Abstract: An exemplary system, method and computer-accessible medium can include, for example, receiving information related to a scan(s) of a three-dimensional structure(s) containing a first tissue(s) and a second tissue(s), and providing the information to a system for identifying respective tissue types of the first tissue(s) and the second tissue(s). The structure(s) can be scanned to generate the information. The structure(s) can include a paraffin block(s). The first tissue(s) or the second tissue(s) can be excised. The tissue types can include a cancerous tissue and a non-cancerous tissue, and the first tissue(s) can be identified as the cancerous tissue and the second tissue(s) can be identified as the non-cancerous tissue.

Abstract: A biopsy collecting device includes a needle unit comprising a biopsy specimen. Also, the biopsy collecting device includes an activator unit operatively coupled to the needle unit and including a channel at a bottom surface of the activator unit, wherein the channel is configured to detachably couple the biopsy collecting device to an attaching unit of a spectroscopy system.

Abstract: A method for classifying a tissue sample of a biopsy specimen includes receiving a signal from at least one location of the tissue sample including a plurality of chromophores. Further, the method includes verifying whether the received signal comprises a predetermined amount of at least one of an attenuated illumination light and a re-emitted light. Also, the method includes determining that a spectrum of the received signal is within a predetermined range. In addition, the method includes processing the spectrum of the received signal to decompose the signal into a plurality of components. Furthermore, the method includes classifying tissue in the at least one location of the tissue sample into one of a plurality of tissue types based on the plurality of components.

Abstract: An exemplary system, method and computer-accessible medium can include, for example, receiving information related to a scan(s) of a three-dimensional structure(s) containing a first tissue(s) and a second tissue(s), and providing the information to a system for identifying respective tissue types of the first tissue(s) and the second tissue(s). The structure(s) can be scanned to generate the information. The structure(s) can include a paraffin block(s). The first tissue(s) or the second tissue(s) can be excised. The tissue types can include a cancerous tissue and a non-cancerous tissue, and the first tissue(s) can be identified as the cancerous tissue and the second tissue(s) can be identified as the non-cancerous tissue.

Abstract: A biopsy collecting device includes a needle unit comprising a biopsy specimen. Also, the biopsy collecting device includes an activator unit operatively coupled to the needle unit and including a channel at a bottom surface of the activator unit, wherein the channel is configured to detachably couple the biopsy collecting device to an attaching unit of a spectroscopy system.

Abstract: A method for classifying a tissue sample of a biopsy specimen includes receiving a signal from at least one location of the tissue sample including a plurality of chromophores. Further, the method includes verifying whether the received signal comprises a predetermined amount of at least one of an attenuated illumination light and a re-emitted light. Also, the method includes determining that a spectrum of the received signal is within a predetermined range. In addition, the method includes processing the spectrum of the received signal to decompose the signal into a plurality of components. Furthermore, the method includes classifying tissue in the at least one location of the tissue sample into one of a plurality of tissue types based on the plurality of components.

Abstract: A device is shown for measuring the angle of inclination of a radiographic imaging cassette. The device has a digital inclinometer, such as a MEMS accelerometer, configured to measure the angle of inclination of the cassette with respect to gravity. The device may be portable, including a display coupled to the inclinometer for indicating the angle of inclination of the cassette. The display may be a digital readout, or an analog meter having radio-opaque gradations such that the angle of inclination is recorded on an image processed from the imaging cassette. Alternatively, the digital inclinometer may be integrated into the imaging cassette, and be configured such that readings from the digital inclinometer may be uploaded to a digitizer via an RF transmitter or other transmission means.

Abstract: A device is shown for measuring the angle of inclination of a radiographic imaging cassette. The device has a digital inclinometer, such as a MEMS accelerometer, configured to measure the angle of inclination of the cassette with respect to gravity. The device may be portable, including a display coupled to the inclinometer for indicating the angle of inclination of the cassette. The display may be a digital readout, or an analog meter having radio-opaque gradations such that the angle of inclination is recorded on an image processed from the imaging cassette. Alternatively, the digital inclinometer may be integrated into the imaging cassette, and be configured such that readings from the digital inclinometer may be uploaded to a digitizer via an RF transmitter or other transmission means.