The use of isotopic labeling with carbon 14 is widespread in biological and medical research, medical diagnostics and drug discovery and development. However, methods to detect radioisotopes depend on the detection of a nuclear decay event, an inefficient process as there is only 1 decay event per minute for every 4.35 billion atoms of 14C present in a sample, requiring the use of high levels of radioactivity.
The aim of this project is to demonstrate a device, suitable for routine laboratory use, for atom counting of the tracer 14C, treating 14C as a """"""""stable"""""""" isotope, decreasing the dosage required for most experiments and making new classes of studies possible. LARA will be extended from analysis of 13CO2 to similar analysis of 14CO2. Instrumentation will have sensitivity orders of magnitude greater than possible with scintillation (decay) detection and will compete with typical tandem accelerator mass spectrometers (AMS) that have demonstrated sensitivity at the picomole to the attomole level. The enhanced sensitivity is important for low dose and small sample tracer studies, long-term metabolic studies, pharmacokinetics studies and is being studied as a possible tool for protein sequencing and micro-imaging studies. A 14CO2 LARA device is projected to be considerably smaller, less complex and much lower in cost than an AMS with comparable capability. It will be shown that a sealed infrared laser operating at a unique infrared transition in 14CO2, can be routinely used to probe a sample cell containing carbon dioxide. The sample will be in a low pressure electrical discharge optimized for low noise detection of the optogalvanic effect. Such a system can be used to quantitatively measure small samples of 14C-enriched carbon dioxide. Results of the measurements with enriched samples will quantify improvements required to achieve ultimate sensitivity. Techniques will be developed to achieve enhanced sensitivity at the picomole to attomole level. Techniques will include electronic and digital algorithms to lower noise, gas mixture variations to enhance signal and quantum electronic (laser) enhancements. It is further aimed to build prototype instruments for routine laboratory use and transfer the technology to biomedical research facilities.

Agency
National Institute of Health (NIH)
Institute
National Center for Research Resources (NCRR)
Type
Exploratory/Developmental Grants Phase II (R33)
Project #
4R33RR018280-03
Application #
7034825
Study Section
Special Emphasis Panel (ZRR1-BT-1 (01))
Program Officer
Farber, Gregory K
Project Start
2005-04-01
Project End
2008-03-31
Budget Start
2005-04-01
Budget End
2006-03-31
Support Year
3
Fiscal Year
2005
Total Cost
$308,940
Indirect Cost
Name
Rutgers University
Department
Physics
Type
Schools of Arts and Sciences
DUNS #
130029205
City
Newark
State
NJ
Country
United States
Zip Code
07102
Murnick, Daniel; Dogru, Ozgur; Ilkmen, Erhan (2010) C Analysis via Intracavity Optogalvanic Spectroscopy. Nucl Instrum Methods Phys Res B 268:708-711
Murnick, Daniel E; Dogru, Ozgur; Ilkmen, Erhan (2008) Intracavity optogalvanic spectroscopy. An analytical technique for 14C analysis with subattomole sensitivity. Anal Chem 80:4820-4