BERNARD W AGRANOFF
Pharmacy in Ann Arbor, MI

4967084, Oct 30, 1990

Feb 2, 1989

7/305873

Arthur Rich - Ann Arbor MI
Ralph S. Conti - Ypsilanti MI
Bernard W. Agranoff - Ann Arbor MI

The University of Michigan - Ann Arbor MI

G01T 128

250361R

An arrangement for counting detectable events, such as scintillation events in a specimen sample utilizes first and second detector elements arranged on either side of the sample. The first detector is of the type which is able to produce information relative to the position of the event in the sample. The second detector generates a timing signal responsive to the detected event. In certain embodiments, the first detector also issues a timing signal in response to the detection of the event, and both timing signals are compared for temporal coincidence, whereupon circuitry for determining the position of the detectable event is triggered. The total energy of the event can be obtained from addition of the analog amplitudes of the timing signals. In certain embodiments, the second detector also produces position information, and the first and second detectors may provide respective coordinate values of a coordinate pair.

4853945, Aug 1, 1989

Jun 7, 1988

7/203789

Arthur Rich - Ann Arbor MI
Bernard W. Agranoff - Ann Arbor MI

The University of Michigan - Ann Arbor MI

G01T 1208

377 10

A liquid scintillation counter system utilizes multiplexing to monitor scintillation events in a continuously flowing effluent, using relatively few sensors, such as photomultiplier tubes, each such photomultiplier tube, in a specific embodiment, receiving light generated by scintillation events at a plurality of predetermined monitoring points along the flow path of the effluent. Each monitoring point, is coupled by means of light guides to at least two of the photomultiplier tubes. Some background noise is eliminated by use of discriminators which establish a predetermined threshold level for the magnitude of the outputs of the photomultiplier tube, above which the pulses are countable. Coincident circuitry is used to determine the presence of a scintillation event, and thereby issue a coincidence pulse which is counted. In accordance with the invention, n photomultiplier tubes can be used to monitor (n/2)(n-1) monitoring points along the flow path.

4771444, Sep 13, 1988

Sep 11, 1986

6/906173

Arthur Rich - Ann Arbor MI
Bernard W. Agranoff - Ann Arbor MI

The University of Michigan - Ann Arbor MI

G01T 1208

377 20

A liquid scintillation counter system utilizes multiplexing to achieve monitoring of a plurality of scintillation samples using relatively few sensors, such as photomultiplier tubes, each such photomultiplier tube, in a specific embodiment, receiving light generated by scintillation events in a plurality of the scintillation samples. Each scintillation sample, which may be contained in a vial, is coupled by means of light guides to at least two of the photomultipler tube. Some background noise is eliminated by use of discriminators which establish a predetermined threshold level for the magnitude of the outputs of the photomultiplier tube, above which the pulses are countable. Coincident circuitry is used to determine the presence of a scintillation event, and thereby issue a coincidence pulse which is counted. In accordance with the invention, n photomultiplier tubes can be used to monitor (n/2)(n-1) samples.