SBIR-STTR Award

Tritium AMS Analysis of Cancer Biomarkers
Award last edited on: 5/31/09

Sponsored Program
STTR
Awarding Agency
NIH : NCI
Total Award Amount
$2,451,072
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Paul L Skipper

Company Information

Newton Scientific Inc (AKA: NSI)

255 Bent Street
Cambridge, MA 02141

Research Institution

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Phase I

Contract Number: 1R41CA084688-01
Start Date: 00/00/00    Completed: 00/00/00
Phase I year
2000
Phase I Amount
$191,702
The goal of this project is to develop an exceptionally compact, high throughput tritium accelerator mass spectrometer (AMS) to enable ultra-sensitive tracer studies relevant to the molecular analysis of cancer. The proposed tritium AMS will operate at much lower energy than existing multi-isotope AMS instruments, and will incorporate a sample inlet that can be coupled to a wide variety of liquid micro-flow sample preparation systems. AMS is a powerful tool for detection of rare isotopes such as tritium that are commonly used to radiolabel organic biomolecules, with detection limits in the attomole (10exp-18 mole) and lower range. In contrast to existing instrumentation, an AMS designed exclusively for detection of tritium may be as compact and inexpensive as conventional mass spectrometers. As currently practiced, analysis of biological samples by AMS is limited by the requirement for highly specialized sample preparation procedures that are not compatible with on-line and rapid detection applications. The instrument proposed here addresses this shortcoming by integrating a specialized sample interface into the overall design. The goals of Phase I are to develop and optimize the interface, to experimentally determine the feasibility of tritium AMS at very low energy, and to develop a design to be implemented in Phase II.

Phase II

Contract Number: 5R41CA084688-02
Start Date: 00/00/00    Completed: 00/00/00
Phase II year
2001
(last award dollars: 2007)
Phase II Amount
$2,259,370

The goal of this project is to develop an exceptionally compact, high throughput tritium accelerator mass spectrometer (AMS) to enable ultra-sensitive tracer studies relevant to the molecular analysis of cancer. The proposed tritium AMS will operate at much lower energy than existing multi-isotope AMS instruments, and will incorporate a sample inlet that can be coupled to a wide variety of liquid micro-flow sample preparation systems. AMS is a powerful tool for detection of rare isotopes such as tritium that are commonly used to radiolabel organic biomolecules, with detection limits in the attomole (10exp-18 mole) and lower range. In contrast to existing instrumentation, an AMS designed exclusively for detection of tritium may be as compact and inexpensive as conventional mass spectrometers. As currently practiced, analysis of biological samples by AMS is limited by the requirement for highly specialized sample preparation procedures that are not compatible with on-line and rapid detection applications. The instrument proposed here addresses this shortcoming by integrating a specialized sample interface into the overall design. The goals of Phase I are to develop and optimize the interface, to experimentally determine the feasibility of tritium AMS at very low energy, and to develop a design to be implemented in Phase II.