Abstract: A clip-style pulse sensor may be adapted to apply limited, even pressure to a patient's tissue. A clip-style sensor is provided that reduces motion artifacts by exerting limited, uniform pressure to the patient tissue to reduce tissue exsanguination. Further, such a sensor provides a secure fit while avoiding discomfort for the wearer.

Abstract: An optical sensor having a cover layer, an emitter disposed on a first side of the cover, a detector disposed on the first side of said cover, and a plurality of stacked independent adhesive layers disposed on the same first side of the cover, wherein the top most exposed adhesive layer is attached to a patient's skin. Thus, when the sensor is removed to perform a site check of the tissue location, one of the adhesive layers may also be removed and discarded, exposing a fresh adhesive surface below for reattachment to a patient's skin. The independent pieces of the adhesive layers can be serially used to extend the useful life of the product.

Abstract: A spectrophotometric sensor assembly for non-invasive monitoring of a blood metabolite within a subject's body tissue is provided that includes a pad, a light source, and a light detector The light source is operative to emit light signals of a plurality of different wavelengths. The light detector is operative to detect light emitted by the light source and passed through the subject's body tissue. The light detector is at least partially enclosed in EMI shielding. In some embodiments, the light detector and EMI shielding are disposed in a detector housing that encloses the light detector and shielding. The housing is aligned with a detector aperture disposed in the pad.

Abstract: A portable critical care medical ventilator with autonomous control of oxygenation is provided. The system and method provide for significantly reducing the O2 required to maintain an adequate O2 concentration and as a result delivery of O2 to the body's tissues and does not require the clinician to enter initial values.

Abstract: In medical imaging, a fiducial marker facilitates tissue image correlation that allows for image analysis, normalization and correction of the optical exposure and spectral and spatial distribution in order to compensate for the surface reflections, sub surface tissue interactions and spatial orientation of the excitation and imaging axes to the subject tissue. Using a cross comparison, clinicians can model tissue image data in different forms in order to reference and compare data from various spectral components and or from different images. This may enhance human interpretation between images including the variations between images even when the spectral, spatial and optical conditions or the image resolution or sensitivity are compromised. Such may be used to assess cosmetic, moisturizing, therapeutic materials and treatments.

Abstract: A device for monitoring the efficiency of physical training in a human or animal includes a millimeter wave generator that generates millimeter wave radiation and a millimeter wave antenna that emits millimeter waves generated by the millimeter wave generator in a predetermined direction. The device includes a coupling element that couples the millimeter wave antenna to the millimeter wave generator and that transmits the millimeter wave radiation to the millimeter wave antenna. The device also includes a reference element that intermittently receives millimeter wave radiation from the millimeter wave antenna and a detector that detects millimeter wave radiation and produces a first data stream. The device further includes a processing unit that receives the first data stream and generates a signal indicating development of a body lactate level over time and an output device indicating the development of the body lactate level over time, to a user.

Abstract: A system for detecting haemozoin in a sample, said system including a light source for exciting the sample with an optical signal to generate a non-linear optical response, and a detector for detecting the generated non-linear optical response from the excited sample. A method for detecting haemozoin in a sample, the method including exciting the sample with an optical signal to generate a non-linear optical response from the sample, and detecting the emitted non-linear optical signal from the excited sample.

Abstract: According to embodiments, a medical sensor may be configured for use on mucosal tissue. Such a sensor may include a portion that facilitate the application of the sensor to the tissue and a portion that includes the optical components of the sensor. The two portions of the sensor may be reversibly coupled to one another. In embodiments, such sensors may be used to determine patient hematocrit.

Abstract: A physiological monitor for determining blood oxygen saturation of a medical patient includes a sensor, a signal processor and a display. The sensor includes at least three light emitting diodes. Each light emitting diode is adapted to emit light of a different wavelength. The sensor also includes a detector, where the detector is adapted to receive light from the three light emitting diodes after being attenuated by tissue. The detector generates an output signal based at least in part upon the received light. The signal processor determines blood oxygen saturation based at least upon the output signal, and the display provides an indication of the blood oxygen saturation.

Abstract: A probe holder mounting device for a biological photometric device includes: a probe holder having a plurality of probe mounting parts to which optical fiber probes are mounted; a band-like mounting device body having a plurality of insertion holes into which the probe mounting parts are to be inserted to fix the probe holder in position by means of the insertion holes; belts whose one ends are respectively connected to both longitudinal ends of the mounting device body and whose other ends are engaged with each other; and an adjusting belt connected to the mounting device body at a position where the probe holder is fixed in position in a lateral direction of the mounting device body.

Abstract: A device for clamping a hose line for determining the concentration of a constituent of blood in a hose line, in particular in the hose line of an extracorporeal blood circuit of an extracorporeal blood treatment apparatus, includes a clamping unit with two receiving elements and an electric motor-driven actuation mechanism. Actuation mechanism is constituted such that, when a clamping force is applied, the first and second receiving element can be moved from a position releasing the hose line into a position clamping the hose line. Moreover, the device comprises an unlocking mechanism which is constituted such that, by actuating an unlocking element, the actuation mechanism in the position clamping the hose line can be decoupled from electromotive drive. Unlocking mechanism makes it possible for the receiving elements to be transferred easily and rapidly by hand from the position clamping the hose line into the position releasing the hose line.

Abstract: There is provided a biological information measuring apparatus, which permits to release constriction of capillary vessels a human body to provide stable measurement results of biological information and a proper S/N ratio. The biological information measuring apparatus 1 includes a beam-emitting type sensor device 10 provided on a mounting unit 2 to optically measure biological information of a subject 4. The beam-emitting type sensor device 10 is placed in a position so as to be in a non-contact state relative to the subject 4 when measuring the biological information.

Abstract: The present disclosure relates to systems and methods for monitoring pain management using measurements of physiological parameters based on a PPG signal. A reference physiological parameter may be compared against a later measurement to identify a change in condition that may indicate a pain management problem.

Abstract: In order to provide a non-invasive and continuous concentration measurement with the technology of standard pulse oximeters, an a priori relationship is created, through an in-vivo tissue model including a nominal estimate of a tissue parameter indicative of the concentration of a blood substance. The a priori relationship is indicative of the effect of tissue on in-vivo measurement signals at a plurality of wavelengths, the in-vivo measurement signals being indicative of absorption caused by pulsed arterial blood. In-vivo measurement signals are acquired from in-vivo tissue at the plurality of wavelengths and a specific value of the tissue parameter is determined based on the a priori relationship, the specific value being such that it yields the effect of the in-vivo tissue on the in-vivo measurement signals consistent for the plurality of wavelengths. The specific value then represents the concentration of the substance in the blood.

Abstract: The present disclosure relates to systems and methods for monitoring pain management using measurements of physiological parameters based on a PPG signal. A reference physiological parameter may be compared against a later measurement to identify a change in condition that may indicate a pain management problem.

Abstract: A method for monitoring bladder function in an animal having a bladder, the method including positioning of a light emitter and a light detector on the animal's skin adjacent to the animal's bladder, emitting light at the bladder with the emitter while detecting light with the detector, and collecting data representative of detected light during bladder activity, to provide an indication of bladder function. Also provided are light shield apparatus and filter apparatus for near infrared spectroscopy (NIRS) bladder monitoring.

Abstract: The apparatus for evaluating biological function of the present invention has living body probes 1, a behavioral information measuring part 2 and an apparatus body 3, and it utilizes near-infrared spectroscopy to evaluate biological function; apparatus body 3 has a controller 8 for calculating (based on light information from living body probes 1) a variety of parameters derived from two-dimensional diagrams showing relationships between changes in oxyhemoglobin and changes in deoxyhemoglobin and two-dimensional diagrams showing relationships between absolute amounts of oxyhemoglobin and absolute amounts of deoxyhemoglobin, a behavioral information input part for entering behavioral information measured by means of behavioral information measuring part 12, and a display part 10 for performing various types of image displays based on various parameters calculated by means of controller 8 and/or behavioral information entered in the behavioral information input part.

Abstract: The present invention provides a method of measuring the concentration of a compound and a value of oxygen saturation in the blood of a part of a subject. Also provided is a device for carrying out the disclosed method. The method relates to measuring the concentration of a compound and a value of oxygen saturation in the blood part of a subject, and correlating the measured concentration of the compound and/or the value of oxygen saturation in the blood to a specific clinical condition. The device comprises a polychromatic light source, a receptor, a detector, and a processing system comprising a calibration algorithm.

Abstract: A spectroscopic system for determining a property of a fluid flowing through a volume of interest underneath the surface of the skin of a patient is described. The spectroscopic system comprises: a probe head having an objective for directing an excitation beam into the volume of interest and for collecting return radiation from the volume of interest; a base station having a spectroscopic analysis unit and a power supply; and a cable connecting the probe head and the base station for transmission of the return radiation from the probe head to the base station and for providing the probe head with power from the power supply of the base station.

Abstract: A measuring apparatus, a physiological sensor, and an interface unit for determining blood parameters of a subject are disclosed. The sensor comprises an emitter unit comprising a first plurality of emitter elements configured to emit radiation at a second plurality of wavelengths and a detector unit configured to receive radiation generated by the emitter elements and transmitted through the tissue of the subject, wherein the detector unit is further configured to produce electric measurement signals indicative of absorption caused by the blood of the subject. The sensor or the interface unit is provided with a memory that stores emitter activation information for at least a third plurality of wavelengths, thereby to enable a monitoring unit operably connectable to the physiological sensor to employ a combination of wavelengths selected from the third plurality of wavelengths, wherein the third plurality is equal to or smaller than the second plurality.

Abstract: Embodiments of the present system and methods measure a concentration of a substance, such as glucose, in a body. The present embodiments measure a first amount of infrared (IR) radiation absorbed or emitted from the body in a first wavelength band, and a second amount of IR radiation absorbed or emitted from the body in a second wavelength band. The present embodiments also measure a temperature at a surface of the body and an ambient temperature. A normalized ratio parameter is calculated from the four measurements, and the concentration of the substance in the body is calculated by correlating the normalized ratio parameter with the body surface temperature and the ambient temperature using an empirically derived lookup table. Also disclosed are methods for creating the empirically derived lookup table.

Abstract: A sensor is provided that is appropriate for optical detection of dissolved carbon dioxide. Such a sensor may be used for transcutaneous detection of carbon dioxide in the tissue. Alternatively, such sensors may be inserted into the tissue. Detection of dissolved carbon dioxide in the tissue may serve as a useful clinical marker for physicians.

Abstract: Method for the continuous measurement of the glucose concentration in blood undergoing pulsational flow, with the steps:—determination of a value for the glucose concentration for a first measurement cycle, and—repetition of the determination of this value in subsequent measurement cycles, where there is multiple detection, within each measurement cycle, of the transmittance and/or scattering power of the blood for at least two incident NIR wavelengths, calculation of an indicator value depending on the blood glucose concentration, and ascertaining the blood glucose concentration by comparing the indicator value with a previously determined calibration table, determination of the blood temperature during the detection of the transmittance and/or scattering power,—continuous measurement of the pulse duration of the pulsational blood flow, where the duration of the measurement cycle is arranged to keep in step as integral multiple of the pulse duration, where the first of the at least two NIR wavelengths is sel

Abstract: A system for enabling reliable skin contact of an electrical wearable device associated with physiological information detected by the wearable device. The system includes a wearable tightness detector powered by a power supply for the wearable device, and a controller for monitoring electrical signals emanating from the power supply and the wearable tightness detector. Also, at least two thermocouples electrically coupled to the wearable tightness detector, along with at least two skin contact modules electrically coupled to the wearable tightness detector. The at least two thermocouples provide the physiological information detected by the wearable device in relation to a subject. An adjustable wearable band is included in the system. The tightness of the wearable band is detected by the wearable tightness detector and an output signal from the at least two thermocouples to ensure reliable physiological information from the subject during the subject's wearing of the wearable device.

Abstract: A physiological parameter tracking system has a reference parameter calculator configured to provide a reference parameter responsive to a physiological signal input. A physiological measurement output is a physiological parameter derived from the physiological signal input during a favorable condition and an estimate of the physiological parameter according to the reference parameter during an unfavorable condition.

Abstract: A sensor used to measure physiological characteristics of body tissues is provided. The physiological sensor includes a first light source assembly having a first light source in parallel with a second light source. Each of the first light source and the second light source have an anode and a cathode. A second light source assembly includes a third light source in parallel with a fourth light source. Each of the third light source and the fourth light source have an anode and a cathode. The anode of the first light source is electrically connected to the cathode of the second light source, the anode of said third light source, and the cathode of said fourth light source. The anode of the third light source is electrically connected to the cathode of the fourth light source.

Abstract: A tissue profile wellness monitor measures a physiological parameter, generates a tissue profile, defines limits and indicates when the tissue profile exceeds the defined limits. The physiological parameter is responsive to multiple wavelengths of optical radiation after attenuation by constituents of pulsatile blood flowing within a tissue site. The tissue profile is responsive to the physiological parameter. The limits are defined for at least a portion of the tissue profile.

Abstract: The present invention pertains to a method and apparatus for hemometry in humans. Pressure is applied proximal to a target area in human tissue. A modulated optical signal based on a digital code sequence is transmitted to the target area. A temporal transfer characteristic is derived from the modulated optical signal. Concentration of an analyte is determined based on the temporal transfer characteristic.

Abstract: Provided is an information processing apparatus including a judgment unit for using measurement data in relation to reflectance of light obtained by irradiating a surface of a living body of a subject with light of a predetermined wavelength to judge a condition of a blood vessel and/or a condition of blood flow of the living body in accordance with a color phase corresponding to the reflectance of light.

Abstract: A living body measuring instrument having a sub-mount on which plural light-emitting devices oscillating at different wavelengths are mounted in proximity, one optical output monitoring device that detects the optical outputs of these light-emitting devices and a light source mounted on the same heat sink which are housed in one can-package, a light-receiving device that detects a signal from a living body, and a circuit that separates the optical output signals from the light-emitting devices, wherein at least one light-emitting device has a light-emitting layer including a In1-xGaxAsyP1-y quantum well layer and a barrier layer on a GaAs substrate, the strain ? satisfies 0.4%???1.4%, wherein y in the composition satisfies 0.10?y?0.45, and the wavelength of the emitted light is from 700 nm to 760 nm.

Abstract: The present invention provides an optical measuring apparatus and an optical measuring method for being able to correct the influence of a superficial tissue to be able to accurately measure a degree of light absorption of a deep layer tissue such as a human body and fruits, and a storage medium that stores an optical measuring program. The optical measuring apparatus includes a probe, and the probe includes one light emitting diode and two photodiodes. In a configuration of the optical measuring apparatus, one of the photodiodes receives light which is emitted from the light emitting diode and transmitted through a superficial layer and a deep layer of a tissue, and the other photodiode receives light having a deep layer transmission distance different from that of the light received by one of the photodiodes. The light received by the other photodiode is also transmitted through the superficial layer and deep layer of the tissue.

Abstract: Systems and methods for analyzing sublingual microcirculation perfusion and identifying particular nerve tracts. In exemplary embodiments, a digital micro-mirror device is configured to direct a reflected light to a subject area and a controller is configured to alter a parameter of the reflected light.

Abstract: The present disclosure relates generally to patient monitoring systems and, more particularly, to wireless patient sensors and patient monitors. In an embodiment, a patient sensor device includes an emitter configured to emit light into a tissue of a patient as well as a detector configured to detect the light from the tissue of the patient and produce a corresponding electrical signal. The patient sensor also includes signal processing circuitry configured to receive and convert the electrical signal of the detector into detector signal data. The patient sensor also includes a wireless module communicatively coupled to a patient monitor and configured to transmit a physiological parameter value, the detector signal data, or both, to the patient monitor. The patient sensor also includes a processor configured to determine whether the patient sensor or the patient monitor should calculate the physiological parameter value based, at least in part, on the detector signal data.

Abstract: Methods and apparatus for video rate or near video rate quantitative imaging of tissue physiological and morphological properties from visible/NIR light spectral images obtain rapid multi-spectral reflectance images by illuminating with a series of spectra containing multiple narrow wavelength bands. An iterative light-transport based inversion algorithm may be applied for correcting the intensity of the spectral images from the geometry/coupling effect as well as from the scattering amplitude distortions. The method can produce video rate absorption as well as scattering spectral images that can be further analyzed very rapidly, using matrix-based rapid inversion algorithms to produce more detailed quantitative images containing information relevant to tissue physiology and morphology.

Abstract: In an embodiment, a sensor may be adapted to provide information related to its position on a patient's tissue. postioned adjacenta sensor may be provided with tissue contact sensors which may relay a signal related to the proper placement of the sensor relative to the tissue of a patient. Such a sensor may be useful for providing information to a clinician regarding the location of the sensor in relation to the skin of a patient in order to provide improved measurements.

Abstract: A method for analysis of blood components or parameters is disclosed where a probe having an excitation outlet and a response inlet is placed in proximity to or in contact with a tissue of an underside of a patient's tongue over a big vein in the tongue so that an excitation signal exits the outlet, produces a response which enters the inlet for detection and analysis.

Abstract: Embodiments of the present disclosure relate to a system and method for determining a likelihood of successful ventilator weaning for a patient undergoing mechanical or assisted ventilation. Specifically, embodiments provided herein include methods and systems for determining or predicting weaning readiness in a patient based on physiological parameters determined via photoplethysmography.

Abstract: An embodiment of a light homogenizing apparatus having one or more emitters (110, 120) incident on a light mixing element. The emitters including at least one laser light source. The light mixing element comprising a diffuser (130) followed by an internally reflective light guide (160). This apparatus substantially homogenizes light from all emitters (110, 120) before light exits the internally reflective light guide (160) where it could then be incident on living tissue for use in photoplethysmographic measurement. Other embodiments are described and shown.

Abstract: A method and apparatus for noninvasive measurement of a human body component, such as glucose, in vivo, include near infrared spectroscopy based laser sources driven at a carrier frequency lying within the characteristic absorption of the component. The apparatus also drives the laser diodes with a modulation frequency to generate a frequency difference between the measuring light and reference beam, and the interference of the two beams results in a beat frequency signal, which frequency is proportional to the optical path difference between the measuring light and the reference beam. The scattering lights from human tissue with different optical lengths are simultaneously detected and selected based on the beat frequency. The method is a convenient embodiment of the floating reference principle, which takes advantage of optical length selection.

Abstract: A medical sensor that allows wrapping about an applied part while maintaining the alignment of the detector and emitter is provided. The medical sensor includes a carrier band that can accommodate variably sized applied parts without misaligning the detector and emitter. The medical sensor can provide space between the skin of the applied part and the emitter and detector. The medical sensor carrier band can be designed with a flexible region and thicker mounting sections that act as spring-loaded mounts when the carrier band is secured in a wrapped position.

Abstract: Embodiments disclosed may include a sensor which may be adapted to provide information related to its position on a patient's tissue. A sensor may be provided with tissue contact sensors which may relay a signal related to the sensor's proper placement adjacent a patient's tissue. Such a sensor may be useful for providing information to a clinician about the status of a sensor, such as if a sensor may be located more closely to the tissue in order to provide improved measurements.

Abstract: A reflection-detector sensor position indicator comprises emitters that transmit light having a plurality of wavelengths. A detector outputs a sensor signal. At least one reflection detector outputs at least one sensor position signal. An attachment assembly attaches the emitters, the detector and the reflection detector onto a tissue site. A sensor-on condition indicates that the attachment assembly has positioned the emitters generally centered over a fingernail, the detector on a fingertip opposite the fingernail and the reflection detector over the fingernail. The sensor signal, in the sensor-on condition, is at least substantially responsive to the emitter transmitted light after attenuation by pulsatile blood flow perfused within a fingernail bed underneath the fingernail. The sensor position signal, in the sensor-on condition, is at least substantially responsive to the emitter transmitted light after reflection off of the fingernail.

Abstract: A method of determining a volume of a platelet includes: (a) illuminating the platelet with incident light at a plurality of illumination wavelengths; (b) obtaining at least one two-dimensional image of the platelet corresponding to each illumination wavelength; (c) for each illumination wavelength, determining a mean optical density and a maximum optical density for the platelet; (d) determining an area of the platelet; (e) for each illumination wavelength, determining a volume of the platelet; (f) for each illumination wavelength, determining an integrated optical density for the platelet; and (g) determining the volume of the platelet based on a weighted combination of the area of the platelet, the volumes of the platelet corresponding to each of the illumination wavelengths, and the integrated optical densities for the platelet corresponding to each of the illumination wavelengths.

Abstract: An article of manufacture and method for controlling the application of a coupling agent, such as a silicone oil or mineral oil, on a surface of a tissue prior to contacting the tissue with an apparatus for non-invasive optical measurement of the concentration of an analyte. The article ensures that a specific quantity of the coupling agent is deposited in a uniform layer over the entire target area of the tissue, thereby enhancing both the optical signal and the repeatability of thermal and optical coupling with the components of the apparatus.

Abstract: A method is provided for determining contact of a sensor with a patient's tissue. The method comprises comparing the intensity of detected light at a first wavelength to a threshold, wherein the first wavelength is not used to determine a physiological characteristic of the patient, and determining if the sensor is in contact with the patient's tissue based on the comparison. In addition, a method is provided for determining the amount of light shunting during operation of the sensor. The method comprises comparing the intensity of detected light at a first wavelength to a threshold, wherein the first wavelength is not used to determine a physiological characteristic of the patient, and determining the amount of light shunting based on the comparison.

Abstract: Optical sensor devices, image processing devices, methods and computer readable code computer-readable storage media for detecting biophysical parameters, chemical concentrations, chemical saturations, vital signs and physiological information such as a malignant condition are provided. The optical sensor includes an array of photodetectors, where each photodetector is configured to detect a spectrum of light. Exemplary physiological parameters include but are not limited to a pulse rate, a biophysical or physiological property of skin, a cardiovascular property, a property related to an organ such as the liver or the kidneys, and a temperature fluctuation. Alternatively one or more parameters are detected from a food item such as food tissue, a consumable beverage such as an alcoholic beverage, a dairy product, wine, a baked good, a fruit and a vegetable.

Abstract: An object of the present invention is to provide a noninvasive constituent concentration measuring apparatus and constituent concentration measuring apparatus controlling method, in which accurate measurement can be performed by superimposing two photoacoustic signals having the same frequency and reverse phases to nullify the effect from the other constituent occupying large part of the object to be measured. The constituent concentration measuring apparatus according to the invention includes light generating means for generating two light beams having different wavelengths, modulation means for electrically intensity-modulating each of the two light beams having different wavelengths using signals having the same frequency and reverse phases, light outgoing means for outputting the two intensity-modulated light beams having different wavelengths toward a test subject, and acoustic wave detection means for detecting an acoustic wave generated in the test subject by the outputted light.

Abstract: A system for measuring a physiological parameter of blood in a patient is presented. The system includes a transmission module configured to emit a plurality of photon density waves into tissue of the patient from a plurality of modulated light sources. The system also includes a receiver module configured to detect characteristics of the plurality of photon density waves. The system also includes a processing module configured to identify characteristics of a pulsatile perturbation of the tissue based on the characteristics of the plurality of photon density waves, and identify a value of the physiological parameter based on at least the characteristics of the pulsatile perturbation of the tissue and the characteristics of the plurality of photon density waves.

Abstract: A simple noninvasive technique that is capable of very accurate and fast blood analyte, e.g., glucose, level monitoring is provided. Fluctuation in the levels of glucose and other analytes affect the refractive index of blood and extra cellular fluid in biological tissue. Given that the propagation speed of light through a medium depends on its refractive index, continuous monitoring of analyte levels in tissue is achieved by measuring characteristics of the tissue that can be correlated to the refractive index of the tissue. For instance, the frequency or number of optical pulse circulations that are transmitted through an individual's tissue of known thickness within a certain time period can be correlated to an individual's blood glucose level.

Abstract: A system for continuous in vivo biosensing of specific analyte molecule concentrations based on the dynamic optical properties of electronic polymers is disclosed. The biosensor system includes at least one implant member subcutaneously exposed to the interstitial fluid of the subject, and a reader member at least temporarily positioned over the implant member to probe it with light of specific wavelengths through the skin. The system has many potential applications, including the real-time monitoring of blood glucose levels in diabetics as a method to supplement or replace conventional capillary blood testing.