Abstract: The present invention provides methods of identifying subjects that are suitable for high-dose cyclophosphamide treatment.

Abstract: The present invention relates to methods of treating an autoimmune disorder, using a lymphocytotoxic but hematopoeitic cell sparing high-dose pulsed amount of an oxazaphosphorine drug in combination with immune therapeutics such as, for example, monoclonal antibodies that selectively bind B-cell specific antigens.

Abstract: The present invention relates to methods of treating a cancer and in particular, a B-cell derived cancer, using a lymphocytotoxic but hematopoeitic cell sparing high-dose pulsed amount of an oxazaphosphorine drug, either alone, or in combination with immune therapeutics such as, for example, monoclonal antibodies that selectively bind B-cell specific antigens.

Abstract: A finger biometric sensor may include a finger biometric sensing layer having an upper major surface and at least one sidewall surface adjacent thereto. The finger biometric layer may be for generating signals related to at least one biometric characteristic of the user's finger when positioned adjacent the first major surface. The finger biometric sensor may also include a piezoelectric transducer layer coupled to the at least one sidewall surface of the finger biometric sensing layer and a plurality of electrically conductive layers coupled to the piezoelectric transducer layer to define transducer electrodes. At least one of the electrically conductive layers may also cooperate with the finger biometric sensing layer for sensing the at least one biometric characteristic.

Abstract: This disclosure relates, at least in part, to methods of eliminating adverse immune reactions in a subject in need thereof including those associated with autoimmune diseases, allergic reactions and transplant rejection, including administration of a lymphocytotoxic non-myeloablative amount of a oxazaphosphorine drug to the subject.

Abstract: An electronic device includes a portable housing, an optical source carried by the portable housing, and an optical dispersion finger sensor carried by the portable housing. The sensor may include an integrated circuit substrate adjacent the optical source so that light propagates into and is dispersed by the user's finger with at least a portion of the dispersed light exiting the user's finger in a direction toward the integrated circuit substrate. The sensor may also include at least one optical dispersion sensing pixel on the substrate for sensing dispersed light from the user's finger to be used to generate optical dispersion biometric data from the user's finger. A processor may be connected to the one or more sensing pixels to enable at least one device function based upon the optical dispersion biometric data.

Abstract: A finger biometric sensor may include a finger biometric sensing layer having an upper major surface and at least one sidewall surface adjacent thereto. The finger biometric layer may be for generating signals related to at least one biometric characteristic of the user's finger when positioned adjacent the first major surface. The finger biometric sensor may also include a piezoelectric transducer layer coupled to the at least one sidewall surface of the finger biometric sensing layer and a plurality of electrically conductive layers coupled to the piezoelectric transducer layer to define transducer electrodes. At least one of the electrically conductive layers may also cooperate with the finger biometric sensing layer for sensing the at least one biometric characteristic.

Abstract: An optical dispersion finger sensor includes an integrated circuit substrate, and an optical source for directing light into a user's finger when positioned adjacent the integrated circuit substrate. The light may propagate into and be dispersed by the user's finger so that at least a portion of the dispersed light exits the user's finger in a direction toward the integrated circuit substrate. The sensor may also include at least one optical dispersion sensing pixel on the integrated circuit substrate for sensing dispersed light from the user's finger. A processor may be connected to the optical dispersion sensing pixels for generating optical dispersion biometric data based upon dispersed light from the user's finger.

Abstract: A finger sensor may include an integrated circuit substrate for receiving a user's finger adjacent thereto, and a plurality of infrared sensing pixels on the substrate. Each infrared sensing pixel may include at least one temperature sensor, at least one infrared antenna, and at least one conductive via interconnecting the at least one temperature sensor and the at least one infrared antenna. The infrared sensing pixels are for sensing infrared radiation emitted from subdermal features when the user's finger is positioned adjacent the integrated circuit substrate. The finger sensor apparatus may also include a processor connected to the infrared sensing pixels for generating infrared biometric data based upon infrared radiation emitted from the subdermal features of the user's finger.

Abstract: A multi-biometric finger sensor may include infrared sensing pixels on an integrated circuit substrate for sensing infrared radiation emitted from the user's finger, and at least one other finger biometric characteristic sensor on the integrated circuit substrate for sensing a finger biometric characteristic different than the infrared radiation emitted from the user's finger. The sensor may also include a processor connected to the plurality of infrared sensing pixels and the at least one other finger biometric characteristic sensor. Each of the infrared sensing pixels may include at least one infrared antenna and at least one temperature sensor connected thereto.

Abstract: A multi-biometric finger sensor includes a plurality of electric field fingerprint sensing pixels on an integrated circuit substrate for sensing an image of the user's finger, and at least one other finger biometric characteristic sensor on the integrated circuit substrate for sensing a finger biometric characteristic different than the image of the user's finger. Each of the electric field fingerprint sensing pixels may include an electric field sensing electrode, a guard shield surrounding the electric field sensing electrode, and an amplifier connected between the electric field sensing electrode and the guard shield. The sensor may also include a finger drive electrode adjacent the plurality of electric field sensing pixels, and a processor connected to the electric field fingerprint sensing pixels and the at least one other finger biometric characteristic sensor.

Abstract: A finger sensor apparatus may include an integrated circuit substrate for receiving a user's finger adjacent thereto, and a plurality of infrared sensing pixels on the integrated circuit substrate. The infrared sensing pixels are for sensing infrared radiation naturally emitted from subdermal features when the user's finger is positioned adjacent the integrated circuit substrate. The finger sensor apparatus may also include a processor connected to the infrared sensing pixels for generating infrared biometric data based upon infrared radiation naturally emitted from the subdermal features of the user's finger.

Abstract: A multi-biometric finger sensor may include at least one optical dispersion sensing pixel on an integrated circuit substrate for sensing dispersed light from the user's finger, and at least one other finger biometric characteristic sensor on the integrated circuit substrate for sensing a finger biometric characteristic different than the dispersed light from the user's finger. The sensor may also include a processor connected to the at least one optical dispersion sensing pixel and the at least one other finger biometric characteristic sensor.

Abstract: Production of a stem cell enriched cell composition using essentially non-toxic methodology comprising contacting a cell mixture with a cell-permeable, fluorescent non-polar compound that reacts upon contact with intracellular enzyme aldehyde dehydrogenase or phosphokinase found substantially exclusively in stem cells so as to form a biocompatible fluorescent product that is polar and non-permeable to the membrane of the stem cells, and isolating the cells containing the marker by fluorescent cell sorting.

Abstract: A system for detecting and tracking targets or objects located in the earth's shadow. The system senses and processes starlight from one or more stars. More particularly, the stellar background provides an illumination source with which targets are detected as they eclipse or occlude one or more stars. The system includes a receiver which collects incident starlight and a sensor, coupled to the receiver, for sensing the collected starlight focused thereon by the receiver and for providing a sensor output signal indicating the intensity of the sensed starlight. A signal processor, responsive to the sensor output signal, provides a target detection signal indicating whether a target has crossed the line of sight between the receiver and one or more stars. The signal processor may be further responsive to a stellar background catalog for providing the target detection signal with bearing information indicating the bearing of a detected target.

Abstract: A bicycle mudguard includes a plastic moulding comprising a main aerofoil section and at one end of which a ball is provided. The ball cooperates with a pair of clamp members to form a ball and socket fitment for adjustable and releaseable attachment of the mudguard to one of mariaus members of the bicycle frame.

Abstract: A fluoroscopic image is processed digitally using a television camera operating at a frame rate of at least 30 frames per second viewing the image and providing an analog video output, a digitizer which digitizes the analog video output to provide digital information representative of the analog signal, a plurality of frame processors which carry out arithmetic and logical operations on the digital image information and are operable at the frame rate of the television camera coupled to the output of the digitizer, a 2-D filter operable at the frame rate of the television camera coupled to said frame processors, a converter and interface to convert digital image information processed in the frame processors and 2-D filter back into an analog signal and television display coupled to the output of the converter for displaying the processed signal.

Abstract: A fluoroscopic image is processed digitally using a television camera operating at a frame rate of at least 30 frames per second viewing the image and providing an analog video output, a digitizer which digitizes the analog video output to provide digital information representative of the analog signal, a plurality of frame processors which carry out arithmetic and logical operations on the digital image information and are operable at the frame rate of the television camera coupled to the output of the digitizer, a 2-D filter operable at the frame rate of the television camera coupled to said frame processors, a converter and interface to convert digital image information processed in the frame processors and 2-D filter back into an analog signal and television display coupled to the output of the converter for displaying the processed signal.