An apparatus for performing an optical test of a sample comprises a receptacle for accepting a specimen slide, at least one illumination element, an optical lens, and image acquisition apparatus, all having fixed positioned relationships relative to said receptacle.

An apparatus for measuring a characteristic of a sample using a centrifuge and optical components is disclosed. The centrifuge may be a standard benchtop centrifuge. The optical components may be sized and dimensioned to fit, along with the sample, inside the centrifuge.

A spectral imaging system configured to obtain spectral measurements in a plurality of spectral regions is described herein. The spectral imaging system comprises at least one optical detecting unit having a spectral response corresponding to a plurality of absorption peaks of a target chemical species. In an embodiment, the optical detecting unit may comprise an optical detector array, and one or more optical filters configured to selectively pass light in a spectral range, wherein a convolution of the responsivity of the optical detector array and the transmission spectrum of the one or more optical filters has a first peak in mid-wave infrared spectral region between 3-4 microns corresponding to a first absorption peak of methane and a second peak in a long-wave infrared spectral region between 6-8 microns corresponding to a second absorption peak of methane.

An implantable apparatus for physiological measurement in a host organism has an implantable sample chamber having a measurement port and live cells that are treated to fluoresce in response to light having an excitation wavelength. An optical sensor housing implanted within the host organism has a window to convey excitation light output and receive fluorescent light; a coupling that couples the measurement port of the sample chamber to the window; an optical chamber partitioned into an excitation sub-chamber and a detection sub-chamber, wherein both sub-chambers are in optical communication with the window; an excitation source energizable to direct excitation light through the excitation sub-chamber and to the window; and a detector in the path of fluorescent light received from the live cells. A signal processing apparatus is energizable to acquire and process a detector signal and to transmit a processed signal that is indicative of fluorescent light energy.

The present invention is directed to a device consisting of a portable and multi-band UV light device that uses a combination of UVA, UVB, and UVC wavelength band of UV emitters. For detection, UV emitters are energized to a particulate collector that will fluoresce and glow when there is the presence of a wide range of different harmful aerosol droplet particles in the air that may be collected. This instant and positive visual detection with an available audio alarm alert indicates the presence of harmful aerosol droplet particles in the vicinity of this Instant Particulate Detector or IPD device, allowing the user to take immediate and corrective action. The user can also subsequently select disinfection utilizing UVC wavelength light to sterilize the particulate collector and Instant Particulate Detector or IPD device.

A remote illumination and detection method, node, and system is described. The remote illumination and detection method generates a detection message when motion is detected by a detector. The detector includes a wireless communications module that wirelessly transmits the detection message to a remote sensing device. The remote sensing device includes a camera having a field of view and wirelessly communicates with the detector. The remote sensing device then proceeds to generate an illumination instruction to illuminate an area within the field of view, when the remote sensing device receives the detection message. The remote sensing device transmits the illumination instruction to an illuminator. The illuminator wirelessly communicates with the remote sensing device. The method then illuminates an area near the illuminator, when motion is detected by the detector and the illumination instruction is received by the illuminator.

An implantable apparatus for physiological measurement in a host organism has an implantable sample chamber having a measurement port and live cells that are treated to fluoresce in response to light having an excitation wavelength. An optical sensor housing implanted within the host organism has a window to convey excitation light output and receive fluorescent light; a coupling that couples the measurement port of the sample chamber to the window; an optical chamber partitioned into an excitation sub-chamber and a detection sub-chamber, wherein both sub-chambers are in optical communication with the window; an excitation source energizable to direct excitation light through the excitation sub-chamber and to the window; and a detector in the path of fluorescent light received from the live cells. A signal processing apparatus is energizable to acquire and process a detector signal and to transmit a processed signal that is indicative of fluorescent light energy.

A coating and its application methods to coat at least one surface of a substrate, in particular cellulose-based substrates, and give it barrier properties to water, grease, oxygen, lights, moisture; heat resistance, a lower friction coefficient. The coating does not change the original properties of flexibility, biodegradability and recyclability of the original substrate. The coated substrate can be printed, can be recycled and exhibits unchanged properties in areas requiring folding of paper or cardboard.

A portable device for detecting and/or quantifying hemozoin by optical reflectance spectrophotometry, directly on the patient's skin, on tissues or in a liquid sample which comprises means for calibrating the device; at least one optical emitter to excite the sample; at least eight optical detectors to detect the reflectance spectrum of the sample; at least eight bandpass optical filters to filter the reflected light for each optical detector; wherein the optical filters and optical detectors are aligned with each other, wherein the emitter and optical detectors are positioned allowing reflection of the emitted light towards the optical detectors, wherein the optical filters and optical detectors comprise wavelengths between 400 nm and 800 nm; and a microcontroller configured to calculate a ratio between the reflectance values of the sample at each wavelength to detect the reflectance peaks. Also disclosed is a method of detecting and/or quantifying hemozoin by optical reflectance spectrophotometry.

An apparatus for measuring a characteristic of a sample using a centrifuge and optical components is disclosed. The centrifuge may be a standard benchtop centrifuge. The optical components may be sized and dimensioned to fit, along with the sample, inside the centrifuge.