Erik Viirre, M.D, Ph.D. - US grants

The Virtual Retinal Display (VRD) is a new form of display device developed at the Human Interface Technology Laboratory in Seattle, Washington. This device scans light directly into the eye to create images at the retina. It is anticipated that the VRD will become a ubiquitous display device as it will be miniaturized to wear on a spectacles frame. The VRD is bright, yet safe and uses lasers as highly color saturated sources of light. The research from this proposal will be studies on the fundamentals of light perception of scanned images. These studies will allow us to optimize the scan characteristics for best color, resolution and contrast. We intend to understand the features of temporal and spatial integration by the retinal processing elements of the scanned light and how that integration affects the image perception. We will then be able to produce images with excellent color matching and image sharpness. By optimizing the VRD in this research we will allow its use where image quality is essential, such as in remote surgery, or surgical training. Further, bright, high quality images with the VRD will make it excellent for use in augmented vision applications, where images are superimposed on the real world.

The Virtual Retinal Display (VRD) developed by the PIs and their colleagues creates an image by scanning non-coherent or coherent light across the retina in a raster pattern, rather than using a conventional image plane screen. The VRD has full color and a broad luminance range for high contrast, even in bright ambient daylight; the mechanism will eventually be miniaturized to fit on a spectacle frame, making wearable displays feasible. Because of these attributes, and the fact that VRD parameters can be configured in various combinations to alter characteristics of the perceived image such as field of view, resolution and the size of the scanning aperture, the VRD holds great promise for enhancing vision in the partially sighted. The goal of this research is to investigate how best to realize this promise. The small exit pupil of the VRD allows clear images to be seen by users with corneal distortions and/or partial opacities of the lens such as cataracts. For central retinal diseases such as macular degeneration, the VRD can be configured to direct high contrast, large feature images to the peripheral retina. For peripheral disorders, where only a small central area may remain functional, the display can be configured with a high-resolution narrow field of view. Pilot tests of subjects with partial loss of vision indicate that even non-optimized images from the VRD can usually be seen better than CRT images. The PIs will conduct psychophysical visual testing with partially sighted users, and systematic comparison with standard computer displays (CRTs and LCDs), to determine for a variety of visual disorders the appropriate VRD scanning and modulation characteristics for optimal image resolution, contrast sensitivity, color perception and absence of flicker. The ability of users to view text, see video images and use common computer applications such as word processors, spreadsheets, and web browsers will also be assessed. The expectation is that this research will ultimately lead to new visual display products and techniques to enhance computer access for people with low vision, including the growing elderly population

The project proposes to create a distributed, multi-user social computing environment that will develop the capabilities of human Electroencephalography (EEG) to analyze users engagement with digitally based experiences. For this project, users will wear non-invasive, EEG headsets while navigating a shared virtual world. Beginning with a handful of EEG systems, the team will scale up over the course of the project to gather signals from dozens of users, providing a basis for larger scale studies. By comparing the EEG signals with each participants activities in virtual world, and with the brain activity and the activities of other users, a model of human brain activity will be developed for different types of behavior profiles and subjective states. This will allow significant improvement for the development of neural markers of human perceptual, cognitive and affective states, the parsing of EEG signals, the applicability of EEG interfaces to new types of experiences, all of which can enhance distance learning, collaborative distributed work, improved mobile computing interfaces and health care applications. The project will advance the capabilities for determining an individuals cognitive state by the creation of new computing methods utilizing comparative EEG analysis and data analysis of event states in a digital simulation. Bringing methods of large scale data analysis to articulate patterns across many users in the situated milieu of the online virtual world will create a new method to utilize EEG analysis to infer human subjective experience. The necessity of conducting this analysis in real-time, with data gathered from distributed, wireless EEG instruments will provide the impetus for utilizing accelerated hybrid multi-core techniques to bear on this domain.

The results from the project will be applicable for a variety of digital environments including computer aided learning and training, digitally mediated collaborative work environments, visualization of complex data sets, and digitally based entertainment experiences such as virtual worlds and computer games. The project will improve the functionality and outcomes of these digital media environments, better adjusting them to the cognitive states of the users. The PIs will train and employ a diverse body of participants to be involved in these activities. As part of an internship program at the Preuss School, a nationally recognized middle and high school on the campus of UCSD, UCSD faculty and staff mentor high school seniors to provide these students valuable experiences in a research laboratory. In addition, UMBC operates the very successful Meyerhoff program for minority students, primarily African-American, for which over 90% of a yearly entrance number of more than fifty go on to graduate school in science or engineering. Many of these students are computer science majors that have had the elective graduate course of Service Oriented Computing for Scientists and Engineers.

This project will study brain aging and inflammation in microgravity. Long-term space exposure creates a series of physiological alterations including cognitive decline. Studying astronauts' brains before and after their mission can tell what goes wrong but provides little insight on the mechanisms responsible for the observed alterations. This, this project will grow stem cell-derived human brain tissues at the International Space Station to accelerate our understanding of the mechanisms involved in brain aging. These studies will have profound implications for improved neurological pre-clinical models for applications on Earth. Educational benefits from this investigation include incorporating the results into the training of graduate students and high school students. The work will also be disseminated to the broader community through a video channel and podcast episodes.

Microgravity has been shown to evoke alterations in cell growth, differentiation, cell communication, aging, and epigenetic/gene expression alterations in various cell types, including brain cells. Preliminary data, from a previous spaceflight, showed exposure to microgravity induced a series of molecular changes that mimic aging in human cells. Such alterations might accelerate or enhance cellular (telomerase dynamics) and molecular processes (activation of endogenous retroelements) that are important for neurological disorders. Here, this study will mechanistically investigate this aging phenotype on human brain organoids infused with microglia. First, the brain organoids will be optimized for spaceflight compatibility. Second, the impact of re-activation of endogenous retroelements will be characterized. And third, brain organoids will be generated with inducible TERT and modulate their activity at different developmental stages to determine how telomerase activity affects the development of brain organoids. The proposed work will advance understanding of 3D brain organoids enabling improved models of neurological disorders that represent significant health burdens.

This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.