Friedrich Kretschmer1, Szilard Sajgo2, Viola Kretschmer2, Tudor C Badea3. 1. Retinal Circuit Development & Genetics Unit, Neurobiology Neurodegeneration & Repair Laboratory, National Eye Institute, National Institute of Health, Bethesda, MD, USA. Electronic address: friedrich@openetho.com. 2. Retinal Circuit Development & Genetics Unit, Neurobiology Neurodegeneration & Repair Laboratory, National Eye Institute, National Institute of Health, Bethesda, MD, USA. 3. Retinal Circuit Development & Genetics Unit, Neurobiology Neurodegeneration & Repair Laboratory, National Eye Institute, National Institute of Health, Bethesda, MD, USA. Electronic address: tudor.badea@nih.gov.
Abstract
BACKGROUND: Visually evoked compensatory head movements (Optomotor responses) or eye movements (Optokinetic responses) are extensively used in experimental mouse models for developmental defects, pathological conditions, and testing the efficacy of therapeutic manipulations. NEW METHOD: We present an automated system to measure Optomotor and Optokinetic responses under identical stimulation conditions, enabling a direct comparison of the two reflexes. A semi-automated calibration procedure and a commercial eye tracker are used to record angular eye velocity in the restrained animal. Novel video tracking algorithms determine the location of the mouse head in real time and allow repositioning of the stimulus relative to the mouse head. RESULTS: Optomotor and Optokinetic responses yield comparable results with respect to determining visual acuity in mice. Our new head tracking algorithms enable a far more accurate analysis of head angle determination, and reveal individual head retractions, analogous to saccadic eye movements observed during Optokinetic Nystagmus. COMPARISON WITH EXISTING METHODS: To our knowledge this is the first apparatus allowing the direct comparison of Optomotor and Optokinetic responses in mice. Our tracking algorithms, which allow an objective determination of head movements are a significant increment over existing systems which rely on subjective human observation. The increased accuracy of the novel algorithms increases the robustness of automated Optomotor response determinations and reveals novel aspects of this reflex. CONCLUSIONS: We provide the blueprints for inexpensive hardware, and release open source software for our system, and describe an accurate and accessible method for Optomotor and Optokinetic response determination in mice. Published by Elsevier B.V.
BACKGROUND: Visually evoked compensatory head movements (Optomotor responses) or eye movements (Optokinetic responses) are extensively used in experimental mouse models for developmental defects, pathological conditions, and testing the efficacy of therapeutic manipulations. NEW METHOD: We present an automated system to measure Optomotor and Optokinetic responses under identical stimulation conditions, enabling a direct comparison of the two reflexes. A semi-automated calibration procedure and a commercial eye tracker are used to record angular eye velocity in the restrained animal. Novel video tracking algorithms determine the location of the mouse head in real time and allow repositioning of the stimulus relative to the mouse head. RESULTS: Optomotor and Optokinetic responses yield comparable results with respect to determining visual acuity in mice. Our new head tracking algorithms enable a far more accurate analysis of head angle determination, and reveal individual head retractions, analogous to saccadic eye movements observed during Optokinetic Nystagmus. COMPARISON WITH EXISTING METHODS: To our knowledge this is the first apparatus allowing the direct comparison of Optomotor and Optokinetic responses in mice. Our tracking algorithms, which allow an objective determination of head movements are a significant increment over existing systems which rely on subjective human observation. The increased accuracy of the novel algorithms increases the robustness of automated Optomotor response determinations and reveals novel aspects of this reflex. CONCLUSIONS: We provide the blueprints for inexpensive hardware, and release open source software for our system, and describe an accurate and accessible method for Optomotor and Optokinetic response determination in mice. Published by Elsevier B.V.
Entities:
Keywords:
Behavior; Eye movements; Head movements; Mouse; Optokinetic reflex; Optomotor response; Retina; Video tracking visual field; Vision
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