Vision-Related Quality of Life among Patients Attending the Diabetes and Eye Clinics in Kenyatta National Hospital, Kenya

Emade, Nerice; Nyamori, Joseph; Njuguna, Margaret; Njambi, Lucy; Gichuhi, Stephen

doi:https://doi.org/10.1155/2023/7809692

Journal of Ophthalmology

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Abstract Introduction Materials and Methods Results Discussion Conclusion Data Availability Ethical Approval Consent Disclosure Conflicts of Interest Authors’ Contributions Acknowledgments Supplementary Materials References Copyright Related Articles

Research Article | Open Access

Volume 2023 | Article ID 7809692 | https://doi.org/10.1155/2023/7809692

Vision-Related Quality of Life among Patients Attending the Diabetes and Eye Clinics in Kenyatta National Hospital, Kenya

Nerice Emade,¹Joseph Nyamori,²Margaret Njuguna,²Lucy Njambi,²and Stephen Gichuhi³

Academic Editor: Alessandro Meduri

Received26 Jul 2022

Revised19 Dec 2022

Accepted30 Dec 2022

Published17 Jan 2023

Abstract

Importance. The increasing incidence of diabetes mellitus worldwide has resulted in an increase in microvascular complications such as diabetic retinopathy. Visual impairment, patients’ worries, and restrictions due to diabetes mellitus and diabetic retinopathy may affect patients’ quality of life. Objective. Our main objective was to determine the overall vision-related quality of life (VRQoL) among patients with diabetes mellitus attending the diabetes and eye clinics in Kenyatta National Hospital, Kenya. Design. Analytical cross-sectional study conducted in December 2020 setting: This study was performed at the Diabetes and Eye Clinics in Kenyatta National Hospital, the main national referral centre in Nairobi, Kenya. Participants. Using a purposive consecutive sampling method, we enrolled 100 participants, 50 with diabetic retinopathy and 50 without diabetic retinopathy. Main Outcomes and Measures. We compared the VRQoL of participants with diabetic retinopathy with those without diabetic retinopathy and assessed whether VRQoL worsened with increasing the severity of diabetic retinopathy. VRQoL was assessed using the World Health Organization/Prevention of Blindness and Deafness Vision Function-20 Questionnaire (VF-20). With this tool, the higher the mean score, the worse the quality of life. Diabetic retinopathy was graded using the Early Treatment of Diabetic Retinopathy Study. VRQoL trend with DR were analysed using the worse eye. Results. Participants with diabetic retinopathy had worse overall total VRQoL mean score (33.4, SD11.5) than those without (26.9, SD 4.7) in all domains; overall self-rating, 2.6 vs. 2.2, ; general functioning, 18.0 vs. 14.7, ; psychosocial, 6.7 vs. 5.3, ; and visual symptoms, 6.1 vs. 4.8, . VRQoL was worse with increasing severity of diabetic retinopathy in all domains moving from mild NPDR to moderate NPDR, severe NPDR and PDR, overall self-rating (2.2, 2.5, 3.5, 3.3; ); visual symptoms (5.6, 5.6, 7.5, 7.4; ); psychosocial (5.7, 6.5, 6.0 8.8; ); and general functioning (15.7, 16.9, 17.5 23.6; ). Presence of DR, distance vision impairment, and diabetic macula oedema were associated with low overall self-rating. Conclusion and Relevance. Our findings underscore the need for interventions for early detection and management of diabetic retinopathy to prevent developing more advanced DR and its associated deterioration of VRQoL.

1. Introduction

Diabetes mellitus (DM) is a significant cause of morbidity and mortality as well as increased health-system cost [1]. Between 1990 and 2010, the global prevalence of DM tripled, and the incidence doubled [2]. The proportion of people living with diabetes is projected to increase by about one-third between 2025 and 2030 in high-income countries [3, 4]. The 2015 Kenyan STEP Survey showed that the nation-wide prevalence of DM was 2.4%, which was close to the 2.2% reported by the International Diabetes Federation [5, 6]. Diabetes mellitus can lead to several ocular complications such as diabetic retinopathy(DR), diabetic papillopathy, glaucoma, cataract, and ocular surface diseases [7]. DR is the most common microvascular complication affecting all the small retinal vessels by causing an increase in vascular permeability, ocular haemorrhages, lipid exudate, and the development of new vessels on the retina [8]. Therefore, much attention has been given to expanding the role of the current treatments (intravitreal pharmacotherapies, photocoagulation, and pars plans vitrectomy) for DR along with introducing novel therapies [9]. Novel therapies, including intravitreal human mesenchymal stem cell and intraoperative cold irrigating eye balanced salt solution, are currently being evaluated for the management of diabetic retinopathy and diabetic macula oedema [10–12].

Globally, about one-third of patients with DM aged 50 years and above have DR while about 10% have vision-threatening DR [13, 14]. A population-based study conducted between 2007 and 2008 in Kenya among adults aged ≥50 years reported that the prevalence of DR was 36% [15]. A follow-up study of the same cohort in 2013 found that the cumulative incidence of DM among previously nondiabetic participants aged ≥50 years was 61 per 1000 while that of DR was 15.8 per 1000 among those without DM before and 224.7 per 1000 among those with known DM before [16]. The Global Burden of Disease Study estimated that, between 1990 and 2020, the number of people aged ≥50 years who were blind from DR increased by 50% while the age-standardized prevalence of blindness due to DR increased by 15%. In Sub-Saharan Africa, the corresponding figures were 17% and 26%, respectively [17].

Recently, researchers have noted the significant role of quality of life (QoL) in the management of diabetes. Most studies investigating DR and QoL are from high-income countries and the questionnaires designed accordingly. Thus, they are not usually appropriate for all populations.

Different studies from around the world published inconsistent results on the QoL among patients with diabetes. A study assessing the impact of diabetic complications on health-related QoL using the SF-36 QoL questionnaire noted that DR had no effect on patients’ QoL [18]. However, in a study aimed at assessing the effect of DR on QoL using the 26-domain retinopathy dependent QoL questionnaire, it was reported that vision loss due to DR had a significant impact on patients’ QoL [19]. A study conducted in India assessing health-related and vision-related quality of life among patients with DR using the National Eye Institute 25-Item Visual Function Questionnaire concluded that QoL was worse in DR than in non-DR patients [20].

Several studies have reported a reduction in the vision-related quality of life in persons with DM and DR. However, little is known about the QoL of diabetics and specifically DR patients in Sub-Saharan Africa as well as in Kenya. To fill this gap, our study sought to use the WHO-PBD/VF-20 questionnaire which has been reported to be superior to most VRQoL questionnaires because it considers the mental and social impact as well as the vision-related activities [21]. VF-20 addresses 20 aspects of visual function grouped into 11 dimensions and 4 subscales. The WHO-PBD/VF-20 questionnaire has been validated for use in Kenya [22].

Understanding the VRQoL maybe important in assisting clinicians to manage DM and DR patients from a holistic point of view as well as guide policy makers and other stakeholders including patient support groups on national comprehensive diabetes care. In this regard, our aim was to investigate the VRQoL among people living with diabetes attending the Diabetes and Eye Clinics at the Kenyatta National Hospital using the WHO-PBD/VF-20 questionnaire.

2. Materials and Methods

2.1. Study Setting and Design

Kenyatta National Hospital (KNH) is in Nairobi, and it is the main national referral centre. This study was performed at the Diabetes and Endocrinology Centre of Excellence (diabetes clinic) as well as at the Eye Clinic in KNH. The diabetes clinic has a catchment population of over 3000 and the eye clinic over 300. This was a hospital-based analytic cross-sectional study conducted from 1^st December to 31^st December 2020.

2.2. Sampling Strategy and Recruitment

The minimum sample size for this study was derived from a previous study conducted in Nakuru using WHO/PBD-VF-20 questionnaire validated for use in Kenya [22]. Eligible participants were defined as those with either type 1 or type 2 DM for at least 5 years from the time of diagnosis. Participants included were aged 18 years and above, with or without diabetic macular oedema. A purposive consecutive sampling method was used, and we recruited 102 participants. Excluded from this study were diabetic patients with mental illness, gestational diabetes, as well as those with other visually impairing ocular morbidities such as glaucoma, retinal vascular occlusions, and optic neuritis.

In the diabetes clinic, patients with DM and fundus photographs indicating no DR were enrolled; meanwhile, those with DR were referred to the eye clinic for confirmation of retinopathy by a vitreoretinal specialist before enrollment.

2.3. Data Collection

Participants’ blood pressure was measured upon arrival and their medical data on diabetes mellitus recorded from their files (duration of diabetes mellitus and latest glycated haemoglobin). The history of the course of microvascular complications such as the presence of hypertension was assessed. Best presenting visual acuity was determined for all participants using the E-charts for distant and near vision in a well-illuminated room. The distant E-charts were placed at 6 metres and the near E-charts at 40 cm.

In the eye clinic, slit-lamp examination was performed for all eligible participants to assess for the presence of cataract. Pharmacologic dilation of the participant’s pupil was done using one drop of tropicamide 1%. Slit-lamp biomicroscopy, with a 90 dioptres lens, was used to diagnose diabetic retinopathy and diabetic macular oedema, which was then confirmed by the vitreoretinal specialist. The presence of dry eye syndrome was also assessed for all participants in both clinics using Schirmer’s test strips and artificial tears only (Schirmer’s test 1).

In the eye clinic, following confirmation of the presence of diabetic retinopathy, grading for each eye was done using the Early Treatment Diabetic Retinopathy Study (ETDRS) grading system. We assumed that patients’ VRQoL will be driven by the worse eye with respect to diabetic retinopathy status. Diabetic macular oedema was defined as the presence of retinal thickening or hard exudates in the posterior pole within 500 mm of the fovea. Patients were with diabetes with any retinal thickening within 1/3 disc diameter (DD) of the centre of the macula, hard exudates within 1/3DD of the centre of macula with adjacent thickening, and retinal thickening ≥1DD of the centre of the macula.

In the diabetes clinic, all eligible participants had two fundus photographs taken per eye by a trained and validated technician using a nonmydriatic digital retinal camera (model CR-2AF). These images were digitally stored in a software. The assessment of cataract in this clinic was performed using the same camera. Participants were interviewed face-to-face by the principal investigator. Information was collected on demographic data, education, and employment status. For those who did not understand English, a translator was assigned to them. The WHO/PBD-VF-20 questionnaire was administered over a period of 15 minutes. We created a pictorial card illustrating scales 1 to 5 to help participants answer the WHO-PBD-VF-20 questionnaire.

2.4. Data Entry and Analysis

Data entry was done using Microsoft Excel and any inconsistency was corrected. Descriptive statistics was displayed using tables and figures. The descriptive data included the sociodemographic data, medical and ocular data, and VRQoL mean scores. Where data approximated a normal distribution, means and standard deviations were reported. Frequencies were reported with percentages and values. The results of the student t-test comparing the mean score VRQoL between those with DR to those without DR were displayed in the same table, and value <0.05 was considered statistically significant. We stratified the participants by degree of DR (using the ETDRS system) and tested for a linear trend of worsening VRQoL scores from baseline to the more advanced degrees of DR using the one-way ANOVA and post hoc tests. We conducted the analysis using the patient’s worse eye in order to assess the association between ETDRS grades and QoL scores. We performed a multivariate analysis for all patients’ overall eyesight rating adjusting for possible confounders such as age, sex, diabetic macula oedema, best presenting visual acuity, presence of cataract, dry eye syndrome, and duration of DM. The criteria used for explaining for good overall eyesight (mean score <3) and low overall eyesight (mean score ≥ 3) were based on the cut-off points for question 1 from the VFQ-20 questionnaire. Using the forward selection, a threshold of from univariate analysis was considered.

2.5. Ethics Statement

Ethical approval was obtained from the University of Nairobi Ethics and Research Committee, Kenyatta National Hospital (reference number: P356/07/2020), and the Kenyatta National Hospital administration. We obtained a written informed consent from all the participants. Participants and researchers’ safety was ensured by adhering to the COVID-19 measures. Participants with DR were referred to a vitreoretinal (VR) specialist for confirmation of diagnosis and treatment.

3. Results

We studied 100 participants, 50 with DR and 50 without DR. Among those with DR, only 12 participants were diagnosed with diabetic macule oedema (DME) (Figure 1). The mean age of participants with DR was 58.7 years and those without DR was 61.1 years (). Most participants with DM (61%) and DR (66%) were females (Table 1). HbA1c was documented in 59% of participants (Table 2). Among patients with DR, majority were diagnosed with mild NPDR and a minimum number with severe NPDR. Patients with sight-threatening diabetic retinopathy received treatment in the form of anti-VEGF, laser photocoagulation, and/or vitrectomy (see supplementary table).

The composite VRQoL mean score for participants with DR was 33.4 (SD 11.5) while that of participants without DR was 26.9 (SD 4.7). For all the domains, participants with DR had significantly worse (higher) mean scores than those without DR (Table 3).

The trends in VRQoL mean score among participants with DR with different ETDRS grades using the better and worse eyes were similar. Using the worse eye, the VRQoL mean scores for the 4 domains increased with advanced DR with PDR having the highest mean scores and mild NPDR the lowest. The overall self-rating eyesight mean score (SD) for participants with PDR was slightly higher than those with mild NPDR (3.3 [0.8]; 2.2[0.5]). The VRQoL mean score (SD) for general functioning was highest among participants with PDR when compared to those with mild NPDR (23.6 [12.4] vs. 15.7 [3.8]) (Figure 2).

Marital status, BPVA, presence of cataract, and dry eye syndrome had statistically significant association with the diabetic retinopathy status (Tables 1 and 2). On multivariate analysis, the presence of DR, distance vision impairment, and the presence of DME were statistically associated with low overall QoL among all participants (Table 4).

4. Discussion

In our study, we found that the overall vision-related quality of life (VRQoL) among patients with DR was significantly poorer than those without DR using VF-20 questionnaire. This result was evident in all the four subscales of the VF-20 questionnaire with general functioning being the most affected followed by psychosocial functioning and visual symptoms. Patients’ general vision perception was the least affected. Although our patients with DR perceived their overall eyesight as good, they still had difficulties in performing some daily activities. As regards patients’ psychosocial status, some were worried about losing their sight, being a burden to others and being hesitant to participate in social gatherings. Similar results were documented in a previous study in India [20]. In contrast to a study by Wolf et al, the DM patients even without DR did not have any significant difficulty in seeing different colours [23]. As regards visual symptoms, we explored perceived ocular discomfort and difficulty seeing because of glare from bright light. This ocular discomfort had a significant impact on daily life of patients with DR when compared to those without DR. Contrary to Polack et al., our participants were able to report a significant effect of glare on their vision [22]. This discrepancy could be due to variations in study population and settings.

We also found that VRQoL in the patient’s worse eye became poorer with increasing severity of the ETDRS grading. Using the better or the worse eye, patients with PDR had a significantly poorer perception of their general functioning followed by their psychosocial and visual symptoms. A study on the effect of DR and its severity on health-related quality of life in a population-based sample of Latinos with type 2 DM using the NEI VFQ-25 obtained similar results [24]. With the better eye, we noted that although the VRQoL again worsened with increasing severity, patients with no apparent DR had a poorer VRQoL when compared to those with mild NPDR. This was an unexpected, rare finding. In the multivariable analyses performed using general vision subscale as dependent variable in a binomial logistic regression model, higher mean scores were significantly associated with the presence of DR, distance vision impairment, and the presence of DME. Our results were comparable to those reported in a study conducted in India and in the USA, respectively, using the NEI VFQ-25 questionnaire [20, 23, 25].

Potential limitations of this study included patients’ undetermined psychological status including the fear of being infected with COVID-19 while answering the questions might have affected the accuracy of answers, but the researcher had no means to control it. It is also important to note that we could not assess the effect of HbA1c on patients’ perception of their general vision because of missing data in about a half of the patients.

5. Conclusion

In summary, quality of life was significantly lower in diabetics with DR when compared with those without DR with maximum effect seen on general functioning, psychosocial, visual symptoms, and general vision. Quality of life decreased with increasing severity of DR in the presence of DME and with distance vision impairment.

The results of this study are relevant because they demonstrate for the first time in our setting the negative influence of DR on patients’ overall quality of life. Health professionals should be aware that quality of life is one of the primary objectives of diabetes treatment. Apart from the benefits in terms of visual outcomes, early identification and treatment of patients with DR would have a positive impact on the different dimensions of the patient’s quality of life. However, the potential impact of the early diagnosis and treatment of DR on quality of life deserves the performance of specific intervention studies to address this issue. We also believe that there is a need for additional studies to conduct a linguistic and psychometric validation of new measures of quality of life and treatment satisfaction and to develop measurement tools that would allow the assessment of the impact of DR treatments on the patients in Kenya.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Ethical Approval

Ethical approval was obtained from the University of Nairobi Ethics and Research Committee, Kenyatta National Hospital (reference number: P356/07/2020), and the Kenyatta National Hospital administration.

The authors obtained a written informed consent from all the participants.

Disclosure

The abstract of this article was previously published in the University of Nairobi Research Archive in partial fulfilment of the authors’ postgraduate training in Ophthalmology. The contents of this manuscript are the responsibility of the authors and do not necessarily reflect the views of USAID or the US Government. The funding organizations had no role in the design and conduct of the study; collection, management, analysis, and interpretation of the data; preparation, review, or approval of the manuscript; and decision to submit the manuscript for publication.

Conflicts of Interest

The authors declare that they have no conflicts of interest. Nerice Emade was financially supported by Lions Hilfswerk Bayern Süd (LHBS), Germany, in carrying on this research project.

Authors’ Contributions

Emade and Gichuhi had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Emade, Nyamori, Njuguna, Njambi, and Gichuhi conceptualized and designed the study. Emade, Nyamori, Njuguna, Njambi, and Gichuhi acquired, analysed, and interpreted the data. Emade, Nyamori, Njuguna, Njambi, and Gichuhi wrote the original draft. Emade, Nyamori, Njuguna, Njambi, and Gichuhi did critical revision of the manuscript for important intellectual content. Emade and Gichuhi did statistical analysis. Emade, Nyamori, Njuguna, Njambi, and Gichuhi provided administrative, technical, or material support. Nyamori, Njuguna, Njambi, and Gichuhi supervised the study.

Acknowledgments

The authors acknowledge the study participants and staff of Kenyatta National Hospital Eye Clinics and the Diabetes and Endocrinology Centre of Excellence, in particular Mr. Reki for fundus photographs. This work was supported by the University of Nairobi’s Building Capacity for Writing Scientific Manuscripts (UANDISHI) Program at KAVI, Institute of Clinical Research, funded in part by IAVI, University of California, San Francisco’s International Traineeships in AIDS Prevention Studies (ITAPS, U.S. NIMH, R25MH123256), and the United States Agency for International Development (USAID). The full list of IAVI donors is available at https://www.iavi.org.

Supplementary Materials

The supplementary table describes the diabetic retinopathy status among patients attending the eye clinics using their better and worse eyes. As illustrated in the table, using the patient’s better or worse eyes, majority were found to have mild NPDR (44%) and a minimum number had severe NPDR (4%). Again, patients with sight-threatening diabetic retinopathy received treatment in the form of anti-VEGF (36.4%), laser photocoagulation + vitrectomy (18.1%), or anti-VEGF + laser photocoagulation (9.1%). (Supplementary Materials)

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Copyright © 2023 Nerice Emade et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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