Abstract: Methods and systems enabling the real-time monitoring of a light-induced procedure in a biological medium, and/or the acquisition of information related to this biological medium are provided. In some implementations, the light beam used for the procedure is modulated at a modulation frequency selected in view of the photoacoustic frequency response associated with the procedure. The photoacoustic feedback signal from the medium during the procedure is then monitored. This monitoring may involve filtering the photoacoustic feedback signal around the selected feedback modulation frequency. Ratiometric comparisons of the contribution of different frequencies to the photoacoustic feedback signal are also considered.

Abstract: An apparatus for determining a soft tissue/hard tissue interface including an optical coherence tomography system comprising at least one optical fiber for emitting and receiving detection light; and a probe including a gripping portion, and a signal delivery portion housing the at least one optical fiber, the delivery portion having a distal end portion, the distal end portion being bent such that an end face of the delivery portion generally faces an investigation region when in use. An apparatus for inspecting a soft tissue/hard tissue interface including an optical coherence tomography system comprising at least one optical fiber for emitting and receiving detection light; an near-infrared probing system operatively connected to the at least one optical fiber, the near-infrared probing system emitting at least a wavelength adapted for detecting a pre-determined condition.

Abstract: Methods and systems for the controlled generation of bubbles in a medium having a liquid phase are generally provided. Laser pulses having a time-dependent pulse parameter controllable over their duration are generated. The medium is irradiated with the laser pulses with a radiant exposure sufficient to initiate microcavitation within the medium during each laser pulse. The time-dependent pulse parameter of each laser pulse is controlled according to a generally positive variation over the pulse duration such that the medium absorbs a greater quantity of energy from the laser pulse at an end of the pulse duration than at a beginning thereof. Such methods and systems may be used for various applications such as biology, medicine or material processing.

Abstract: A surgical drilling system for determining proximity of a surgical drill bit to an artery during a drilling procedure, including an excitation and/or collection optical channel of a spectral absorption probe, wherein the excitation channel provides light configured for absorption by blood chromophores and the collection channel captures diffused back-scattered light modulated by said artery; a light detector; and a signal processor for determining a distance between the tissue and the probe based on said back-scattered light. A process for determining proximity of a surgical drill bit to an artery during a drilling procedure includes bringing said excitation light near the tissue including the artery; capturing diffused back-scattered light from said tissue; detecting said light modulated by said blood flow dynamics including an oscillating signal related to said periodic change; and processing said light and determining the proximity of the surgical drill bit to the artery.

Abstract: A low coherence interferometry probe system for evaluating proximity to a tissue layer, comprising a low coherence light source for generating low coherence excitation light, an excitation optical fiber to bring the low coherence excitation light near the tissue layer and a collection optical fiber for capturing back-scattered light from the tissue layer. The probe system comprises a low coherence interferometry sub-system and a digital signal processor for evaluating a distance to the tissue layer. There is also provided a spectral absorption probe system for evaluating proximity to an artery, comprising a light source excitation light having a wavelength adapted for absorption by blood chromophores, an excitation optical fiber and a collection optical fiber.

Abstract: Methods and systems enabling the real-time monitoring of a light-induced procedure in a biological medium, and/or the acquisition of information related to this biological medium are provided. In some implementations, the light beam used for the procedure is modulated at a modulation frequency selected in view of the photoacoustic frequency response associated with the procedure. The photoacoustic feedback signal from the medium during the procedure is then monitored. This monitoring may involve filtering the photoacoustic feedback signal around the selected feedback modulation frequency. Ratiometric comparisons of the contribution of different frequencies to the photoacoustic feedback signal are also considered.

Abstract: Methods and systems for the controlled generation of bubbles in a medium having a liquid phase are generally provided. Laser pulses having a time-dependent pulse parameter controllable over their duration are generated. The medium is irradiated with the laser pulses with a radiant exposure sufficient to initiate microcavitation within the medium during each laser pulse. The time-dependent pulse parameter of each laser pulse is controlled according to a generally positive variation over the pulse duration such that the medium absorbs a greater quantity of energy from the laser pulse at an end of the pulse duration than at a beginning thereof. Such methods and systems may be used for various applications such as biology, medicine or material processing.

Abstract: Methods and systems for the controlled generation of microcavitation bubbles in a medium having a liquid phase are generally provided. Laser pulses having a time-dependent pulse parameter controllable over their duration are generated. The medium is irradiated with the laser pulses with a radiant exposure sufficient to initiate microcavitation within the medium during each laser pulse. The time-dependent pulse parameter of each laser pulse is controlled according to a generally positive variation over the pulse duration such that the medium absorbs a greater quantity of energy from the laser pulse at an end of the pulse duration than at a beginning thereof. Such methods and systems may be used for various applications such as biology, medicine or material processing.

Abstract: A low coherence interferometry probe system for evaluating proximity to a tissue layer, comprising a low coherence light source, an excitation optical fiber to bring the low coherence excitation light near the tissue layer and a collection optical fiber for capturing back-scattered light from the tissue layer. The probe system comprises an interferometry sub-system and a processor for evaluating a distance to the tissue layer. There is also provided a spectral absorption probe system for evaluating proximity to an artery, comprising a light source excitation light having a wavelength adapted for absorption by blood chromophores, an excitation optical fiber and a collection optical fiber. The probe system comprises a light detector and a processor for determining a distance to the artery using the Beer-Lambert law of light absorption with a value for surrounding tissue attenuation coefficient (?eff). A probe system combining low coherence interferometry and spectral absorption is also provided.

Abstract: A fiber optic dosimeter probe for sensing radiation dose including an optical fiber having a free end and a sensitive end, a window having a sensitive side and a rear side; a radiation sensitive layer between the sensitive end of the optical fiber and a sensitive side of the window, the radiation sensitive layer being made of a material having an optical property that changes with absorbed radiation dose, an amount of the material corresponding to a predetermined sensitivity to radiation; wherein the window and the optical fiber have a near water equivalent interaction with radiation and are MR compatible.

Abstract: A fiber optic dosimeter probe for sensing radiation dose including an optical fiber having a free end and a sensitive end, a window having a sensitive side and a rear side; a radiation sensitive layer between the sensitive end of the optical fiber and a sensitive side of the window, the radiation sensitive layer being made of a material having an optical property that changes with absorbed radiation dose, an amount of the material corresponding to a predetermined sensitivity to radiation; wherein the window and the optical fiber have a near water equivalent interaction with radiation and are MR compatible.

Abstract: A low coherence interferometry probe system for evaluating proximity to a tissue layer, comprising a low coherence light source, an excitation optical fiber to bring the low coherence excitation light near the tissue layer and a collection optical fiber for capturing back-scattered light from the tissue layer. The probe system comprises an interferometry sub-system and a processor for evaluating a distance to the tissue layer. There is also provided a spectral absorption probe system for evaluating proximity to an artery, comprising a light source excitation light having a wavelength adapted for absorption by blood chromophores, an excitation optical fiber and a collection optical fiber. The probe system comprises a light detector and a processor for determining a distance to the artery using the Beer-Lambert law of light absorption with a value for surrounding tissue attenuation coefficient (?eff). A probe system combining low coherence interferometry and spectral absorption is also provided.

Abstract: An optical detection system for identifying target bacterial cells in a food sample, comprising a first fluorescent nanoparticle dye labeling specifically the target cells. A second fluorescent dye reacts non-specifically with all bacterial cells. An imaging unit optically excites the fluorescent dyes and captures images of the sample for each of two different wavelength bands emitted as a result of the excitation of the dyes. A processing unit identifies the target cells from the sample and comprises an image processing unit for processing the images of the sample. A target cell identifier identifies the target cells in the images by detecting individual units present at a same location in both of the processed images. An output unit provides data related to the identified target cells in the sample. A method is also provided.

Abstract: A contrast marker for use in imaging applications, wherein the marker is sensitive to an applied magnetic field through the formation of radical pair species and wherein the marker is independently magnetically sensitive, optically sensitive, and magneto-optically sensitive.

Abstract: An apparatus for providing physiological information from an organism in disease diagnosis and treatment monitoring, for use in an MRI instrument. The apparatus operates on the concept of hybridized magneto-optical sensitivity. The MRI includes an MRI scanner and a controller for controlling the MRI scanner. The MRI scanner provides a magnetic field of at least 0.5T. The apparatus further includes a front end built of non-magnetic components, comprising light guides for illuminating a region of interest (ROI) and for collecting light emitted at said ROI; and a back-end comprising a light source for injecting light into said light guides; a light detector for receiving light collected at said ROI; and a processing and control unit for processing said light collected at said ROI.