Project Summary Auditory speech perception is essential for social, vocational, and emotional health in hearing individuals. However, the reliability of auditory signals varies widely in everyday settings (e.g., at a crowded party), requiring supplemental processes to enable accurate speech perception. The principle mechanisms that support the perception of degraded auditory speech signals are auditory-visual (crossmodal) interactions, which can perceptually restore speech content using visual cues provided by lipreading, rhythmic articulatory movements, and the natural correlations present between oral resonance and mouth shape. Moreover, receptive speech processes can be limited through a variety of causes, including intrinsic brain tumor, stroke, cochlear implant usage, and age-related hearing loss, making compensatory crossmodal mechanisms necessary for one to continue working and maintaining healthy social interactions. However, the physiological processes that enable vision to facilitate speech perception remain poorly understood and no integrative model exists for how these multiple visual dimensions combine to enhance auditory speech perception. In the auditory domain, distributed populations of neurons encode spectro-temporal information about acoustic cues that are then transcoded into phonemes. We propose a dual-route perceptual model through which visual signals integrate with phoneme- coded neurons. First, a direct path through which viseme-to-phoneme conversions generate semi-overlapping distributions of activity in the superior temporal gyrus, leading to improved hearing through improved auditory phoneme tuning functions. Second, an indirect path through which visual features restore spectral information about speech frequencies and alter phoneme-response timing, resulting in improved auditory spectro-temporal profiles (which in turn are transcoded into phonemes with greater precision). Finally, we will examine the hypothesis that our perceptual system optimizes which of these visual dimensions is prioritized for recovery based on what is missing from the auditory signal. These studies will provide a unified framework for how speech perception benefits from different visual signals. By understanding biological approaches to crossmodally restoring degraded auditory speech information, we can develop better targeted rehabilitation programs and neural prostheses to maximize speech perception recovery after trauma or during healthy aging.