Simulated Visual Field Loss Does Not Alter Turning Coordination in Healthy Young Adults

Murray, Nicholas G.; Leon, Marlina Ponce de; Ambati, V. N. Pradeep; Saucedo, Fabricio; Kennedy, Evan; Reed-Jones, Rebecca J.

doi:10.1080/00222895.2014.931272

Cited by 4 publications

(9 citation statements)

References 33 publications

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“…If pedestrians are restricted from using peripheral vision by experimental manipulation -in particular, if they are unable to use the lower visual field (Marigold & Patla, 2008) -they behave much as when climbing an uneven staircase, that is, looking at each tread to plan a step (see also Miyasike-daSilva et al, 2019). On the other hand, restricting central vision (Murray et al, 2014) does not adversely impact stair-climbing behavior, although the lack of fine detail might prove problematic in less-predictable environments, and perhaps makes the transition between the stairs and a flat surface harder to navigate. It seems that climbing stairs is possible with peripheral vision only, but why do people not look at the stairs?…”

Section: Peripheral Vision For Actionmentioning

confidence: 99%

Peripheral vision in real-world tasks: A systematic review

2022

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Peripheral vision is fundamental for many real-world tasks, including walking, driving, and aviation. Nonetheless, there has been no effort to connect these applied literatures to research in peripheral vision in basic vision science or sports science. To close this gap, we analyzed 60 relevant papers, chosen according to objective criteria. Applied research, with its real-world time constraints, complex stimuli, and performance measures, reveals new functions of peripheral vision. Peripheral vision is used to monitor the environment (e.g., road edges, traffic signs, or malfunctioning lights), in ways that differ from basic research. Applied research uncovers new actions that one can perform solely with peripheral vision (e.g., steering a car, climbing stairs). An important use of peripheral vision is that it helps compare the position of one’s body/vehicle to objects in the world. In addition, many real-world tasks require multitasking, and the fact that peripheral vision provides degraded but useful information means that tradeoffs are common in deciding whether to use peripheral vision or move one’s eyes. These tradeoffs are strongly influenced by factors like expertise, age, distraction, emotional state, task importance, and what the observer already knows. These tradeoffs make it hard to infer from eye movements alone what information is gathered from peripheral vision and what tasks we can do without it. Finally, we recommend three ways in which basic, sport, and applied science can benefit each other’s methodology, furthering our understanding of peripheral vision more generally.

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Section: Peripheral Vision For Actionmentioning

confidence: 99%

Peripheral vision in real-world tasks: A systematic review

2022

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“…Of the 103 studies, 10 employed commercially produced SIM-SPECs to induce visual impairment or visual field defect (Table 1). [10][11][12][13][14][15][16][17][18][19] Six used SIM-SPECs purchased from Fork in the Road Rehabilitation Services (lowvi sions imula tors. com).…”

Section: Sim-specs (Commercial)mentioning

confidence: 99%

“…com). 11,13,[15][16][17]19 Due to the varying conditions simulated by the different types of SIM-SPECs, different variations of the glasses were sometimes selected, depending on the particular objectives of the study. For example, Juniat et al 13 chose the SIM-SPECs that produced the effects of age-related macular degeneration and the peripheral loss that is associated with glaucoma.…”

Section: Sim-specs (Commercial)mentioning

confidence: 99%

“…Similarly, Murray et al 15 used SIM-SPECs that simulated central vision loss with a large 2-cm diameter dot, which covered the central area of the goggles while the peripheral field was covered with a semi-transparent screen to allow some visual information, but stopped the participant from being able to look out of the side of the goggles. Cambridge simulation glasses (inclu sived esign toolk it.…”

Section: Sim-specs (Commercial)mentioning

confidence: 99%

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Simulation of visual impairment in persons with normal vision for scientific research

Abraham,

Sakyi‐Badu,

Boadi‐Kusi

et al. 2024

Ophthalmic Physiologic Optic

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Simulation of visual impairment in healthy eyes has multiple applications in students' training, research and product development. However, due to the absence of an existing standard protocol, the method of simulation was left to the discretion of the researcher. This review aimed to outline the various methods of simulating visual impairment and categorising them. A scoping review of the relevant publications was conducted. Of the 1593 articles originally retrieved from the databases, 103 were included in the review. The characteristics of the participants, the method for simulation of the visual impairment in persons with normal vision and the level or type of visual impairment that was simulated were extracted from the papers. None of the methods of simulation can be judged as being superior to the others. However, electronic displays produced the most consistent form of visual impairment simulation.

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“…All studies could be categorized as focusing on low-level visual function measurements ( n = 47) such as acuity, contrast detection threshold, and orientation discrimination (e.g., Tatiyosyan, Rifai, & Wahl, 2020 ; Léné et al., 2020 ; Butt, Crossland, West, Orr, & Rubin, 2015 ; Almutleb, Bradley, Jedlicka, & Hassan, 2018 ); mid- to high-level visual function tasks ( n = 111) such as visual search and object recognition (e.g., Walsh & Liu, 2014 ; Geringswald & Pollmann, 2015 ; Geringswald, Porracin, & Pollmann, 2016 ; Liu & Kwon, 2016 ); or high-level spatial cognition tasks ( n = 72) such as wayfinding and obstacle avoidance tasks (e.g., Alberti, Horowitz, Bronstad, & Bowers, 2014 ; Zult, Allsop, Timmis, & Pardhan, 2019 ; Rand, Creem-Regehr, & Thompson, 2015 ; Murray et al., 2014 ) that require object recognition as well as locomotion.…”

Section: Research Areasmentioning

confidence: 99%

A systematic review of extended reality (XR) for understanding and augmenting vision loss

et al. 2023

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Over the past decade, extended reality (XR) has emerged as an assistive technology not only to augment residual vision of people losing their sight but also to study the rudimentary vision restored to blind people by a visual neuroprosthesis. A defining quality of these XR technologies is their ability to update the stimulus based on the user’s eye, head, or body movements. To make the best use of these emerging technologies, it is valuable and timely to understand the state of this research and identify any shortcomings that are present. Here we present a systematic literature review of 227 publications from 106 different venues assessing the potential of XR technology to further visual accessibility. In contrast to other reviews, we sample studies from multiple scientific disciplines, focus on technology that augments a person’s residual vision, and require studies to feature a quantitative evaluation with appropriate end users. We summarize prominent findings from different XR research areas, show how the landscape has changed over the past decade, and identify scientific gaps in the literature. Specifically, we highlight the need for real-world validation, the broadening of end-user participation, and a more nuanced understanding of the usability of different XR-based accessibility aids.

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Simulated Visual Field Loss Does Not Alter Turning Coordination in Healthy Young Adults

Cited by 4 publications

References 33 publications

Peripheral vision in real-world tasks: A systematic review

Peripheral vision in real-world tasks: A systematic review

Simulation of visual impairment in persons with normal vision for scientific research

A systematic review of extended reality (XR) for understanding and augmenting vision loss

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