Imaging method and device for carrying out said method
First Claim
1. An imaging method, comprising:
- conducting an imaging procedure by simultaneously determining in vivo distributions of bioluminescent and/or fluorescent markers and in vivo distributions of radioactive markers of an object at identical projection angles;
wherein the distributions of the bioluminescent and/or fluorescent markers are determined by a first separate detection of photons having a first average energy, which are emitted by the bioluminescent and/or fluorescent markers, by at least one first detector;
wherein the distributions of the radioactive markers are determined by a second separate detection of photons having a second average energy, which are emitted by the radioactive markers, by at least one second detector;
wherein the photons of the bioluminescent and/or fluorescent markers having the first average energy and the photons of the radioactive markers having the second average energy are separated for the separate detection with the aid of a layer, the layer essentially reflecting the photons of the bioluminescent and/or fluorescent markers and transmitting the photons of the radioactive markers;
wherein the layer is used to reflect the photons of the bioluminescent and/or fluorescent markers in a first direction of the at least one first detector and for transmitting the photons of the radioactive markers in-a second direction of the at least one second detector, wherein the first and second directions are different from each other;
wherein the first separate detection and the second separate detection occur simultaneously;
wherein the at least one first detector, the at least one second detector, and the layer are fixedly arranged in a predetermined specific spatial arrangement relative to each other;
wherein the at least one first detector, the at least one second detector, and the layer are fixedly arranged as a rigid arrangement within a common housing;
wherein the object is placed within the housing during the imaging procedure; and
creating a first projection image from the first separate detection and a second projection image from the second separate detection, wherein the first and second projection images are of two-dimensional images of three-dimensional energy distributions of the bioluminescent and/or fluorescent markers and the radioactive markers of the object.
1 Assignment
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Accused Products
Abstract
The invention relates to an imaging method for simultaneously determining in vivo distributions of bioluminescent and/or fluorescent markers and radioactive markers at identical projection angles, the distribution of the bioluminescent and/or fluorescent markers being determined by separate detection of photons having a first average energy, which are emitted by the bioluminescent and/or fluorescent markers, by means of at least one first detector and the distribution of the radioactive markers being determined by simultaneous separate detection of photons having a second average energy, which are emitted by the radioactive markers, by means of at least one second detector. Furthermore, it also relates to an apparatus for carrying out the imaging method, containing at least one CCD camera (1, 2) as first detector, at least one single photon emission computer tomography (SPECT) detector (3) as second detector and a layer (5), which essentially reflects the photons of the bioluminescent and/or fluorescent markers and essentially transmits the photons of the radioactive markers.
10 Citations
4 Claims
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1. An imaging method, comprising:
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conducting an imaging procedure by simultaneously determining in vivo distributions of bioluminescent and/or fluorescent markers and in vivo distributions of radioactive markers of an object at identical projection angles; wherein the distributions of the bioluminescent and/or fluorescent markers are determined by a first separate detection of photons having a first average energy, which are emitted by the bioluminescent and/or fluorescent markers, by at least one first detector; wherein the distributions of the radioactive markers are determined by a second separate detection of photons having a second average energy, which are emitted by the radioactive markers, by at least one second detector; wherein the photons of the bioluminescent and/or fluorescent markers having the first average energy and the photons of the radioactive markers having the second average energy are separated for the separate detection with the aid of a layer, the layer essentially reflecting the photons of the bioluminescent and/or fluorescent markers and transmitting the photons of the radioactive markers; wherein the layer is used to reflect the photons of the bioluminescent and/or fluorescent markers in a first direction of the at least one first detector and for transmitting the photons of the radioactive markers in-a second direction of the at least one second detector, wherein the first and second directions are different from each other; wherein the first separate detection and the second separate detection occur simultaneously; wherein the at least one first detector, the at least one second detector, and the layer are fixedly arranged in a predetermined specific spatial arrangement relative to each other; wherein the at least one first detector, the at least one second detector, and the layer are fixedly arranged as a rigid arrangement within a common housing; wherein the object is placed within the housing during the imaging procedure; and creating a first projection image from the first separate detection and a second projection image from the second separate detection, wherein the first and second projection images are of two-dimensional images of three-dimensional energy distributions of the bioluminescent and/or fluorescent markers and the radioactive markers of the object. - View Dependent Claims (2, 3, 4)
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Specification