a. Functions of the moduleThe instrumentation module has several essential functions. The first is to provide the electrical,mechanical, and computer hardware engineering expertise necessary for the development andimplementation of novel devices and instrumentation. This capability is essential for CVSresearchers to continue to break new ground in vision research. One example is the growinginterest in measuring and correcting the optical aberrations in the eye not only in humans, butalso in animal models. With the support of the instrumentation core the University of Rochesterhas become a leader in the development of advanced wavefront sensors and adaptive opticssystems for improving contact lens design and refractive surgery and also for high-resolutionretinal imaging. In the next 5 years, there will be even greater demand for this module, as weusher in the next generation of wavefront instrumentation. A second critical function of thismodule is the facilitation of intra- and extramural collaborations through the development anddeployment of shared technologies and expertise. For instance the instrumentation module wasa key component in the development of a new, shared, virtual reality laboratory for studying thevisual control of movement, and this innovative approach will now be replicated in the MedicalCenter. A subsidiary (although essential) role of the module is continuing support, debuggingand replication of developed technologies in order to maintain the high productivity of CVSresearchers and collaborators. As CVS has grown over the past 5 years and as newapproaches to research and new technologies are applied to vision research, the demands onthe instrumentation module have burgeoned. The experience and specialized expertise of themodule's staff lie at the foundation of the CVS research effort.
Cheong, Soon Keen; Strazzeri, Jennifer M; Williams, David R et al. (2018) All-optical recording and stimulation of retinal neurons in vivo in retinal degeneration mice. PLoS One 13:e0194947 |
Granger, Charles E; Yang, Qiang; Song, Hongxin et al. (2018) Human Retinal Pigment Epithelium: In Vivo Cell Morphometry, Multispectral Autofluorescence, and Relationship to Cone Mosaic. Invest Ophthalmol Vis Sci 59:5705-5716 |
Cheong, Soon K; Xiong, Wenjun; Strazzeri, Jennifer M et al. (2018) In Vivo Functional Imaging of Retinal Neurons Using Red and Green Fluorescent Calcium Indicators. Adv Exp Med Biol 1074:135-144 |
Zinszer, Benjamin D; Bayet, Laurie; Emberson, Lauren L et al. (2018) Decoding semantic representations from functional near-infrared spectroscopy signals. Neurophotonics 5:011003 |
McGregor, Juliette E; Yin, Lu; Yang, Qiang et al. (2018) Functional architecture of the foveola revealed in the living primate. PLoS One 13:e0207102 |
Lockwood, Colin T; Vaughn, William; Duffy, Charles J (2018) Attentional ERPs distinguish aging and early Alzheimer's dementia. Neurobiol Aging 70:51-58 |
Chernoff, Benjamin L; Teghipco, Alex; Garcea, Frank E et al. (2018) A Role for the Frontal Aslant Tract in Speech Planning: A Neurosurgical Case Study. J Cogn Neurosci 30:752-769 |
Alarcon-Martinez, Luis; Yilmaz-Ozcan, Sinem; Yemisci, Muge et al. (2018) Capillary pericytes express ?-smooth muscle actin, which requires prevention of filamentous-actin depolymerization for detection. Elife 7: |
Jeon, Kye-Im; Hindman, Holly B; Bubel, Tracy et al. (2018) Corneal myofibroblasts inhibit regenerating nerves during wound healing. Sci Rep 8:12945 |
Weiss, Menachem Y; Kuriyan, Ajay E (2018) Acute Monocular Vision Loss in a Young Adult. JAMA Ophthalmol 136:297-298 |
Showing the most recent 10 out of 211 publications