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Health in Motion- Digitally Interactive Tai Chi Home Exercises for Safer Mobility

Award Information
Agency: Department of Health and Human Services
Branch: National Institutes of Health
Contract: 1R43AI102547-01A1
Agency Tracking Number: R43AI102547
Amount: $149,949.00
Phase: Phase I
Program: SBIR
Solicitation Topic Code: NIAID
Solicitation Number: PA12-088
Timeline
Solicitation Year: 2013
Award Year: 2013
Award Start Date (Proposal Award Date): N/A
Award End Date (Contract End Date): N/A
Small Business Information
55 WHITNEY AVE, STE 2
NEW HAVEN, CT 06510-1300
United States
DUNS: 968714837
HUBZone Owned: No
Woman Owned: No
Socially and Economically Disadvantaged: No
Principal Investigator
 HUR KOSER
 (203) 432-9629
 hurkoser@anceradx.com
Business Contact
 ARJUN GANESAN
Phone: (203) 819-2322
Email: arjun.cora@gmail.com
Research Institution
 Stub
Abstract

DESCRIPTION (provided by applicant): Advancements in micro- and Nanotechnology have led to a myriad of direct detection schemes and sensitive transducers for biological assays. Indeed, nano-scale transducers with capabilities to detect single cells have already been demonstrated. However, the overall sensitivity of a bio-assay is currently limited by diffusion- based mass transport towards the sensor surface (dictated by the fluidic component), and is typically orders of magnitude worse than the transducercapabilities. This bottleneck will always exist in architectures where the volume concentration of a target molecule or cell is detected along a wall of a fluid-filled compartment - as is customary with micro-fluidics or micro-well plat based assays. As such, none of the state-of-the-art, solution- based direct bio-sensing schemes - such as enzyme-linked immunosorbent assays (ELISA) - can detect less than 103-104 cells/ml. Achieving higher sensitivities require either long incubation periods (hours to days)or lengthy sample amplification. As a result, there is currently no commercial product for rare cell and pathogen detection that can simultaneously achieve a high overall detection sensitivity (i.e., ~10 colony forming units per ml) and a rapid assay completion time (i.e., lt10 mins). This shortcoming directly translates into inefficiencies in patient treatment - such as the widespread use of broad-spectrum antibiotics with sepsis and urinary tract infections - that contributes to increased costs, longer hospitalization times and the emergence of drug resistant bacterial and fungal strains. In particular, the need for sensitive and rapid pathogen identification is criticalin the context of sepsis, since each hour lost in targeted treatment results in a 9% increase in patient mortality. Current pathogen identification methods, such as blood cultures or PCR tests, take too long to affect the critical initial decision for treatment selection. Sepsis is the second largest cause of death in non-coronary intensive care units (750,000+ cases, 215,000+ deaths annually in US alone), costing over 17B/year to treat. Here, we propose to overcome the diffusion bottleneck that plagues all existing fluid-based direct bioassays by developing a novel platform that relies onbiocompatible magnetic nanofluids for rapid, active and selective transport of target moieties to a given sensor's surface in a label- and labor-free fashion. Our approach can isolate, separate, transport, focus, direct and detect very rare cells or pathogens in an otherwise complex biological fluid sample. Our goal in this Phase I project is to build and demonstrate quantitative, ultra-rapid (lt10 min) detection of several pathogens of interest in spiked buffer, broth and blood samples, with sensitivity levels (~10 pathogens/ml) that cannot be obtained by any existing direct detection method. Furthermore, we propose to study and establish the operational parameters of our prototype system and compare its performance with existing ELISA, PCR and blood culture tests. If successful, our system will achieve unprecedented sensitivity and speed, and could have a real impact in point-of-care diagnostics of infectious agents. Our approach could easily translate into better antibiotic stewardship and lower mortalityrates in sepsis and other severe infections. PUBLIC HEALTH RELEVANCE PUBLIC HEALTH RELEVANCE: Bacterial and fungal infections are the root cause of severe sepsis, causing over 215,000 deaths and costing 17 billion dollars to treat each year. Inthis Phase I project, we propose to develop, build and characterize a desktop platform for labor-free and label-free detection of bacterial and fungal pathogens spiked in whole blood with a speed (lt10 min) and sensitivity (lt10 pathogens/ml) unprecedented in any existing commercial system. The creation of this point-of-care diagnostics platform would not only save precious time in accurately choosing targeted treatment options of life-threatening infections (such as in sepsis), but also lead to a reduction in the emergence rate of drug-resistant pathogens.

* Information listed above is at the time of submission. *

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