Grants

Connecticut Virtuosi Chamber Orchestra

Directed Local Funds

Florence Griswold Museum

Directed Local Funds

Harriet Beecher Stowe House

Directed Local Funds

Hill-Stead Museum

Directed Local Funds

International Festival of Arts & Ideas

Directed Local Funds

Ivoryton Playhouse Foundation

Directed Local Funds

National Theatre of the Deaf-Connecticut/CT Deaf Theatre

Directed Local Funds

Hartford Stage

Directed Local Funds

Mark Twain House & Museum^The

Directed Local Funds

New Britian City Treasurer/New Britain Arts Commission

Directed Local Funds

Amistad Center for Arts & Culture #2

Directed Local Funds

TheaterWorks Inc.

Directed Local Funds

Westport Country Playhouse

Directed Local Funds

West Indian Foundation, Inc.^The

Directed Local Funds

City Youth Theater

Directed Local Funds

Artists Collective, Inc.

Directed Local Funds

Stamford Center for the Arts (Palace Stamford)

Directed Local Funds

NIGMS - National Institute of General Medical Sciences

PROJECT SUMMARY I have presented four research projects to illustrate my vision—harnessing functional polymer synthesis to present and amplify biochemical cues catalyzing cell biological phenomena such as macrophage (Mp) polarization. Dysregulated Mp polarization profoundly alters the trajectories of wound healing, chronic inflam- mation, and tumor progression. Signaling cascades underlying Mp polarization are activated by soluble and substrate-bound ligands that bind and cluster Mp receptors. How do we model the chemical diversity and spati- otemporal complexity of ligand–receptor interactions—individually fragile yet collectively powerful—to advance our fundamental understanding of Mp polarization? Our overarching hypothesis is that polymer brushes will exploit spatially complex patterns of ligand presentation to extract general principles underlying Mp polarization. Polymer brushes—ultra-thin coatings that are tens to hundreds of nm thick—are formed by grafting polymer chains at sufficiently high densities from cell culture substrates. We will interrogate Mps on ligand-functionalized polymer brushes and disclose how ligand identity, density, and spatial distribution sculpt Mp polarization. We will synthesize polymer brushes functionalized with ligands governing Mp phenotypic changes (e.g., glycosaminoglycan(GAG)-mimetic functional groups, phosphatidyl serine (PS), or mannose) and pursue four objectives: (1) GAG-mimetic polymer brushes will clarify how Mps resort to “bet hedging” to diversify polarization responses and cope with environmental uncertainty presented by infections or wounds, (2) PS-functionalized polymer brushes will reveal how Mps decode PS spatial presentation patterns, discriminate between apoptotic and non-apoptotic cells, and improvise phagocytic responses, (3) mannose-functional polymer brushes will reveal how Mps resolve “mixed messages” in tumors, wounds, and other settings where inflammatory and anti- inflammatory signals co-exist, (4) by grafting polymer brushes from multi-compartmental electrospun scaffolds, we will independently control scaffold stiffness, ligand identity, and spatial patterns of ligand presentation. Three- dimensional cell culture platforms with programmable mechanical, topographical, and surface chemical features will elucidate how Mps integrate physical, chemical, and biological stimuli to devise polarization responses. Although we focus on Mp polarization in this initial application to demonstrate proof-of-concept, the toolset we develop here will find broad application. Our long-term research goal is to interrogate fundamen- tal cell biological phenomena beyond Mp polarization via creative surface engineering of cell culture substrates We will establish cell- and disease-agnostic experimental platforms that recapitulate the chemical diver- sity and spatiotemporal complexity of ligand–receptor interactions orchestrating fundamental cell bio- logical phenomena. Building on the platforms established in the first 5 years, and in partnership with collabo- rators, we will interrogate stem cell differentiation, T-cell activation, exosome biogenesis, and other cell biological phenomena in our renewal application.

NEI - National Eye Institute

Project Summary/Abstract The cerebellum is essential for ensuring precise and coordinated movements. Central to this function is the cerebellar cortex, which integrates sensory and motor signals carried by mossy fiber projections. These signals are transformed by Purkinje cells (P-cells), the sole output neurons of the cortical circuit, into simple spike activity that fine-tunes motor commands in real time. Despite extensive knowledge of the relevant anatomy, we still do not know how mossy fiber inputs are dynamically transformed within the cortical circuit to generate P-cell simple spikes. This gap persists largely due to the challenges of recording and manipulating the activity of targeted cell types and pathways within the cerebellum of awake, behaving animals. The oculomotor system offers a unique model to address this problem. The brainstem premotor neurons driving saccades are well characterized, as are their mossy fiber projections to the oculomotor vermis (OMV, lobules VIc and VII). Mossy fibers from both the nucleus reticularis tegmenti pontis (NRTP) and the paramedian pontine reticular formation (PPRF) project bilaterally, with the NRTP relaying desired saccade amplitude from the superior colliculus and the PPRF providing corollary discharges of motor commands to motoneurons. However, how the OMV processes these signals to regulate saccades remains unknown. Our recent experiments revealed that P-cell-specific optogenetic stimulation affects saccades in direction-dependent ways. Stimulation during contraversive saccades reduces velocity at short latency. In contrast, stimulation during ipsiversive saccades produces a delayed effect, manifesting as prolonged deceleration. These latency differences cannot be explained by interactions with mossy fiber saccadic burst signals, which are time-locked to saccade onset. Instead, our findings suggest that the OMV cortical circuit processes mossy fiber inputs differently for each direction, leading to differences in how and when P-cell simple spike activity influences saccade dynamics. Specifically, we hypothesize that the OMV functions as a feedforward controller for contraversive saccades and as a temporal integrator within a negative feedback loop that governs the termination of ipsiversive saccades. The implementation of these direction-dependent mechanisms is unclear. P-cells project to the deep cerebellar nuclei and back to the cortical circuit via axon collaterals, suggesting two possibilities: delays may arise from downstream brainstem circuits or an internal switching mechanism within the OMV that modulates mossy fiber processing. To resolve this issue, we will use optogenetics to perturb PPRF mossy fiber inputs to the OMV while simultaneously recording P-cell activity. While this approach is well-established in rodent models, it has not yet been applied in non-human primates, providing a novel opportunity to determine how the OMV processes saccade-related signals and resolves direction-specific differences.

NSF

With support from the Chemical Measurement and Imaging Program in the Division of Chemistry, Alexandre Shvartsburg at Wichita State University is developing a novel toolbox for the separation and characterization of macromolecules based on the gas-phase mobilities of aligned ions. For a century since the emergence of ion mobility spectrometry (IMS) around 1900, all methods dealt with freely rotating ions. However, most macroions are polar and can align in electric field as a compass aligns with the Earth magnetic field. The transfer of such pendular ions is governed by their projections in given directions, not the average over all orientations normally relevant to IMS. This enables more detailed identification and characterization of ion geometries, in parallel to the police files comprising the face and profile photos of suspects. Such studies further capture the dipole moments also related to the molecular structure. For complex mixture analyses and broad community exploration, these approaches will be coupled to ultrahigh-resolution mass spectrometry (MS) at a major national laboratory. This research is complemented by teaching new specialized courses at selected universities across the US. Essentially all macroions have permanent dipole moments. Above a certain threshold, a sufficient electric field overcomes the thermal rotation yielding pendular states with the mobility controlled by the directional cross section across the dipole (CCSDir). Then the field dependence of mobility reveals the previously unknown moments and CCSDir values, providing new structural information complementary to regular IMS and establishing novel macromolecular separations. While this paradigm was originally shown with the bisinusoidal waveforms from FAIMS, the slow macroion motion permits lower frequencies allowing practical rectangular waveforms. That capability would now be extended to weaker dipoles by raising the waveform amplitude and narrowing the gap for stronger field, with more flexible alignment achieved by varying the waveform profile and gas temperature. The helium buffers compatible with weak field would magnify the differential mobility and facilitate the connection to ion morphologies via first-principles modeling as with linear IMS. These digital waveforms accommodate an arbitrary number of flat segments, allowing us to implement and evaluate the long-standing concept of higher-order differential IMS based on the terms of mobility(field) function beyond quadratic. These and other unprecedented separations ensuing from the dynamic dipole locking would be integrated with Fourier Transform MS at National High Magnetic Field Laboratory, including the unique 21-Tesla Fourier Transform Ion Cyclotron Resonance system delivering ultimate MS resolution. The IMS/MS platforms and technologies resulting from this project would expand the frontiers of integrative structural biology and top-down proteomics. 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.

NHLBI - National Heart Lung and Blood Institute

ABSTRACT Bias in pulse oximetry accuracy is associated with significant delays in care and unrecognized eligibility for therapeutics among patients with darker skin pigmentation. However, very few pulse oximetry studies have incorporated direct measures of skin pigmentation, and none have incorporated objective measurements. This is a problem because the bias of modern pulse oximetry devices is believed to be related to skin pigmentation. Most studies on pulse oximetry bias are retrospective and rely on self-reported race and ethnicity. We know pulse oximetry bias contributes to worse outcomes among non-White hospitalized patients, disproportionately impacting Black and Hispanic patients. However, significant variance in skin pigmentation exists within racial and ethnic groups. Therefore, race and ethnicity are poor surrogates for skin pigmentation. Further, race and ethnicity are social constructs that do not address the root cause of pulse oximeter bias: skin pigmentation. In 2024, the US Food and Drug Administration (FDA) recommended directly measuring skin pigmentation when evaluating pulse oximeters. Accordingly, there is a critical need to prospectively determine the effects of directly measured skin pigmentation on pulse oximeter performance. To address this gap, we will test our overarching hypothesis that darker skin pigmentation will be associated with increased pulse oximetry bias. Pulse oximeter performance, as defined by the correlation between a non-invasive/continuous pulse oximeter (SpO2) and an invasive/intermittent laboratory measure of arterial oxygen saturation (SaO2), is sub-optimal among patients with darker skin pigmentation. Landmark studies demonstrated that non-White patients experience a greater incidence of hypoxemia (SaO2<88%) compared to White patients when SpO2 values are normal (i.e., unrecognized hypoxemia). Unrecognized hypoxemia increases the risk of cardiac arrest, organ dysfunction, and is associated with an up to 3-fold increase in mortality among hospitalized patients. Skin pigmentation may affect the accuracy of SpO2 measurements by introducing error from systematic bias (e.g., consistently higher SpO2 values at a given SaO2). However, retrospective studies can neither directly measure skin pigmentation nor collect arterial blood gases for paired SpO2-SaO2 comparisons. We will leverage data from our ongoing, federally funded SAVE-O2 AI multicenter clinical trial (NCT06374225), comparing a closed- loop autonomous oxygen titration device versus usual care in 300 acutely ill adult patients at three US tertiary care hospitals. We are directly measuring skin pigmentation in all patients via two validated scales plus an objective spectrophotometer. We will use data from the SAVE-O2 AI trial to determine the association between skin pigmentation and pulse oximetry bias (Aim 1). We will then create a prediction tool incorporating skin pigmentation to establish personalized SpO2 targets for hospitalized patients (Aim 2). These specific aims will generate preliminary data to support a clinical trial that will address our long-term goal of validating personalized SpO2 targets based on skin pigmentation to mitigate the risks of unrecognized hypoxemia.

U.S. National Science Foundation

Disability and Rehabilitation Engineering

Disability Foundation Inc

Disability Foundation Inc is an active grantmaking foundation based in Dayton, OH. Focus: community development. Contact the foundation directly for current funding opportunities.

West Bank, Gaza USAID-West Bank

The U.S. Agency for International Development (USAID) West Bank and Gaza Mission (WBG) is inviting all interested Implementing Partners to apply for FY14 Disability Funding to: Increase the participation of people with disabilities in USAID programs/activities; and Strengthen the capacity and services of civil society organizations run by and for people with disabilities; herein referred to as Disabled People s Organizations (DPOs). Up to $5 Million in funding is available to support programs and activities to increase the participation of people with disabilities within the strategies and portfolios of USAID and to strengthen the capacity and services of DPOs. Program areas could include, but are not limited to: agriculture and food security; democracy, human rights &amp; governance; economic growth and trade; education; environment and global climate change; sports; gender equality and women s empowerment; health; and science, technology and innovation, among others. Capacity building programs for DPOs may include organizational capacity, advocacy efforts, cross-disability coalition building, coordination, and leadership and training. All awards (grants or cooperative agreements) under this request for concept papers will be administered through and managed by USAID. Subject to the availability of funds, the total estimated level of funding available for awards under this worldwide request is up to $5,000,000 as follows: 1. Small fund programs: ranging from $20,000 to $300,000 (the total amount of all small fund awards shall not exceed $3.8 million worldwide) 2. Large fund programs: ranging from $300,000 - $600,000 (the total amount of all large fund awards shall not exceed $1.2 million worldwide)