Primary objective of this review was to measure compliance with spectacle use in children with refractive errors. Secondary objective was to understand the reasons for non-compliance.
Methods
The databases searched were Ovid, EMBASE, CINAHL and Pubmed. All studies up to March, 2018 were included. The search terms were- ((((((Compliance [Title/Abstract]) OR Adherence [Title/Abstract]) OR Compliant [Title/Abstract]) OR Adherent [Title/Abstract])) AND (((Spectacle [Title/Abstract]) OR Spectacles [Title/Abstract]) OR Eye Glasses [Title/Abstract])) AND ((((Child [Title/Abstract]) OR Children [Title/Abstract]) OR Adolescent [Title/Abstract]) OR Adolescents [Title/Abstract]). Two researchers independently searched the databases and initial screening obtained 33 articles. The PRISMA guidelines were followed for conducting and writing the systematic review. Two reviewers assessed data quality independently using the Quality Assessment tool for systematic reviews of observational studies (QATSO). Poor quality studies were those, which had a score of less than 33% on the QATSO tool. Sensitivity analysis was done to determine if poor quality studies effected compliance. Galbraith plot was used to investigate statistical heterogeneity amongst studies. A random effects model was used to pool compliance.
Results
Twenty-three studies were included in the review, of which 20 were included in the quantitative analysis. All the studies were cross sectional. The overall compliance with spectacle use was 40.14% (95% CI- 32.78-47.50). The compliance varied from 9.84% (95% CI = 2.36–17.31) to 78.57% (95% CI = 68.96–88.18). The compliance derived in sensitivity analysis was 40.09%. Reasons for non-compliance were broken/lost spectacles, forgetfulness, and parental disapproval.
Conclusion
Appropriate remedial measures such as health education and strengthening vision care services will be required to address poor compliance with spectacle use among children.
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Abkürzungen
BCC
Behavior Change Communication
CI
Confidence Interval
GDP
Gross Domestic Product
HDI
Human Development Index
HIC
High Income Country
LIC
Low Income Country
LMIC
Lower Middle Income Country
MOOSE
Meta- analysis of Observational Studies in Epidemiology
PRISMA
Preferred Reporting Items for Systematic Reviews and Meta-analyses
RE
Refractive Error
SEAR
South East Asia Region
UMIC
Upper Middle Income Country
Background
Uncorrected refractive errors are a major cause of morbidity globally. Recent data shows that uncorrected refractive error is among the leading causes of moderate or severe vision impairment in the global population in 2015 [1].It is estimated that in developing countries, 7 to 31% of childhood blindness and visual impairment is avoidable [2]. In the age group of 5–15 years, nearly12.8 million (0.97% global prevalence) children are visually impaired due to uncorrected or unsatisfactorily corrected refractive errors [3].Theprojected cost of uncorrected refractive error (RE) described as direct and indirect loss of world productivity is 269 billion international dollars (I$) (US$ 202 billion), and the projected cost of addressing the issue is US$ 28 billion over 5 years [4, 5].Children suffering fromrefractive errors viz., myopia, amblyogenic hyperopia, astigmatism and anisometropia require appropriate treatment at the earliest [5, 6].Uncorrected refractive errors in children lead to poor academic growth, injuries, reduced social participation, and functional impairment [7].Correction of visual impairment with spectacles is the most cost-effective intervention for improving eye care and thus the productivity and functionality of children. Spectacles have a quality of being simple to use, non-invasive and inexpensive. However, the benefit of these visual aids depends on the compliance by end users.
A number of studies are available worldwide to look into the factors determining compliance with spectacle use [8‐27]. Studies have shown that the compliance with spectacle use in children with visual impairment due to REs is only one third or less [11, 16, 17, 19, 24]. Compliance remained low even when the spectacles were provided for free, and poorer rates were observed in older children [14, 18, 21, 23, 24]and children residing in rural areas [13, 15]. Poor follow up after school-based screenings, broken spectacles, loss, forgetfulness [9, 11, 13‐15, 17‐20, 23, 24, 27] parental and children’s perceptions [8, 11, 13, 15, 16, 18, 22‐24],peer pressure [9, 11, 14, 18, 19, 22, 24], safety concerns and the patient’s self-esteem are few of the reasons cited for poor compliance.
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Variable rates of compliance worldwide suggest that augmented attention is warranted, including investment in development and assessment of spectacle compliance interventions to assist in reducing complications associated with non-wear of spectacles. Based on literature review, we hypothesized that compliance with spectacle use would be low in children. The primary objective of the present review is to study the compliance with spectacle use in children with REs and to arrive at a summary measure of the rate of compliance by pooling data from various studies. The second objective was to assess the reasons for non-compliance in children with RE.
Methods
This systematic review was conducted in accordance with the Meta- analysis of Observational Studies in Epidemiology [28] (MOOSE) guidelines and the Preferred Reporting Items for Systematic Reviews and Meta-analyses standard (PRISMA) [ 29].
Literature search
An extensive search was conducted on published literature and efforts were made to acquire information about the unpublished literature from conference proceedings, unpublished research and from topic experts. The searches were performed on28th May, 2017 and were updated on 31st March, 2018 on the following databases: Ovid, EMBASE, CINAHL and Pubmed. A thorough search of title and abstract (tiab) using the key words was performed. We did MeSH terms screening along with use of Boolean operators. The search terms were-((((((Compliance [Title/Abstract]) OR Adherence [Title/Abstract]) OR Compliant [Title/Abstract]) OR Adherent [Title/Abstract])) AND (((Spectacle [Title/Abstract]) OR Spectacles [Title/Abstract]) OR Eye Glasses [Title/Abstract])) AND ((((Child [Title/Abstract]) OR Children [Title/Abstract]) OR Adolescent [Title/Abstract]) OR Adolescents [Title/Abstract]). Reference lists of articles retrieved in the initial step were screened for pertinent studies. Efforts were made to contact authors for articles, which could not be obtained. We also searched additional platforms like Google search for non-indexed studies.
Inclusion criteria
Observational and experimental study designs were included in the systematic review. These included cross sectional, case control and cohort study designs. Experimental study designs were also explored. Studies assessing compliance with spectacle use in children with REs, published in English language, with one or more of the key words in the title or abstract were included in the review. Compliance was defined as regular use of glasses prescribed for refractive errors including myopia, hypermetropia and astigmatism, assessed either by observation or by interviewing the children. Studies irrelevant to the objective of this review e.g. in children suffering from other eye disorders, conducted in adults, not published in English language were excluded from the review. The studies in which raw data were missing or unclear were excluded from quantitative analysis. We did not include conference proceedings. The participants comprised of children of both sexes with REs.
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Data extraction
The studies were independently reviewed by two researchers (N.D, S.D), performed a thorough search of the databases and screened titles and abstracts based on the research question, and population and outcome in terms of compliance with spectacle use.. Compliance was defined as regular use of glasses prescribed for refractive errors including myopia, hypermetropia and astigmatism, assessed either by observation or by interviewing the children. Based on the initial screening, full-text articles were obtained. Duplicates were removed in the initial stages. The third investigator (M.D) solved any disagreement in the selection of studies. Two reviewers conducted quality assessment independently using the QATSO tool used in previous studies [30‐32]. No significant difference was found in individual assessments of the reviewers. This study has been registered with PROSPERO, with registration number CRD42017068190.
Data analysis
The data were entered separately from the included studies in a pre-designed and piloted format that recorded the information about author name, country of study, date of publication, study design, number of children, duration of follow up, type of study, percentage compliance and reasons for non-compliance.
After extraction, all related data were entered into Microsoft Excel for compilation. The data were analyzed with STATA MP 12 v11 [33]. Pooled compliance estimate for spectacle use in children was generated using a forest plot. Compliance rates were calculated from raw proportions or percentages reported in the selected studies. The raw proportions/percentages were pooled using a random-effects model and pooled estimates and the 95% Confidence intervals (CI) were calculated. Correlation coefficient was calculated between per capita GDP expenditure and percentage expenditure on health with percentage compliance. In addition compliance was measured on basis of setting of the study i.e., whether the children were provided spectacles in screening settings in the field or in clinical setting. Sensitivity analysis was done to assess the effect of poor-quality studies on the overall compliance with spectacle use. Galbraith plot was used to investigate the statistical heterogeneity amongst the studies.
Results
Study characteristics
A total of 2452articles were retrieved, of which 33 articles met the study criteria for inclusion (Fig. 1). After construing the full text, we finally included 23 studies for the review (Table 1). We did not include data for pooled compliance estimate from three studies [8, 26, 34] as the proportion of children compliant with spectacle use was not available. However, descriptive data from these studies was included.
Fig. 1
Flow of selection of studies for the review
Table 1
Characteristics of selected studies included in systematic review and meta-analysis (N = 23)
S.
No
Authors
Country
Age
Year
Study Design
WHO Regiona
World Bank
Incomeb
Per capita GDP (2017
in $)
HDI
Expenditure on Health
(% of GDP)
Compliance
Measure
Type of prescription
Duration of Follow-up
Sample size
No.
Compliant (%)
1.
Narayanan A
et al
India
13–17 years
2017
Cross Sectional
(Qualitative)
SEAR
LMIC
1940
0.640
3.89
Questionnaire/ Interview based
No specific type
32
2.
Bhatt NK et al
India
6–15 years
2017
Cross Sectional
SEAR
LMIC
1940
0.640
3.89
Wearing spectacles on surprise visit
No specific type
3 months
200
78
(39.0)
3.
Anwar I et al
Pakistan
11–16 years
2017
Cross Sectional
EMR
LMIC
1548
0.562
2.69
Questionnaire/ Interview based
Myopia, hypermetropia, astigmatism and compound
8–12 months
440
180
(40.9)
4.
Kumar MR et al
India
6–17 years
2017
Cross Sectional
SEAR
LMIC
1940
0.640
3.89
Wearing spectacles on surprise visit
Children with visual acuity < 6/9
6 months
82
52
(63.4)
5.
Bhandari G et al
Nepal
5–16 years
2016
Cross Sectional
SEAR
LIC
835
0.574
6.15
Wearing spectacles on surprise visit or in bag
No specific type
No follow up
170
48
(28.2)
6.
Sumana M et al
India
9–16 years
2015
Cross sectional
SEAR
LMIC
1940
0.640
3.89
Wearing spectacles on surprise visit
No specific type
6 months
362
139
(38.4)
7.
Al Shamarti S et al
Iraq
Pre-school
2015
Cross Sectional
EMR
UMIC
5166
0.685
3.40
Questionnaire /Interview based
No specific type
Not mentioned
114
41
(35.9)
8.
Von-Bischhoffs-hausen FB et al
Chile
4–19 years
2014
Cross Sectional
AMR
HIC
15,346
0.843
8.07
Wearing spectacles on surprise visit
Visual Acuity 20/40 in either eye, myopia 0.75 diopters (D), 1.5D of astigmatism, or hyperopia.
12 months
204
121
(59.3)
9.
Pavithra MB et al
India
7–15 years
2014
Cross Sectional
SEAR
LMIC
1940
0.640
3.89
Wearing spectacles on surprise visit
Children with myopia ≥ −0.5 spherical equivalent diopters in one or both eyes, hypermetropia ≥ + 1.00 spherical equivalent diopters in one or both eyes and astigmatism ≥1.00 D
3 months
83
48
(57.8)
10.
Gogate P et al
India
8–16 years
2014
Cross Sectional
SEAR
LMIC
1940
0.640
3.89
Wearing spectacles on surprise visit followed by interview
myopia ≥ −0.50D or hyperopia ≥ + 1.00D
6–12 months
1018
300
(29.4)
11.
Aldebasi YH et al
Saudi Arabia
7–13 years
2013
Cross Sectional
EMR
HIC
20,761
0.853
5.83
Wearing spectacles on surprise visit or in bag
A child with myopia of more than −0.50 Dioptre (D) or hypermetropia of more than + 1.00D are prescribed spectacles
6 months
631
209
(33.1)
12.
Megbelayin EO et al
Nigeria
9–21 years
2013
Cross Sectional
(mixed methods)
AFR
LMIC
1969
0.532
3.56
Wearing spectacles on surprise visit
VA < 6/9 in at least one eye
No follow up
61
6
(9.8)
13.
Turcin LA et al
Romania
6–11 years
2013
Cross Sectional
EUR
UMIC
10,814
0.811
4.95
Wearing spectacles on surprise visit or in bag
Myopia (≥ − 1.00 DS in one or both eyes) Hyperopia (≥ + 1.50 DS in one or both eyes) Astigmatism (values ≥ 1.00 D)
12 months
315
82
(26)
14.
Messer DH et al
USA
8–14 years
2012
Cross Sectional
(mixed methods)
AMR
HIC
59,532
0.924
16.84
Wearing spectacles on surprise visit
Myopia ≥ −0.75 D, astigmatism ≥1.00 DC, and anisometropia ≥1 D and hyperopia ≥ + 2.50 D
3 months
247
82
(33.1)
15.
Keay L et al
China
12–15 years
2010
Cross Sectional
WPR
UMIC
8827
0.752
5.32
Wearing spectacles on surprise visit or in bag
No specific type
1 month
415
204
(49.1)
16.
Li L et al
China
14–18 years
2010
Cross sectional
(Qualitative)
WPR
UMIC
8827
0.752
5.32
Questionnaire/interview based
No specific type
28
17.
Khandekar R et al
India
School going
2008
Cross Sectional
SEAR
LMIC
1940
0.640
3.89
Questionnaire/ Interview based
Myopia (> 0.75 D spherical unilateral or bilateral)
3–4 months
70
55
(78.5)
18.
Congdon N et al
China
11.4–17.1 years
2008
Cross Sectional
WPR
UMIC
8827
0.752
5.32
Questionnaire/ Interview based
Uncorrected VA of 6/12 or worse and a 25% random sample of subjects with VA better than 6/12
No follow up
1892
713
(37.7)
19.
Li L et al
China
Average 14.7 years
2008
Cross Sectional
WPR
UMIC
8827
0.752
5.32
Questionnaire/ Interview based
All children with presenting VA 6/12 in either eye and children with spectacles improving vision to 6/12
3 months
210
55
(26.2)
20.
Odedra N et al
Tanzania
Average 14 years
2008
Cross Sectional
(mixed methods)
AFR
LIC
936
0.538
6.12
Wearing spectacles on surprise visit
VA worse than 6/12 in either eye or hyperopia of 2 diopters (D) or more
3 months
108
40
(37.0)
21.
Holguin AM et al
Mexico
6–18 years
2006
Cross Sectional
AMR
UMIC
8903
0.774
5.86
Wearing spectacles on surprise visit
Children with visual acuity 6/12 or less
4–18 months
493
66
(13.4)
22.
Khandekar R et al
Oman
6–17 years
2002
Cross Sectional
EMR
HIC
15,668
0.821
3.83
Wearing spectacles on surprise visit
No specific group
12 months
571
418
(73.2)
23.
Horwood AM et al
UK
1–7
years
1998
Cross Sectional
EUR
HIC
39,720
0.922
9.88
Questionnaire/ interview based
No specific group
Not mentioned
113
aSEAR South East Asia Region; EMR Eastern Mediterranean Region; WPR Western pacific region; AFR African region; AMR Region of the Americas
bUMIC Upper middle income country; LMIC lower middle income country; LIC Lower income country; HIC: High income country
Empty cells depict missing information
VA Visual acuity
×
All the 23 studies included were cross-sectional in nature. The studies are geographically diverse and covered 14 countries. Most (34.7%) of the studies were from South-East Asian region [8, 10‐12, 15, 19, 23],followed by Eastern Mediterranean region [9, 13, 18, 25] (17.4%). More number (39.1%) of studies was from lower-middle income country (LMIC) groups. The per capita GDP of the countries ranged from 835 USD for Nepal to 59,532 USD for USA. Percentage expenditure on health ranged from 2.69 for Pakistan to 16.84 for USA. In most studies, compliance with spectacles was defined if the child was wearing spectacles at the time of surprise visit by the investigators or had the spectacles in bag (65.2%). For a few studies compliance was defined by taking interviews of the children and asking questions regarding their patterns of spectacle use (34.8%). The prescription patterns varied across studies. Some studies used the cutoff of ≥ 0.5 Diopters for defining myopia and assessing compliance while a few defined myopia with a cut off of ≥ 1 Diopters. Similarly, for hyperopia the cut offs ranged from + 1.0 D to 2.5 Diopters. A few studies defined the prescriptions and cutoffs in terms of visual acuity and included children with visual acuity < 6/9 to < 6/12 across studies.
Population characteristics
The total number of children studied was 7859. The children enrolled were from all age groups ranging from preschool to end of school. The period of follow up ranged from ‘no follow up’ to follow up of 18 months. The variation in ages was vast and contributed to significant heterogeneity.
Quality assessment
The studies were assessed for the methodological quality based on the tool developed by Wong WC et al. [31, 32] Close to half (43.5%) of the studies were of good quality while 9 studies (39.1%) were of satisfactory quality and 4 studies (17.4%) were poor quality studies with score < 30%. The tool used for quality assessment is as shown in eTable 1 (supplementary file). The results of quality assessment of studies are attached as a supplementary file (eTable 2).
Compliance with spectacle use
The overall compliance with spectacle use was 40.14% (95% CI- 32.78-47.50) for 20 studies. The compliance varied from 9.84%(95% CI = 2.36–17.31) to 78.57%(95% CI = 68.96–88.18). Four studies had extreme values and their confidence intervals did not overlap those of other studies. Two of these studies reported very low compliance [16, 24] while 2 reported very high compliance 23, 25] with spectacle use. A forest plot of the studies and the compliance rate is as shown in Fig. 2. The compliance across almost all income groups was poor. The correlation coefficient for relationship between per capita GDP and percentage compliance was − 0.051, indicating a decrease in compliance with an increase in per capita income. However, this was not statistically significant (p = 0.830). Similarly, the correlation coefficient for relation between percentage expenditure on health and percentage compliance was − 0.238, indicating that an increase in percentage expenditure on health was associated with a decrease in compliance. This relationship also, was not statistically significant (p = 0.312). The prescription cut offs used for measuring compliance had an effect on the compliance pattern across studies. Based on the setting of the study the compliance was pooled for screening vs clinical care. It was observed that the compliance was 45.84% in the setting of clinical care and 39.33 in the setting of screening (eFig.1). This difference was not statistically significant. The method of measurement of compliance also varied across groups. A few studies used observation/ surprise visit as a measurement method while others used interviews/questionnaires for measurement of compliance. We grouped and analyzed the studies by compliance measure. The pooled compliance where observation was the method of measurement was 39.24% while the pooled compliance where interview was the method of measurement of compliance; the pooled compliance was 43.23% (eFig.2). This difference was not statistically significant, indicating that the measurement method did not significantly alter the compliance. A few studies that used a higher prescription cut off, reported better compliance as compared to studies that had lower cut offs for measurement of compliance, indicating lesser compliance at lower refractive errors. However most studies did not report any specific cut offs for prescriptions and some studies took cut offs using visual acuity, hence the pooled effect could not be observed.
Fig. 2
Compliance to Spectacle use (%) as reported by selected studies (N = 20)
×
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Sensitivity analysis and investigation for heterogeneity
Sensitivity analysis was done to know whether the poor quality studies [10, 12, 13, 17] had any effect on the overall compliance. The overall compliance with spectacle use did not vary significantly and was 40.09% when these studies were removed from the analysis. The forest plot excluding these studies is as shown in Fig. 3. The Galbraith plot (eFig.3) has shown that the studies had significant heterogeneity. The heterogeneity could be attributed to varying sample sizes and prescription cut offs (degree of refractive errors).
Fig. 3
Sensitivity analysis showing compliance to spectacle use (%) after removal of poor quality studies (N = 16)
×
Reasons for non-compliance with spectacle use
The most commonly cited reasons for non-compliance with spectacle use in the studies were broken [9‐12, 14, 15, 17‐20, 23, 24, 27]/lost spectacles [9‐12, 14, 15, 17‐20, 24, 27], forgetfulness [9‐11, 14, 15, 17‐19, 24, 27] and parental disapproval [8, 9, 11, 12, 15, 16, 18, 23, 24, 34]. These were followed by headache [10‐12, 15, 17, 23, 24, 27], teasing by peers [10, 12, 19]and dislike for spectacles [9, 14, 16‐23]. Other reasons mentioned in a few studies were use only when required [10, 12] unclear vision [11, 12, 22, 27, 34], unattractive frames/poor appearance [8, 34], fear of injuries [8, 34], lack of affordability [9, 12, 16], uncomfortable spectacles [18, 34] and negative attitude of the society [8, 15, 21](eFig.4). The reasons for non-compliance were pooled for different studies, and is as shown in the forest plots (Fig. 4(a-d). The reasons were broadly classified into personal factors, social factors, visual problems and breakage/loss/forgetfulness. The non-compliance due to personal factors was25.78% (Fig. 4a), for social factors it was 13.18% (Fig. 4b), visual problems/headache it was 5.47% (Fig. 4c) and for breakage/loss/forgetfulness it was 23.34% (Fig. 4d) of the total. The results clearly show that personal factors and breakage/loss/forgetfulness were the most commonly cited reasons for noncompliance.
Fig. 4
a Personal factors as a reason for non-compliance to spectacle use. b Social factors as a reason for non-compliance to spectacle use. c Visual problems/ headache as a reason for non-compliance to spectacle use. d Breakage/ loss/ forgetfulness as a reason for non-compliance to spectacle use
×
Discussion
The overall pooled estimate from twenty studies shows that the compliance with spectacle use is considerably low among children 40.14% (95% CI- 32.78-47.50), though the studies were heterogeneous. Majority of the studies were from South East Asia Region (SEAR) and lower middle-income countries. There was a dearth of studies from low-income countries, which could have altered the results and improved representativeness. The estimated compliance rate with spectacle was less than half (40.14%). Sub optimal compliance is a point of concern and can lead to progression of refractive errors. Negative, non significant correlation of percentage compliance with per capita GDP and percentage expenditure on health, suggests that apart from economic factors, psychosocial factors may be a contributor to compliance. It was observed that the setting (screening vs clinical care) and the method of assessing compliance (interview vs observation) did not have significant effect on the compliance. Although, pooled compliance in the clinical care setting where problem was identified by the child or family compared to vision screening setting provided at school was not significant, but the results point to of better compliance in clinical care setting, thus indicating that they are more likely to be aware and are motivated to use the spectacles. Personal, behavioral and cultural factors influence children’s compliance with spectacle use. The rate was less than half for most countries except a few which showed extremes on the lower and higher side. Compliance rate was overlapping between almost all studies except for two studies which reported a very high compliance [23, 25] and two that reported low compliance [16, 24]. In the study by Khandekaret al [23], the compliance may be high for two reasons. First, the sample size was small (77) that may have been a contributor to the difference in the compliance value from other studies. Second, the cut off for spectacle compliance was > 0.75D error, hence free glasses were given to children with higher refractive error, which itself is a factor for good compliance. In the study by Khandekar et al [25], the students were being assessed for compliance at regular intervals, thus improving the compliance rate. On the other hand, the reasons reported by Megbeylian et al [16] (2013) for poor compliance were lack of affordability and deep-rooted customs /traditions. In Nigeria, the expenditure on health as percentage of GDP and the HDI are low, which may be other contributory factors to affordability. The prescription cut offs for spectacle compliance assessment also varied across studies, though most studies did not report specific cut offs, a few showed that the compliance was poorer in children who had lower refractive errors as compared to children with higher refractive errors. Increased severity of refractive error warrants a stricter compliance to spectacle use as it hinders daily activities due to poor visibility. Some studies [14, 16, 19, 24, 27]reported better compliance in myopia as compared to hypermetropia. Recent study by Mc Cormick I et al. (2018) [35] also reported better compliance with higher refractive error in their study on determinants of compliance to spectacle use. Due to different definitions and cut offs we could not find an effect of these factors on the compliance as some studies have mentioned the prescription cut offs in terms of diopters while others have measured it in terms of visual acuity In addition the available data was also not uniform to be pooled together.
Identifying reasons for non-compliance with spectacle use is important for understanding the social determinants for intervention. The most commonly reported reasons for non-compliance were broken glasses [9‐12, 14, 15, 17‐20, 23, 24, 27], forgetfulness [9‐11, 14, 15, 17‐19, 24, 27], loss of spectacles [9‐12, 14, 15, 17‐20, 24, 27] and parental disapproval [8, 9, 11, 12, 15, 16, 18, 23, 24, 34].(Fig. 4 a- 4d) Addressing these issues by generating awareness is imperative.. The outcomes indicate more of socio cultural factors as major contributors to poor compliance that is commonly seen in Upper middle income countries. Any habit, if inculcated in the early years of life is bound to show results in adulthood. Most of the reasons identified for poor compliance are modifiable and are due to carelessness and poor encouragement of children. Breakage, loss and forgetfulness are intervention points that can bring substantial difference in the compliance rate. Parental disapproval is a significant contributor to child behavior. In many low and middle income countries, spectacles are considered a sign of weakness and their use hinders the process of finding a suitable match for the children when they reach adulthood. LASIK has been considered as a procedure for permanent removal of eyeglasses by surgical correction. Factors related to visual problems and headache can be addressed by modification of the prescription glasses and appropriate correction till comfort is achieved.
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Considering the fact that low compliance with spectacle use in children could result in detrimental outcomes, this issue requires necessary and urgent action. Unless social and perceptual barriers are overcome, the families will not access the financial and logistical assistance available to seek eye care for school-aged children. Behavior change communication (BCC) targeted at education and behavior change of parents, so they encourage children to use spectacles, is advocated. Another point of action could be school health programs, which should focus on incorporating the component of ensuring compliance through follow-up, apart from screening of children for refractive errors. Some potential actions that are recommended for the poor compliance found in our studyinclude, provision of spectacles to children at zero cost, facilitation of school vision screening programs by government and involvement of teachers in identification of non compliant children. Parental education and support are key pillars to strengthen the interventions. It is unlikely that uni-dimensional intervention approaches to increase follow up and spectacle adherence in the context of refractive errors (e.g., free spectacles) will be adequate to achieve sustained improvement in treatment outcomes among children. Positive reinforcement is essential at both the school and household levels. Generating awareness and glamourizing spectacles by using lightweight, unbreakable and trendy frames will promote their acceptance, especially in adolescent age groups. Lastly, the role of eye care practitioners is imperative in early identification, diagnosis and treatment of refractive errors among children, so as to curb the problem at a very nascent stage.
There are a number of strengths of this study. First, the present review is a first systematic review on spectacle compliance in children. No systematic review or meta-analysis has been conducted previously on this topic. Efforts have been made to include all the available studies on the topic. Secondly, no time restriction was imposed and we have obtained studies for all years. There are a few limitations of the study as well. Despite all our efforts to extract maximum number of studies, we may have missed relevant studies in unpublished literature (publication bias). Also, the number of studies obtained was mostly from middle-income countries and a clearer picture of influential factors from high income and low-income countries would not be made very clear.
Conclusions
In conclusion, this systematic review and meta-analysis has thrown light upon compliance with spectacle use and reasons poor compliance with spectacles which are a low cost intervention for refractive errors management in children. This issue needs to be addressed through behavioral motivation of children, parents and the society. This review can help stakeholders and program managers in defining health care interventions to improve compliance with spectacle use.
ICMR Centre for Advanced Research in Evidence Based Child Health, Advanced Pediatrics Centre, PGIMER for providing the support in the form of Software to carryout analysis and in searching the literature.
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Ethics approval and consent to participate
Not Applicable.
Consent for publication
Not Applicable.
Competing interests
The authors declare that they have no competing interests.
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Die Verwendung von Ophthalmika in der Schwangerschaft und Stillzeit stellt immer eine Off-label-Anwendung dar. Ein Einsatz von Arzneimitteln muss daher besonders sorgfältig auf sein Risiko-Nutzen-Verhältnis bewertet werden. In der vorliegenden …
Die endogene Endophthalmitis ist eine hämatogen fortgeleitete, bakterielle oder fungale Infektion, die über choroidale oder retinale Gefäße in den Augapfel eingeschwemmt wird [ 1 – 3 ]. Von dort infiltrieren die Keime in die Netzhaut, den …
Eine endogene Endophthalmitis stellt einen ophthalmologischen Notfall dar, der umgehender Diagnostik und Therapie bedarf. Es sollte mit geeigneten Methoden, wie beispielsweise dem Freiburger Endophthalmitis-Set, ein Keimnachweis erfolgen. Bei der …
Die bestmögliche Wundheilung der Kornea, insbesondere ohne die Ausbildung von lichtstreuenden Narben, ist oberstes Gebot, um einer dauerhaften Schädigung der Hornhaut frühzeitig entgegenzuwirken und die Funktion des Auges zu erhalten.
Update Augenheilkunde
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