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The psychological impact of instrumental activities of daily living on people with simulated age-related macular degeneration

Published online by Cambridge University Press:  08 August 2022

Anne Macnamara*
Affiliation:
Cognitive Ageing & Impairment Neurosciences Laboratory, UniSA Justice & Society, University of South Australia, Australia
Scott Coussens
Affiliation:
Cognitive Ageing & Impairment Neurosciences Laboratory, UniSA Justice & Society, University of South Australia, Australia
Celia Chen
Affiliation:
Department of Ophthalmology, Flinders Medical Centre, Flinders University, Australia
Victor R. Schinazi
Affiliation:
Department of Psychology, Faculty of Society & Design, Bond University, Australia; and Future Health Technologies, Singapore-ETH Centre, Campus for Research Excellence and Technological Enterprise (CREATE), Singapore
Tobias Loetscher
Affiliation:
Cognitive Ageing & Impairment Neurosciences Laboratory, UniSA Justice & Society, University of South Australia, Australia
*
Correspondence: Anne Macnamara. Email: [email protected]
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Abstract

Background

People with age-related macular degeneration (AMD) can report reduced mental health. There is also evidence that they struggle with daily tasks because of vision loss.

Aims

The purpose of this study was to assess the psychological impact of instrumental activities of daily living on people with simulated AMD.

Method

Twenty-four normally sighted participants completed 12 household tasks, in a simulated home environment, under a moderate-to-severe AMD simulation. Participants’ psychological state was measured through self-report questionnaires and physiological measurements related to anxiety and stress. Tasks were completed twice, under counterbalanced vision conditions (normal and simulated AMD).

Results

Linear mixed models on vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) revealed a significant large negative effect of the AMD simulation on time to complete tasks, and the anxiety, task engagement and distress self-reports (all P < 0.024, all ω2 > 0.177). There were also significant medium-large effects of trial order on time, task incompletion, task errors, and the anxiety and task engagement self-reports (all P < 0.047, all ω2 > 0.130), whereby the results improved during the second attempt at the tasks. No physiological measures were significant (all P > 0.05).

Conclusions

Completing instrumental activities of daily living under an AMD simulation had a negative impact on participants’ self-reported mental state. The observed trial order effects also illuminated how practice with tasks could ease anxiety and stress over time.

Type
Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of the Royal College of Psychiatrists

Age-related macular degeneration

The prevalence of mental health problems (e.g. depression, anxiety) is higher in visually impaired people than normally sighted samples.Reference van der Aa, Comijs, Penninx, van Rens and van Nispen1,Reference Le, Nguyen, Vu, Dao, Olson and Zhang2 Within the visually impaired, those with age-related macular degeneration (AMD) were shown to have greater declines in psychological well-being than those with other visual impairments.Reference Pinquart and Pfeiffer3 The pronounced declines may be attributed to AMD's progressive nature and limited treatability.Reference Pinquart and Pfeiffer3,Reference Berman and Brodaty4

The defining characteristic of AMD is the deterioration of part of the retina (the macula), which leads to gradual loss of central vision.Reference Mitchell, Liew, Gopinath and Wong5 Central vision loss leaves people with AMD vulnerable to harm as they become disadvantaged at detecting surrounding hazards.Reference Black and Wood6 Indeed, Wood et alReference Wood, Lacherez, Black, Cole, Boon and Kerr7 found that 74% of a patient group with AMD reported at least one fall or injury over the course of a year, with 30% reporting two or more falls. The stress of potentially hurting oneself can also precipitate fear toward engaging in daily activities, leading to dependence, social isolation and consequently, a reduction in mental health.Reference van Landingham, Massof, Chan, Friedman and Ramulu8,Reference Legters9

Simulating vision loss

A challenge in isolating the psychological effects of vision loss are the comorbidities typically found in AMD. Visual impairments disproportionally affect older adults, and those with vision loss are subject to significantly more physical and mental comorbidities (e.g. stroke, hearing loss, dementia) than those without.Reference Court, McLean, Guthrie, Mercer and Smith10 One approach to circumvent these issues is to simulate AMD conditions in normally sighted participants. This strategy enables the disentanglement of specific vison-related effects on behaviours from other age-related declines and comorbid factors.

However, simulation techniques should be employed cautiously. As visual decline, particularly for AMD, typically occurs progressively, patients can learn compensatory strategies (i.e. peripheral retinal locus or eccentric fixation) to adapt to vision loss.Reference Macnamara, Chen, Schinazi, Saredakis and Loetscher11,Reference Walsh and Liu12 Such strategies may not be developed during a short-term simulation study. Moreover, a scotoma moves synchronously with a person's eye, whereas the scotoma in many simulations are stable.Reference Macnamara, Chen, Schinazi, Saredakis and Loetscher11 As such, simulations can never fully replicate life with AMD, and may even underestimate the true effect of vision loss.Reference Butt, Crossland, West, Orr and Rubin13 Nonetheless, findings of simulation research generally mimic behaviours exhibited in studies on patients with AMD.Reference Macnamara, Chen, Schinazi, Saredakis and Loetscher11 For example, reduced reading speed resulting from AMD has been identified in both simulation and patient studies.Reference Ho, Boffa and Palanker14,Reference Varadaraj, Lesche, Ramulu and Swenor15 Therefore, an AMD simulation will, at a minimum, provide preliminary insights into the impact of visual impairment on everyday life.

Impact of activities of daily living

It is well established that visually impaired populations can struggle with activities of daily living, such as walking, recognising faces and driving.Reference Mitchell, Liew, Gopinath and Wong5,Reference Taylor, Hobby, Binns and Crabb16 Studies assessing how AMD affects instrumental activities of daily living have typically confirmed this through objective measures of task performance (i.e. accuracy, errors, time),Reference Copolillo, Christopher and Lyons17,Reference Pardhan, Latham, Tabrett and Timmis18 but fewer studies have explored the implications of living with AMD from a psychological and physiological perspective. Of the studies that have examined mental health, many findings have been based upon reflective self-reports via longitudinal prospective cohort studies or retrospective case–control studies.Reference Le, Nguyen, Vu, Dao, Olson and Zhang2,Reference Heesterbeek, van der Aa, van Rens, Twisk and van Nispen19 Measuring a person's psychological response to everyday tasks has been relatively overlooked in a visual impairment context. However, previous research demonstrates that linking psychological and physiological data is possible,Reference Grantcharov, Boillat, Elkabany, Wac and Rivas20Reference Martens, Antley, Freeman, Slater, Harrison and Tunbridge23 and could therefore be utilised to measure the combined impact of AMD on everyday tasks.

An analysis of the functional status in over 750 patients with AMD identified an increased risk of functional disability for instrumental activities of daily living, like housework.Reference Gopinath, Liew, Burlutsky and Mitchell24,Reference Hochberg, Maul, Chan, Van Landingham, Ferrucci and Friedman25 Moreover, a study on daily tasks found that over twice as many patients with AMD reported needing help with housework, or being unable to complete housework even with help, compared with a control group.Reference Hochberg, Maul, Chan, Van Landingham, Ferrucci and Friedman25 There is currently a gap in the literature regarding the psychological state of those with AMD during housework. Despite the familiarity that any person has with such tasks, it should not be presumed that housework may not still be a large source of unacknowledged distress. Visually impaired people have described the additional energy and focus required to undertake tasks with low vision as mentally fatiguing.Reference Bakker, Steultjens and Price26 Therefore, even when ordinary tasks (i.e. folding towels) have little risk of causing physical harm, they could still negatively contribute to a person's mental health.

Consequently, this study will investigate the short-term psychological and physiological impact of completing instrumental activities of daily living (i.e. housework) in a simulated home environment – with bedrooms, kitchen and living areas. Utilising a real-world environment will be fundamental in generating ecologically valid responses. We hypothesise that participants completing instrumental activities of daily living under an AMD simulation will incur greater psychological and physiological distress than without the simulation.

Method

Participants

Participants were recruited by means of advertisements at the University of South Australia. The recruitment criteria included competent English-speaking adults aged 18 years and above, with no history of visual impairments and corrected visual acuity better than 6/18 (Snellen acuity chart). The use of a normally sighted population helped to trial the feasibility of the study before potentially expanding the research into clinical populations. During eligibility screening, potential participants were asked if they had any psychiatric disorders or cognitive impairments. A formal cognitive or medical history assessment was not made at this point. Final eligibility was dependent on participants fitting into a Hexoskin,27 a biometric shirt used to collect physiological data. Participants were also subject to COVID-19 requirements (e.g. symptom checks and high-risk health category restrictions) as instituted by the University of South Australia. The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008. All procedures involving human participants were approved by the University of South Australia's Human Research Ethics Committee (protocol 2028089). Written informed consent was obtained from all participants; and they were offered $30 as honorarium for their participation.

Apparatus and measures

Simulated vision goggles

A moderately severe AMD impairment was simulated via Fork in the Road macular degeneration simulator goggles (see Fig. 1;28). Two layers of 20 mm diameter circular Bangerter occlusion foils of 0.1 LogUnit (resulting in 6/60 vision) were then added to create a 10° central scotoma monocularly in both eyes. These were placed in the inner central region of each lens. A neuro-ophthalmologist calibrated the goggles to verify that the visual effect reliably reflected 6/60 best corrected visual acuity in either eye. The scotoma was verified with Zeiss Humphry 24-2 automated visual field analyser (Carl Zeiss Meditec Inc., Jena, Germany).

Fig. 1 Picture of cutlery taken through the simulated AMD vision and normal vision goggles. (a) Example of simulated AMD vision. (b) Example of normal vision. AMD, age-related macular degeneration.

Normal vision goggles

The same Fork in the Road macular degeneration simulator goggles28 were utilised. Except, the elements used for creating the AMD visual effect were removed from the goggles, leaving only a clear lens. Therefore, the normal vision goggles were not intended to alter participant's vision at all. The use of the goggles in both conditions ensured equity in wearing the goggle frames (i.e. weight, comfort, shape, same level of restricted peripheral vision).

Activities of daily living

The study was conducted at the University of South Australia's Sleep and Chronobiology Laboratory (see Fig. 2), which emulates a house environment. This study used three of the bedrooms, the hallway, living room and kitchen, to allow participants to engage in instrumental activities of daily living.

Fig. 2 Sleep and Chronobiology Laboratory. The Sleep and Chronobiology Laboratory is within the MC building at Magill Campus, University of South Australia. From left to right/up to down: the rooms used in the study included the living room and kitchen (35 m2), hallway (18.9 m2) and bedrooms (11.4 m2 each).

Twelve tasks that required mobility around the laboratory and visual discrimination of objects (e.g. colour and texture) were developed (see Table 1). Each set of tasks was completed twice, using the normal and simulated AMD goggles.

Table 1 Instructions for the 12 instrumental activities of daily living

To reduce the impact of practice effects between the normal and simulated AMD conditions, there were two versions of the location of the materials and two versions of the instructions. As illustrated in Fig. 3, the location of materials within the laboratory could differ by finding an item under a bedroom desk versus by the bedroom door. This forced participants to visually search for items during the second task set instead of relying on their previous exposure. Likewise, the task instructions could differ by colour or material item (see Supplementary Appendix 1 available at https://doi.org/10.1192/bjo.2022.558 for alternative instructions). For example, ‘Fold the three black towels … ’ versus ‘Fold the three pink towels … ’; or ‘Arrange the animal picture cards … ’ versus ‘Arrange the Uno number cards … ’. Once again, this required participants to apply visual discrimination during the task sets. Although the order of vision condition (i.e. normal vision completed first or second) was counterbalanced between participants, the material locations and task instructions were randomised to minimise learning effects.

Fig. 3 Alterantive material locations. (a) Example of the alternative locations of the DVDs in each bedroom. (b) Example of the alternative locations of the pillows in the hallway.

Performance measures

Two task performance measures were interpreted from the Hexoskin. This included the time taken from the start of the first task until the end of the last task, and the number of steps. An increase in either measure was inferred as reduced task performance, because it suggested participants put greater effort into completing the task (e.g. more time spent searching for an item because of disrupted vision). The researcher also noted two observational measures during the testing session: task incompletion (whether the task was completed) and task errors (how many errors were made during the task). Task errors included any deviation from the specific instruction (e.g. missed materials, collecting incorrect coloured materials, moving to incorrect locations). Increased difficulty completing the task would be indicated by increased task incompletion and more task errors.

Psychological measures

The State–Trait Anxiety Inventory (STAI) and the Short Stress State Questionnaire (SSSQ) are two self-report questionnaires administered to capture anxiety and stress, respectively. In terms of the STAI, only the State form was used; a 20-item scale examining the presence and severity of current symptoms of anxiety.Reference Spielberger, Gorsuch, Lushene, Vagg and Jacobs29 The higher the score, the greater the presence of anxiety. The STAI-State has good internal consistency: α = 0.86–0.95.Reference Spielberger, Gorsuch, Lushene, Vagg and Jacobs29

The SSSQ is a 24-item measure comprising three subscales: worry (cognitive interference and self-regulation), task engagement (motivation and task focus) and distress (negative affect and mood). Higher worry and distress scores, and lower task engagement scores suggest the presence of stress. The SSSQ has good internal consistency in each domain: α = 0.84, α = 0.81 and α = 0.87, respectively.Reference Helton30

Physiological measures

Recordings were collected with a Hexoskin biometric shirt.27 There were eight Hexoskin shirts available representing different sizes (one S and XXL, as well as two each for M, L and XL). The shirt comprises electrocardiogram, respiratory inductive plethysmography and accelerometer sensors, to compute cardiac (sampling rate: 256 Hz), respiratory (128 Hz) and activity (64 Hz) data, respectively. The sensors were embedded within the shirt, across the thorax and navel regions. This recording method was unobtrusive and comfortably worn by participants under their clothing. The data was saved to a recording device fitted within the shirt during testing. The device was removed post-testing, and data was uploaded to the Hexoskin Online Dashboard. Use of the Hexoskin in this manner has been validated by similar studies.Reference Grantcharov, Boillat, Elkabany, Wac and Rivas20,Reference Al Sayed, Vinches and Halle31

Debriefing

Participants were asked simple follow-up questions upon completion of the experiment to subjectively ascertain which vision condition (normal, simulated AMD or neither) was more difficult and triggered greater anxiety or stress.

Procedure

Participants acclimated to the vision goggles before the main task by completing two cognitive tasks under each condition (normal and simulated AMD; results reported in Macnamara et alReference Macnamara, Schinazi, Chen, Coussens and Loetscher32). This adaptation period lasted approximately 30 mins.

As outlined in Fig. 4, the subsequent main experiment was split into two task blocks, with the psychological questionnaires administered before, during and after the instrumental activities of daily living tasks. During the first block of tasks, participants wore either the normal or simulated AMD goggles to complete the tasks. During the subsequent second block, the tasks were repeated under the alternative vision condition. Participants could wear prescription glasses beneath the goggles, if required.

Fig. 4 Study procedure. AMD, age-related macular degeneration; SSSQ, Short Stress State Questionnaire; STAI, State–Trait Anxiety Inventory.

Within each experimental task block, participants completed the 12 tasks (see Table 1). These were split into a further four sub-blocks (three tasks per block) for ease of remembering the required tasks. At the start of each sub-block, the researcher read the instructions for three tasks aloud (twice), and participants were required to accurately repeat the instructions back to demonstrate comprehension. Instructions were not offered again unless requested. Instead, prompts were provided from one task to the next (e.g. ‘Return cups to sink’). Once the three tasks were completed, the participants were provided with the three task instructions for the next sub-block. This continued until all four sub-blocks (and consequently all 12 tasks) were completed.

The entire study took place during a single session and lasted for approximately 90 min. Participants wore the Hexoskin for the duration of the session and were debriefed at the end.

Data processing

Data was processed with RStudio (version 1.3.1093 for Windows; RStudio, Boston, USA, https://www.rstudio.com/products/rstudio/download/). The raw physiological data was downloaded from the Hexoskin Dashboard, including time taken to complete the tasks, steps, the R–R interval, heart rate and expiration timing.

Signal quality assessments for the R–R interval were used to exclude participants from analyses when >20% of the data was noisy or unreliable, according to the Hexoskin quality measures included in the software package.33 The R–R interval was further pre-processed with the R Heart Rate Variability (RHRV) package in R.Reference García Martínez, Otero, Vila, Touriño, Rodríguez-Liñares and Presedo34 Artifacts were removed via the RHRV filter function, whereby outlier parameters were set to 1.25 times the interquartile range. Any remaining outliers were manually removed with the RHRV edit function. The heart rate was then interpolated and heart rate variability time domain (standard deviation of NN intervals (SDNN) and the root mean square of successive differences (rMSSD)) and frequency domain analyses (low-frequency (0.05–0.15 Hz) and high-frequency (0.15–0.4 Hz) relative measures) were created. Lower SDNN and rMSSD are indicative of a greater stress response.Reference Grantcharov, Boillat, Elkabany, Wac and Rivas20 Moreover, stress is recognised by an increase in low-frequency and decrease in high-frequency activity.Reference Kim, Cheon, Bai, Lee and Koo22

The expiration data were processed into an expression of respiratory rate, calculated as the average number of seconds between breaths. A reduction in the number of seconds between breaths was interpreted as increased anxiety, because the reduction in seconds indicates an increase in respiratory rate.Reference Tipton, Harper, Paton and Costello21

The STAI-State was scored by reverse-coding selected items (as indicated by the scale guidelines), then summing the scores for all of the items.Reference Spielberger, Gorsuch, Lushene, Vagg and Jacobs29 The SSSQ was scored according to the method presented in Helton and Näswall,Reference Helton and Näswall35 in which the mean score per subscale was calculated. Henceforth, the questionnaire scores will be referred to as the anxiety (STAI-State), worry, task engagement and distress (SSSQ) scales.

Statistical analysis

All statistical analyses were conducted in Jamovi (version 1.6 for Windows; The jamovi project, Sydney, Australia, https://www.jamovi.org/download.html). Significance was set at P < 0.05 for all tests. Outliers – more than three standard deviations above or below the mean – were excluded from analysis. Separate linear mixed models were conducted to analyse the following dependent variables: performance measures of steps, time, task completion and task errors; psychological measures of anxiety, worry, task engagement and distress; and physiological measures of heart rate, SDNN, rMSSD, low frequency, high frequency and respiratory rate. In each model, the participant identification number was set as a random intercept. Vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) were entered as predictor variables. For the psychological data (i.e. anxiety, worry, task engagement and distress), additional baseline scores for each of the scales were added as covariates. Preliminary models were conducted controlling for age and gender, but since these variables did not change the results, age and gender were not included as covariates.

When appropriate, Bonferroni-corrected post hoc comparisons were conducted. Effect sizes (ω2) were calculated with the effect size online package,Reference Ben-Shachar, Lüdecke and Makowski36 and interpreted as very small (<0.01), small (0.01–0.06), medium (0.06–0.14) and large (>0.14), according to Field.Reference Field37

Results

Forty-three people indicated their interest in the study. Two of these people did not complete the screening process, and seven people did not fulfil all of the inclusion criteria: one was excluded for history of psychiatric disorders, three for COVID-19 restrictions (e.g. high-risk health categories) and three for Hexoskin sizes. Of the remaining 34 people, ten were unable to attend testing because of scheduling issues and developing COVID-19 symptoms the day before testing. A total of 24 participants (19 women, five men; age range 18–60 years, mean 27.1 years, s.d. 9.7 years), completed this study. The linear mixed-model results for the performance, psychological and physiological measures are presented in Table 2. The corresponding marginal means, s.e. and 95% confidence intervals for the vision condition and trial order variables are reported in Supplementary Appendix 2.

Table 2 Linear mixed-model results of the effect of vision condition and trial order

Significant predictors (P < 0.05) are in bold.

a. All interaction predictors reflect a vision condition × trial order interaction.

Performance data

There was a significant main effect of vision condition for time (F(1, 21.31) = 37.35, P < 0.001, ω2 = 0.609). As illustrated in Fig. 5(a), participants were slower to complete the tasks during the simulated AMD condition (mean 900.93 s, s.e. 17.36) compared with the normal vision condition (mean 792.92 s, s.e. 17.07). There was also a significant main effect of trial order (F(1, 21.31) = 55.37, P < 0.001, ω2 = 0.7), with participants completing the tasks slower during their first trial (mean 912.68 s, s.e. 17.36) compared with their second trial (mean 781.17 s, s.e. 17.07). There was no significant interaction between vision condition and trial order (P = 0.987).

Fig. 5 Vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) effects for the task performance measures. Results are for (a) time, (b) steps, (c) task incompletion and (d) task errors. AMD, age-related macular degeneration.

There were no significant main effects or interaction for the number of steps taken to complete the tasks (all P > 0.903; see Fig. 5(b)).

Regarding task incompletion, results of a linear mixed model revealed a significant main effect of trial order (F(1, 22) = 21.67, P < 0.001, ω2 = 0.463). Tasks were more often incomplete during the first trial (mean 1.42, s.e. 0.187) compared with the second trial (mean 0.208, s.e. 0.187; see Fig. 5(c)). The was no significant main effect of vision condition (P = 0.635), nor interaction between vision condition and trial order (P = 0.449).

There was a significant main effect of trial order for task errors (F(1, 22) = 38.11, P < 0.001, ω2 = 0.607). Figure 5(d) shows that task errors occurred more during the first trial (mean 2.83, s.e. 0.372) compared with the second trial (mean 1.21, s.e. 0.372). There was no significant main effect of vision condition (P = 0.437), nor interaction between vision condition and trial order (P = 0.679).

Psychological data

Results of a linear mixed model found a significant main effect of vision condition for anxiety (F(1, 21) = 5.93, P = 0.024, ω2 = 0.177). The anxiety scores were higher after the simulated AMD condition (mean 35.91, s.e. 1.87) than after the normal vision condition (mean 31.49, s.e. 1.87; see Fig 6(a)). There was also a significant main effect of trial order (F(1, 21) = 5.46, P = 0.029, ω2 = 0.162), whereby anxiety scores were higher during the first trial (mean 35.82, s.e. 1.87) compared with the second trial (mean 31.58, s.e. 1.87). Baseline scores significantly predicted subsequent anxiety scores (F(1, 20) = 8.85, P = 0.007, ω2 = 0.263). There was no significant interaction between vision condition and trial order (P = 0.528).

Fig. 6 Vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) effects for the psychological measures. Results models are for (a) anxiety, (b) worry, (c) task engagement and (d) distress. Higher scores on (a), (b) and (d), and lower scores on (c), suggest a ‘negative’ response. AMD, age-related macular degeneration.

In terms of worry, baseline scores significantly predicated subsequent worry scores (F(1, 20) = 76.17, P < 0.001, ω2 = 0.774). There were no significant main effects or interaction (all P > 0.117; see Fig. 6(b)).

There was a significant main effect of vision condition for task engagement (F(1, 21) = 11.93, P = 0.002, ω2 = 0.322). As illustrated in Figure 6(c), task engagement scores after the simulated AMD condition were lower (mean 3.87, s.e. 0.087) than after the normal vision condition (mean 4.05, s.e. 0.087). There was also a significant main effect of trial order (F(1, 21) = 4.43, P = 0.047, ω2 = 0.130). Scores for task engagement were higher during the second trial (mean 4.01, s.e. 0.087) compared with the first trial (mean 3.91, s.e. 0.087). Baseline scores significantly predicted subsequent task engagement scores (F(1, 20) = 38.34, P < 0.001, ω2 = 0.629). There was no significant interaction between vision condition and trial order (P = 0.705).

Regarding distress, a linear mixed model found a significant main effect of vision condition (F(1, 13.53) = 7.79, P = 0.015, ω2 = 0.304). Figure 6(d) displays that distress scores were higher after the simulated AMD condition (mean 1.32, s.e. 0.060) than after the normal vision condition (mean 1.11, s.e. 0.060). There was no significant main effects of trial order (P = 0.141), nor interaction between vision condition and trial order (P = 0.361). Baseline scores did not significantly predict subsequent distress scores (P = 0.630).

Physiological data

The linear mixed models yielded no significant main effects nor interactions for the heart rate, SDNN, rMSSD, low frequency, high frequency and respiratory rate data (all P > 0.05; see Supplementary Appendix 3 for figure).

Debriefing

Based on feedback following the tasks, approximately 92% of participants felt that it was more difficult to finish the tasks during the simulated AMD condition (see Table 3). Also, approximately 83% of participants experienced greater anxiety or stress during the simulated AMD condition.

Table 3 Participant's responses to follow-up questions

AMD, age-related macular degeneration.

Discussion

In this study, we investigated the psychological impact of instrumental activities of daily living (i.e. housework) on people with simulated AMD. There were a series of main effects for task performance and the psychological self-reports, but no physiological measures reached significance. Critically, AMD simulation does have a significant negative impact on symptoms associated with a person's mental health during everyday tasks.

Regarding task performance, participants took significantly longer to complete the activities in the simulated AMD condition, mimicking findings from other daily tasks and wayfinding simulation studies.Reference Copolillo, Christopher and Lyons17,Reference Rousek and Hallbeck38 Despite this outcome, participants’ competency (i.e. completion rate and errors) in completing the tasks did not change by vision condition, demonstrating that people with moderately severe AMD can still successfully complete tasks, but with reduced functioning speed. The outcome coincides with the participants’ self-reported engagement with the tasks. Task engagement scores were significantly lower during the simulated AMD condition, suggesting that loss of vision may affect a person's motivation and confidence in their abilities to complete the activities. Therefore, the participants may have undertaken the tasks at a slower pace to ensure that they were being done correctly. Our observations expand the findings of other visual impairment research on speed and accuracy. For example, reading performance studies have previously found that participants’ reading speed decreases as the degree of visual impairment (e.g. scotoma size) increases.Reference Bernard, Scherlen and Castet39 Essentially, as vision declines, people forgo time so as to complete an activity correctly. Speed–accuracy trade-offs have already been posited to explain slower visual processing speeds, particularly within ageing populations.Reference Owsley40

Completing tasks under vision loss conditions was also found to have a large negative impact on the mental state of participants. As a direct result of the AMD simulation, there were significantly worse anxiety, task engagement and distress scores. Of note, the distress scale is a specific measure of negative affect and mood, which only underscores the degree to which everyday tasks can influence the mental state of a visually impaired person. Participants’ final feedback was also consistent with the psychological scores, with 83% of participants responding that they experienced more anxiety and stress during the simulated AMD condition. As vision loss was simulated in a younger population without age-related comorbidities (i.e. cognitive decline, hearing loss), we believe that these findings can reasonably be attributed to the effects of vision loss.

The results also revealed that repetition of the tasks greatly influenced the participants behaviour. Performance on the tasks significantly improved (i.e. reduced time, more tasks completed, less task errors) during the participants’ second attempts at completing them. This is not unusual given that practice effects are present in repeated measures designed experiments.Reference Cherry41 But, interestingly, there were medium-large effects of trial order for self-reported anxiety and task engagement as well. Although this could also be a simple effect of practice, it may also reaffirm vision-related rehabilitation strategies. Patients with AMD may be encouraged during rehabilitation by the knowledge that repeatedly undertaking a task may lessen their anxiety and build confidence in their abilities.

A strength of this study is that it is one of the first, to our knowledge, that obtains physiological and psychological data to investigate how AMD affects aspects of mental health during instrumental activities of daily living. However, the observed changes in physiological data did not reach significance. The disparity between this data and the psychological scores may be attributed to the requirements of the study tasks. Completing daily tasks (e.g. folding towels) may be considerably less alarming than the activities in previous studies that showed a physiological stress response. For example, participants in a ‘stressful’ virtual reality simulation were instructed to ride an open elevator to the top of a building and then step off the edge.Reference Martens, Antley, Freeman, Slater, Harrison and Tunbridge23 Compared with the control condition (riding a virtual closed elevator to the third floor), physiological recordings indicated a greater stress response (e.g. increased pulse rate, skin conductance, salivary cortisol and changes in heart rate variabilityReference Martens, Antley, Freeman, Slater, Harrison and Tunbridge23). Therefore, the non-significant change in our study could simply be because household tasks do not trigger a measurable difference in physiological responses.

Although the physiological measures did not reflect the increased anxiety and stress the participants self-reported in the AMD condition, our findings should not be used to dismiss the use of physiological measures in visual impairment research. Research into activities of daily living with different population groups have already been incorporating physiological measures (e.g. limb amputees or patients with lung disease).Reference van Schaik, Geertzen, Dijkstra and Dekker42,Reference Silva, Nogueira, Porto, Gazzotti, Nascimento and Camelier43 Furthermore, the use of physiological and objective wearable measures, such as the Hexoskin, can broaden the scope of research from studies investigating specific triggers (i.e. reading, housework) to unconstrained field work.

As discussed, limitations of the current study include the nature of the tasks. Although we were specifically interested in familiar instrumental activities of daily living, like housework, we recognise that physiological differences may not be discernible unless repeated with tasks that have been identified as concerning for people with AMD (e.g. stair climbing).Reference Taylor, Smith, Jones, Binns and Crabb44 Furthermore, although the use of younger, corrected to normally sighted people under simulation was intended to reduce the influence of comorbidities, it still needs to be acknowledged that this is not the demographic (i.e. typically those aged over 45 years) most afflicted by AMD.Reference Jonas, Cheung and Panda-Jonas45 Consequently, the sample related constraints of this study, including gender imbalance, small sample size, participant age group and visual status, may have hindered the generalisability of this study and should be addressed in future research.

In terms of the simulation, the adaption period for the AMD simulation goggles was approximately 30 mins, which does not equate to the long-term (i.e. months, years) oculomotor adaptations that may occur if patients develop a peripheral retinal locus to compensate for central vision loss.Reference Macnamara, Chen, Schinazi, Saredakis and Loetscher11,Reference Walsh and Liu12 Therefore, this study could have overestimated the psychological effects of AMD (e.g. increased anxiety and distress), since the normally sighted participants had far less time to adjust their behaviour. This is also reflected by the effects of trial order, which imply that the psychological effects may improve with practice. Opposingly, it is also possible that the study underestimated the psychological effects of AMD if participants circumvented the simulated scotoma by looking elsewhere through the simulation goggles.Reference Macnamara, Chen, Schinazi, Saredakis and Loetscher11 In such as case, the normally sighted participants may not have experienced the same level of visual disability that patients with AMD have.

In summary, this is the first study, to our knowledge, where a person's mental health during instrumental activities of daily living were measured psychologically and physiologically in response to simulated AMD. There was a significant large effect on self-reported anxiety, stress and completion time as a direct result of simulated vision loss. Since completing household tasks occurs daily over a long-term period, it is conceivable that instrumental activities of daily living do contribute negatively to the mental health of visually impaired people. However, clinical research on patients with AMD in the future could help to further elucidate this relationship.

Supplementary material

Supplementary material is available online at https://doi.org/10.1192/bjo.2022.558

Data availability

The data that support the findings of this study are available from the corresponding author, A.M., upon reasonable request.

Acknowledgements

We appreciate the advice from the Royal Society for the Blind, especially Andrew Davies, on people living with age-related macular degeneration. Their insights were significant during the conceptualisation of this study.

Author contributions

A.M. and T.L. conceptualised the study. All authors (A.M., S.C., C.C., V.R.S. and T.L.) contributed to the design and structure of the experiment. A.M. conducted the study. A.M., S.C. and T.L. analysed the data. All authors assisted in interpreting the results. A.M. wrote the final manuscript, with the consultation and input of all of the authors.

Funding

A.M. is supported by the Australian Government Research Training Program Scholarship and T.L. is funded by a National Health and Medical Research Council Dementia Research Leadership Fellowship (grant number GNT1136269).

Declaration of interest

None.

References

van der Aa, HP, Comijs, HC, Penninx, BW, van Rens, GH, van Nispen, RM. Major depressive and anxiety disorders in visually impaired older adults. Invest Ophthalmol Vis Sci 2015; 56(2): 849–54.10.1167/iovs.14-15848CrossRefGoogle ScholarPubMed
Le, P, Nguyen, M, Vu, T, Dao, D-P, Olson, D, Zhang, AY. Anxiety and depression in patients with retinitis pigmentosa. J VitreoRetinal Dis 2021; 5(2): 114–20.10.1177/2474126420936455CrossRefGoogle Scholar
Pinquart, M, Pfeiffer, JP. Psychological well-being in visually impaired and unimpaired individuals: a meta-analysis. Br J Vis Impair 2011; 29(1): 2745.10.1177/0264619610389572CrossRefGoogle Scholar
Berman, K, Brodaty, H. Psychosocial effects of age-related macular degeneration. Int Psychogeriatr 2006; 18(3): 415–28.CrossRefGoogle ScholarPubMed
Mitchell, P, Liew, G, Gopinath, B, Wong, TY. Age-related macular degeneration. Lancet 2018; 392(10153): 1147–59.10.1016/S0140-6736(18)31550-2CrossRefGoogle ScholarPubMed
Black, A, Wood, J. Vision and falls. Clin Exp Optom 2005; 88(4): 212–22.10.1111/j.1444-0938.2005.tb06699.xCrossRefGoogle ScholarPubMed
Wood, JM, Lacherez, P, Black, AA, Cole, MH, Boon, MY, Kerr, GK. Risk of falls, injurious falls, and other injuries resulting from visual impairment among older adults with age-related macular degeneration. Invest Ophthalmol Vis Sci 2011; 52(8): 5088–92.10.1167/iovs.10-6644CrossRefGoogle ScholarPubMed
van Landingham, SW, Massof, RW, Chan, E, Friedman, DS, Ramulu, PY. Fear of falling in age-related macular degeneration. BMC Ophthalmol 2014; 14: 10.10.1186/1471-2415-14-10CrossRefGoogle ScholarPubMed
Legters, K. Fear of falling. Phys Ther 2002; 82(3): 264–72.CrossRefGoogle ScholarPubMed
Court, H, McLean, G, Guthrie, B, Mercer, SW, Smith, DJ. Visual impairment is associated with physical and mental comorbidities in older adults: a cross-sectional study. BMC Med 2014; 12: 181.10.1186/s12916-014-0181-7CrossRefGoogle ScholarPubMed
Macnamara, A, Chen, C, Schinazi, VR, Saredakis, D, Loetscher, T. Simulating macular degeneration to investigate activities of daily living: a systematic review. Front Neurosci 2021; 15: 663062.10.3389/fnins.2021.663062CrossRefGoogle ScholarPubMed
Walsh, DV, Liu, L. Adaptation to a simulated central scotoma during visual search training. Vision Res 2014; 96: 7586.10.1016/j.visres.2014.01.005CrossRefGoogle ScholarPubMed
Butt, T, Crossland, MD, West, P, Orr, SW, Rubin, GS. Simulation contact lenses for AMD health state utility values in NICE appraisals: a different reality. Br J Ophthalmol 2015; 99(4): 540–4.10.1136/bjophthalmol-2014-305802CrossRefGoogle ScholarPubMed
Ho, E, Boffa, J, Palanker, D. Performance of complex visual tasks using simulated prosthetic vision via augmented-reality glasses. J Vis 2019; 19(13): 22.Google ScholarPubMed
Varadaraj, V, Lesche, S, Ramulu, PY, Swenor, BK. Reading speed and reading comprehension in age-related macular degeneration. Am J Ophthalmol 2018; 186: 138–43.CrossRefGoogle ScholarPubMed
Taylor, DJ, Hobby, AE, Binns, AM, Crabb, DP. How does age-related macular degeneration affect real-world visual ability and quality of life? A systematic review. BMJ Open 2016; 6(12): e011504.10.1136/bmjopen-2016-011504CrossRefGoogle ScholarPubMed
Copolillo, A, Christopher, A, Lyons, A. Effects of simulated low vision on postural adjustment to changes in center of mass in older adults. Occup Ther Health Care 2017; 31(2): 115–25.10.1080/07380577.2016.1278295CrossRefGoogle ScholarPubMed
Pardhan, S, Latham, K, Tabrett, D, Timmis, MA. Objective analysis of performance of activities of daily living in people with central field loss. Invest Ophthalmol Vis Sci 2015; 56(12): 7169–78.10.1167/iovs.15-16556CrossRefGoogle ScholarPubMed
Heesterbeek, TJ, van der Aa, HPA, van Rens, GHMB, Twisk, JWR, van Nispen, RMA. The incidence and predictors of depressive and anxiety symptoms in older adults with vision impairment: a longitudinal prospective cohort study. Ophthalmic Physiol Opt 2017; 37(4): 385–98.10.1111/opo.12388CrossRefGoogle ScholarPubMed
Grantcharov, PD, Boillat, T, Elkabany, S, Wac, K, Rivas, H. Acute mental stress and surgical performance. BJS Open 2019; 3(1): 119–25.10.1002/bjs5.104CrossRefGoogle ScholarPubMed
Tipton, MJ, Harper, A, Paton, JFR, Costello, JT. The human ventilatory response to stress: rate or depth? J Physiol 2017; 595(17): 5729–52.10.1113/JP274596CrossRefGoogle ScholarPubMed
Kim, HG, Cheon, EJ, Bai, DS, Lee, YH, Koo, BH. Stress and heart rate variability: a meta-analysis and review of the literature. Psychiatry Invest 2018; 15(3): 235–45.10.30773/pi.2017.08.17CrossRefGoogle ScholarPubMed
Martens, MA, Antley, A, Freeman, D, Slater, M, Harrison, PJ, Tunbridge, EM. It feels real: physiological responses to a stressful virtual reality environment and its impact on working memory. J Psychopharmacol 2019; 33(10): 1264–73.10.1177/0269881119860156CrossRefGoogle ScholarPubMed
Gopinath, B, Liew, G, Burlutsky, G, Mitchell, P. Age-related macular degeneration and 5-year incidence of impaired activities of daily living. Maturitas 2014; 77(3): 263–6.10.1016/j.maturitas.2013.12.001CrossRefGoogle ScholarPubMed
Hochberg, C, Maul, E, Chan, ES, Van Landingham, S, Ferrucci, L, Friedman, DS, et al. Association of vision loss in glaucoma and age-related macular degeneration with IADL disability. Invest Ophthalmol Vis Sci 2012; 53(6): 3201–6.10.1167/iovs.12-9469CrossRefGoogle ScholarPubMed
Bakker, K, Steultjens, E, Price, L. The lived experiences of adults with a visual impairment who experience fatigue when performing daily activities. Br J Occup Ther 2019; 82(8): 485–92.CrossRefGoogle Scholar
Carré Technologies. Hexoskin Smart Garments Specifications. Carré Technologies, 2021 (https://www.hexoskin.com/).Google Scholar
Fork in the Road Vision Rehabilitation Services. Low Vision Simulators. Fork in the Road Vision Rehabilitation Services, 2019 (https://www.lowvisionsimulators.com/products/macular-degeneration-simulators?variant=16992106381381).Google Scholar
Spielberger, CD, Gorsuch, RL, Lushene, R, Vagg, PR, Jacobs, GA. Manual for the State-Trait Anxiety Inventory. Consulting Psychologists Press, 1983.Google Scholar
Helton, WS. Validation of a short stress state questionnaire. Proc Hum Factors Ergon Soc Annu Meet 2004; 48(11): 1238–42.10.1177/154193120404801107CrossRefGoogle Scholar
Al Sayed, C, Vinches, L, Halle, S. Validation of a wearable biometric system¡¯s ability to monitor heart rate in two different climate conditions under variable physical activities. E Health Telecomm Syst Netw 2017; 6(2): 12.Google Scholar
Macnamara, A, Schinazi, VR, Chen, C, Coussens, S, Loetscher, T. The effect of age-related macular degeneration on cognitive test performance. Scientific Reports 2022; 12: 4033.10.1038/s41598-022-07924-8CrossRefGoogle ScholarPubMed
Carré Technologies. Hexostore API Documentation. Carré Technologies, 2022 (https://api.hexoskin.com/docs/resource/).Google Scholar
García Martínez, C, Otero, A, Vila, X, Touriño, M, Rodríguez-Liñares, L, Presedo, J, et al. Heart Rate Variability Analysis with the R package RHRV. Springer International Publishing, 2017.10.1007/978-3-319-65355-6CrossRefGoogle Scholar
Helton, WS, Näswall, K. Short stress state questionnaire. Eur J Psychol Assess 2014; 31: 20–30.Google Scholar
Ben-Shachar, M, Lüdecke, D, Makowski, D. effectsize: estimation of effect size indices and standardized parameters. J Open Sour Softw 2020; 5(56): 2815.10.21105/joss.02815CrossRefGoogle Scholar
Field, A. Discovering Statistics using IBM SPSS Statistics (4th edn). SAGE Publications, 2013.Google Scholar
Rousek, J, Hallbeck, M. The use of simulated visual impairment to identify hospital design elements that contribute to wayfinding difficulties. Int J Ind Ergon 2011; 41(5): 447–58.10.1016/j.ergon.2011.05.002CrossRefGoogle Scholar
Bernard, JB, Scherlen, AC, Castet, E. Page mode reading with simulated scotomas: a modest effect of interline spacing on reading speed. Vision Res 2007; 47(28): 3447–59.10.1016/j.visres.2007.10.005CrossRefGoogle ScholarPubMed
Owsley, C. Vision and aging. Annu Rev Vis Sci 2016; 2: 255–71.10.1146/annurev-vision-111815-114550CrossRefGoogle ScholarPubMed
Cherry, K. What Are Practice Effects? Explore Psychology, 2019 (https://www.explorepsychology.com/practice-effects/).Google Scholar
van Schaik, L, Geertzen, JHB, Dijkstra, PU, Dekker, R. Metabolic costs of activities of daily living in persons with a lower limb amputation: a systematic review and meta-analysis. PLoS One 2019; 14(3): e0213256.CrossRefGoogle ScholarPubMed
Silva, CS, Nogueira, FR, Porto, EF, Gazzotti, MR, Nascimento, OA, Camelier, A, et al. Dynamic hyperinflation during activities of daily living in COPD patients. Chronic Respir Dis 2015; 12(3): 189–96.10.1177/1479972315576143CrossRefGoogle ScholarPubMed
Taylor, DJ, Smith, ND, Jones, PR, Binns, AM, Crabb, DP. Measuring dynamic levels of self-perceived anxiety and concern during simulated mobility tasks in people with non-neovascular age-related macular degeneration. Br J Ophthalmol 2020; 104(4): 529–34.10.1136/bjophthalmol-2019-313864CrossRefGoogle ScholarPubMed
Jonas, JB, Cheung, CMG, Panda-Jonas, S. Updates on the epidemiology of age-related macular degeneration. Asia Pac J Ophthalmol (Phila) 2017; 6(6): 493–7.Google ScholarPubMed
Figure 0

Fig. 1 Picture of cutlery taken through the simulated AMD vision and normal vision goggles. (a) Example of simulated AMD vision. (b) Example of normal vision. AMD, age-related macular degeneration.

Figure 1

Fig. 2 Sleep and Chronobiology Laboratory. The Sleep and Chronobiology Laboratory is within the MC building at Magill Campus, University of South Australia. From left to right/up to down: the rooms used in the study included the living room and kitchen (35 m2), hallway (18.9 m2) and bedrooms (11.4 m2 each).

Figure 2

Table 1 Instructions for the 12 instrumental activities of daily living

Figure 3

Fig. 3 Alterantive material locations. (a) Example of the alternative locations of the DVDs in each bedroom. (b) Example of the alternative locations of the pillows in the hallway.

Figure 4

Fig. 4 Study procedure. AMD, age-related macular degeneration; SSSQ, Short Stress State Questionnaire; STAI, State–Trait Anxiety Inventory.

Figure 5

Table 2 Linear mixed-model results of the effect of vision condition and trial order

Figure 6

Fig. 5 Vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) effects for the task performance measures. Results are for (a) time, (b) steps, (c) task incompletion and (d) task errors. AMD, age-related macular degeneration.

Figure 7

Fig. 6 Vision condition (normal versus simulated AMD) and trial order (trial 1 versus trial 2) effects for the psychological measures. Results models are for (a) anxiety, (b) worry, (c) task engagement and (d) distress. Higher scores on (a), (b) and (d), and lower scores on (c), suggest a ‘negative’ response. AMD, age-related macular degeneration.

Figure 8

Table 3 Participant's responses to follow-up questions

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