust with a larger sample. Further, most of the patients interviewed were of low sociocultural status, which may have limited their understanding of the questions in the instrument used to assess HRQoL. Generalization of our findings may be limited because our sample was collected in a central public hospital and might not be representative of the diabetic population in other care centers or in primary care. Further investigations are warranted to adjust the dimensions of HRQoL to other variables (eg, sex, BMI, type of DM and treatment regimens, and disease duration) to explore the relationships between HRQoL and the demographic and clinical variables considered, we think may explain some of these relationships. Further studies are needed to explore the relationships between demographic and clinical variables. As previously stated, the use of qualitative methodology could be useful to obtain information complementary to that achieved by quantitative studies, allowing more accurate interpretation of some results. Finally, participants’ self-reported duration of diabetes, and height and weight values when calculating BMI might not be as reliable as measurements taken from official medical records.

One of the main points of our results is the relationship found between the vitality dimension of the SF-36 and obesity and insulin use in patients with type 2 DM. To our knowledge, there are no studies providing such data (ie, reporting the negative impact of these two factors on this specific dimension of HRQoL), which seems worthy of exploring further. Apart from the reasons previously stated, adjusting HRQoL values for age is important, since type 1 patients are significantly younger than those with type 2 diabetes, and our analysis allowed us to analyze and compare these two groups without the confounding effect of age.

Conclusion

Our findings suggest that being female, obese, having type 2 DM and taking insulin, and having diabetes for a longer period of time are characteristics associated with worse age-adjusted HRQoL in patients with DM. Globally, physical functioning and vitality were the dimensions more related to these demographic and clinical variables.