Some clinical and epidemiological studies have suggested that Alzheimer’s Disease (AD) and cataract, may share common pathogenetic mechanisms, subsequently a positive association between the prevalence of AD and cataract, although other studies found no significant relationship between dementia and visual impairment including cataract in the elderly. Little is known about the association between Activity of Daily Living (ADL) and the combination of AD and cataract. To examine the association between ADL and the combination of AD and cataract, we performed a national survey in nursing care institutions in Japan, examining the decreased ADL in elderly with and without AD and cataract for 453 elderly aged 85.0 ± 8.13 years. The proportion, 43.5% of AD in subjects without cataract was significantly higher than that, 23.5% with cataract. Almost all ADL in AD with cataract was significantly lower than that without cataract, although all ADL in cataract patients receiving surgery in AD was significantly (all p < 0.002) higher than that in cataract patients without surgery in AD, as was confirmed by the multiple regression analysis incorporating into the relevant factors as independent variables. These results showed that ADL scores including cognitive functions decreased by cataract were increased by the surgery in the patients with AD. A significantly negative association between AD and cataract seen in our data, which was inconsistent with the previous result, might lead to the necessities of the clinical diagnosis for slight severity of cataract for patients with AD.
Alzheimer’s Disease Cataract Elderly Activity of Daily Living Cognitive Function1. Introduction
Alzheimer’s Disease (AD) is the most common form of dementia. The number of individuals with AD has been increasing considerably in recent years, accounting for more than 50% of dementia cases [1] . AD causes the cognitive impairment of elderly in need of care, consequently interfering with daily tasks and decreasing Activities of Daily Living (ADL) in many ways [2] . Although epidemiologic studies have shown many risk factors such as occupational exposures (exposure to pesticides, electromagnetic fields, organic solvents and volatile anesthetics), pre-existing medical conditions (cerebrovascular disease, hypertension, diabetes, dyslipidemia, traumatic brain injury, depression and cancer) and lifestyle factors (smoking, consumptions of alcohol and coffee, body mass index, physical activity and cognitive activity) as non-genetic etiology of AD [3] [4] , the accurate involvements of the occupational, pre-existing medical conditions and lifestyle factors in the development of AD remain to be elucidated.
It is estimated that there are 39 million blind persons and that cataract is the first cause of blindness worldwide [5] . Epidemiological studies have shown that smoking, diabetes mellitus, asthma, chronic bronchitis, cardiovascular disease, exposure to UVB light and corticosteroids use would increase cataract risk [6] [7] . Furthermore, over the last few years, clinical and epidemiological studies have suggested that dementia and visual impairment, in particular AD and cataract, may share common pathogenetic mechanisms [8] - [10] . Age-related vision impairment has been found to be closely associated with cognitive and behavioral manifestations [11] . Some epidemiologic studies also have demonstrated a positive association between AD and cataract [12] - [14] . Nevertheless, other studies found no significant relationship between cognitive impairment and vision loss including cataract in the elderly [15] [16] . In addition to the inconsistent studies on the association between AD and cataract, little is known about the association between Activity of Daily Living (ADL) and the combination of AD and cataract [17] .
Both AD and cataract which increase with the aging deteriorate ADL and subsequently require nursing care [18] - [20] . To examine the association between ADL and the combination of AD and cataract, we performed a national survey in nursing care institutions in Japan, examining the decreased ADL in elderly with and without AD and cataract.
2. Methods
Fifty facilities were randomly selected out of 3410 nursing care institutions in Japan. Five resident patients and 5 daycare patients were sampled at random from each facility. A total of 500 patients without cerebral infarction, cerebral and subarachnoid hemorrhage were prospective subjects in this study. We mailed a questionnaire to a chief medical doctor in charge of each facility and subjects inquiring about ADL and medical conditions, including AD and cataract, as described below and obtained 453 responses (90.6%, 273 resident patients and 180 daycare patients). This survey was conducted from 2010 to 2012. The average age and SD of the 453 subjects were 85.0 and 8.13 years old. This research was conducted after obtaining approval from the ethical committee of the Japan Association of Geriatric Health Service Facilities.
The questionnaires regarding medical conditions in subjects were related to AD and cataract with and without surgery. To examine AD, the questions concerned neuropsychological examinations including the patients’ medical history, neurological testing, Mini-Mental State Examination [21] , and standard clinical evaluation including brain scanning. In the diagnostic process, we used DSM-IV-TR and ruled out other factors. The National Institute of Neurological and Communicative Disorders and Stroke-Alzheimer’s Disease and Related Disorders Association guidelines [22] were used for detection and diagnosis of either possible or probable AD, and stage of dementia according to the Clinical Dementia Rating (CDR) Scale [23] . We categorized as AD all those with CDR scale scores of 0.5 or higher also meeting the criteria for probable or possible AD. Cataract was diagnosed according to the International Classification of Diseases (ICD), 10th Revision (H25) by family practice medical doctor. Diabetes mellitus was diagnosis according to Japan Diabetes Society clinical diagnosis guideline by family practice medical doctor [24] . The diagnoses of AD and cataract were performed within one year prior to the contact with nursing care institutions for elderly in this study. Our subjects included 125 patients with possible or probable AD, 253 and 108 patients with cataract treated with surgery and conservatively, respectively, and 52 elderly without AD or cataract.
Regarding ADL, the questions were developed on the basis of a standard described previously [19] [25] and [26] . They dealt with bed mobility, transfer and locomotion, cognitive function (orientation), cognitive function (communication), cognitive function (mental activity), eating (swallowing), eating (feeding), toilet use, and bathing for elderly requiring both residential nursing care systems and those for daycare. Each ADL was categorized into a five-point scale. In the case of bed mobility, for example, a score of 5 represents being able to stand on one’s feet and maintain this posture; score 4: having difficulty maintaining a standing posture, but being able to transfer from one place to another in a sitting position; score 3: being unable to move in a sitting position, but being able to sit in a proper posture without support; score 2: having difficulty sitting in an upright posture, but being able to turn over on a bed; and score 1: not being able to turn over on a bed. In the case of eating (feeding), a score of 5 represents being able to eat well without any support of others; score 4: spilling food during eating; score 3: having difficulty eating by themselves, but being able to eat with support for their posture and position of the dish; score 2: being unable to eat without complete support; and score 1: being unable to eat with any support (receiving tube feeding). Thus, the requirement for more concentrated nursing care during eating for the elderly decreased the ADL score. A lower score for each ADL implies worse ADL. In Table 1, we show ADL and prevalence of AD, cataract treated with surgery, and cataract treated conservatively according to the status of nursing care (residential and daycare).
Pearson’s correlation coefficients of age showed weak but significant associations with bed mobility (−0.154), transfer and locomotion (−0.222), cognitive function (orientation) (−0.207), cognitive function (communication) (−0.161), cognitive function (mental activity) (−0.191), eating (dysphagia) (−0.176), eating (feeding) (−0.105), toilet use (−0.161), and bathing (−0.112). Because of significant differences in proportions in terms of the sex and age between elderly with and without diseases in addition to significant correlations between age and ADL scores, we compared each ADL score by analysis of covariance (ANCOVA) with age and sex as covariants, in which age was assigned as a continuous variable and sex were dummy-coded with follows: male 0, female 1. Mean ADL score and standard deviation adjusted by age and sex were calculated using regression coefficients corresponding to age, sex, and disease obtained by ANCOVA and raw mean values of age and sex in total subjects. To assess the interaction for ADL score between the combination of AD and cataract treated with or with- out surgery, we used two-way ANCOVA with age and sex as covariants. To confirm the results of ANCOVA, we performed multiple regression analysis for each ADL score incorporating into facility, sex, age, DM, cataract surgery, and Clinical Dementia Rating (CDR) scale as independent variables. The statistical software SPSS ver. 21 was used. P-values less than 5% with two tails were considered statistically significant.
3. Results
Table 1 shows numbers (proportion) and age of residential or day care users with and/or without cataract and AD in this study. The proportion, 43.5% of AD in subjects without cataract were significantly higher than that, 23.5% with cataract (Chi square test, p < 0.000). The proportions of woman using residential was significantly higher than that using day care. The proportions, 85.5% of women in subjects with AD were significantly higher than that, 66.1% without AD (p = 0.000). The proportions, 69.6% of women without cataract was significant lower than that, 79.5% with cataract, respectively (p = 0.042) (Table 1).
Table 2 shows that ADL adjusted by age and sex according to AD and cataract. The two-way ANCOVA showed statistically significant main effects of AD on ADL scores of cognitive functions including orientation,
Numbers (proportion) and age of residential or day care users with and/or without cataract and AD in this study
Facility
Cataract
AD
Proportion of women (%)
Age (years; mean ± SD)
Residential
(−) 53
(−) 23
17 (73.9)
87.13 ± 8.45
(+) 30
23 (76.7)
84.90 ± 6.06
(+) 220
(−) 151
132 (87.4)
86.78 ± 7.97
(+) 69
60 (87.3)
86.55 ± 7.49
Day care
(−) 39
(−) 29
15 (51.7)
77.83 ± 10.45
(+) 10
9 (90.0)
81.50 ± 6.50
(+) 141
(−) 125
84 (67.2)
83.65 ± 7.56
(+) 16
11 (68.8)
84.25 ± 6.98
Statistics (p value)
Facility
ns
0.000
0.000
0.000
Cataract
-
0.000
0.042
0.010
AD
-
-
ns
ns
The proportions of AD in subjects without and with cataract showed 43.5% and 23.5%, respectively (p < 0.000). The proportion of women using residential and day use showed 85.5% and 66.1%, respectively (p < 0.000). The proportion of women without and with cataract were 69.6% and 79.5%, respectively (p = 0.042).
communication and mental activity, eating including swallow and feeding, toilet use and bathing in addition to significant main effects of cataract on all ADL scores but bating. Furthermore, there were significant interactive effects of AD and cataract on ADL of transfer and locomotion, cognitive functions including orientation and communication, and toilet use (Table 2).
Age and sex-adjusted ADL in 361 cataract subjects with and without AD and surgery against cataract are shown in Table 3. There were statistically significant main effects of AD on ADL scores of cognitive functions including orientation, communication and mental activity in addition to significant main effects of surgery on all ADL scores. Furthermore, there were significant interactive effects of AD and surgery on ADL of transfer and locomotion (Table 3). Of 276 cataract subjects without AD, 228 (82.61%) received cataract surgery, whereas only 25 (29.41%) cataract surgery with AD of 85 cataract subjects, which difference in ratio of receiving surgery between patients with and without AD was recognized to be statistically significant by Chi-square test (p < 0.001).
Table 4 shows results on multiple regression analysis for each ADL score using facility, sex, age, DM, cataract surgery, and CDR score as independent variables in 356 subjects with cataract. Cataract surgery was statistically positively associated with ADL score of bed mobility, cognitive function (orientation), cognitive function (communication), cognitive function (mental activity) and toilet use. CDR was statistically negatively associated with all ADL scores but transfer and locomotion. There was no association of DM with any ADL score examined in this study (Table 4).
To summary these results, almost all ADL in AD with cataract was significantly lower than those without cataract, although all ADL in cataract patients receiving surgery in AD was significantly higher than those in cataract patients without surgery in AD, as was confirmed by the multiple regression analysis incorporating into the relevant factors as independent variables.
4. Discussion
The present study showed a higher prevalence of AD in subjects without cataract than those with cataract, demonstrating a significant negative association between AD and cataract. On the contrary, recent population studies have demonstrated a significant positive relationship between AD and cataract. Mandas et al. [27] , who analyzed data from 1168 subjects aged 65years or older admitted between 2006 and 2013 to the outpatients clinic of the geriatric care unit at the University of Cagliari and to the one at Santissima Trinità Hospital in Cagliari, showed a relationships between mild cognitive impairment, various forms of age-related dementia (Alzheimer’s
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