A sample observation device includes a flow cell in which a fluid containing samples flows, an irradiation unit configured to irradiate the samples flowing in the flow cell with planar light, an image formation unit having an observation axis inclined with respect to an irradiation surface for the planar light, and configured to form an image of observation light generated in the sample due to the irradiation with the planar light, a two-dimensional imaging element configured to capture a light image including at least a cross section of the fluid among light images according to the observation light formed by the image formation unit, and outputs image data, and an analysis unit configured to analyze a light intensity profile of the sample in a flow direction of the fluid on the basis of the image data.

A universal and standalone rapid diagnostics test reader is disclosed herein that includes: a set of control electronics, an illumination component, an imaging component, a housing component, a wireless communication component, a rapid diagnostics test component, a universal rapid diagnostics test tray, wherein the tray can hold at least one rapid diagnostics test component having a shape and a size in a fixed position relative to the imaging component and the illumination component, and wherein the reader can accommodate more than one different rapid diagnostics test component, while using the same universal rapid diagnostics test tray. A universal rapid diagnostics test tray for a reader is also disclosed that includes: a rapid diagnostics test component; a tray component that is designed to operatively couple with the reader, wherein the reader can analyze more than one different rapid diagnostics test components, while using the same universal rapid diagnostics test tray; and a security component, wherein the security component operatively secures the rapid diagnostics test component in place on the tray component, wherein the tray component can hold the at least one rapid diagnostics test component having a shape and a size in a fixed position relative to the imaging component and the illumination component.

An information processing device includes a categorizing section configured to extract a material component image identified as a material component from plural images obtained by imaging a sample fluid containing a plurality of types of material components and flowing through a flow cell, and to categorize the extracted material component image by predetermined category, a count derivation section configured to derive a count of the material component per standard visual field, or derive a count per unit liquid volume of the material component contained in the sample fluid, for each of the categories based on the number of material component images categorized by the categorizing section, and a generation section configured to generate an all-component image in which the material component images are arranged according to the counts that have been derived by the count derivation section for each of the categories.

A system is provided for detecting non-metallic, non-aqueous substances in an aqueous sample, comprising a transmitter section, which emits electromagnetic radiation in the terahertz range towards the sample, a receiver section, which detects radiation components of said electromagnetic radiation which are modified by the sample and/or the substances therein and an evaluation section, which evaluates radiation components which are detected by the receiver section in order to establish whether non-metallic, non-aqueous substances are present or not in the aqueous sample, a transition of the aqueous sample from the liquid aggregate state into the solid aggregate state or vice versa taking place, radiation components which are modified respectively, for a plurality of different states of the aqueous sample, during this transition being detected by means of the receiver section, and the radiation components thus detected being evaluated by means of the evaluation section.

A method for optical imaging of single protein molecules including tethering single protein molecules via a flexible polymer linker to a glass slide having a surface coated with an indium tin oxide (ITO) so that the single protein molecules are tethered to the coated surface. The single protein molecules are driven into oscillation by applying an alternating electric field to the coated surface and the glass slide is located in the field of view of an objective lens. Incident light is directed onto the coated surface from an angle to generate an evanescent field and produce scattered light. The scattered light is collected and imaged by a CMOS imager to record a sequence of images of the scattered light. A Fast Fourier Transform (FFT) filter is applied to each pixel of the recorded image sequence to produce an oscillation amplitude image from which size, charge, and mobility of the plurality of single protein molecules can be determined.

The present invention relates to a hybrid imaging system for photodiagnosis and phototherapy and, more particularly, to a hybrid imaging system for photodiagnosis and phototherapy, which simultaneously acquires a visible ray image or a near-infrared ray image and a long wave infrared ray image by using an optical method. The hybrid imaging system for photodiagnosis and phototherapy according to the present invention includes a light distribution unit, a visible ray/near-infrared ray measurement unit, a long wave infrared ray measurement unit, and a light source unit, thereby simultaneously and quickly extracting a visible ray image, a near-infrared ray image, and a long wave infrared ray image without mutual distortion.

A universal rapid diagnostics test reader is disclosed and described herein that includes a set of control electronics, a digital camera component, an illumination component, a housing component, and a rapid diagnostics test tray, wherein the tray can hold at least one rapid diagnostics test having a shape and a size in a fixed position relative to the digital camera component and the illumination component, and wherein the reader can accommodate more than one different rapid diagnostics test. Methods are also disclosed that include: providing at least one first rapid diagnostics test having a first physical size, first feature and first format; providing at least one second rapid diagnostics test having a second physical size, second feature and second format; inserting the first rapid diagnostics test in a universal rapid diagnostics test reader; analyzing the first rapid diagnostics test using the universal rapid diagnostics test reader; removing the first rapid diagnostics test from the reader; inserting the second rapid diagnostics test in a universal rapid diagnostics test reader without any mechanical adjustments of the reader or without the use of any additional parts or additional inserts; and analyzing the second rapid diagnostics test using the universal rapid diagnostics test reader.

Provided are a gas detection device, an information processing device, and a program which enable a user himself/herself to easily determine whether a gas leak has occurred. The gas detection device includes: a first imaging section configured to capture an image of an inspection region in an infrared region; a second imaging section configured to capture an image of the inspection region in a wavelength range that is not influenced by light absorption by gas; and a hardware processor configured to perform image processing for detecting a gas in a first image captured by a first imaging section, and to perform control to simultaneously display various types of images on a display section from a display target image group including the first image, a second image captured by a second imaging section, and a third image subjected to the image processing.

An imaging system for a rotatable object includes an imaging unit configured to take a series of images of a portion of the rotatable object and a light source. The light source is directed at the rotatable object and is configured to generate pulses of light that illuminate the rotatable object during rotation of the rotatable object and allow the imaging unit to take the series of images of the rotatable object. The system also includes a synchronizer that monitors the rotational position of the rotatable object as it rotates, and a controller in communication with the imaging unit, the light source, and the synchronizer. The controller controls the operation of the imaging unit and/or the light source based upon the rotational position of the rotatable object such that each of the series of images is taken at the same rotational position of the rotatable object.

A first series of images of a first fluid is received. A first set of fluid characteristics of the first fluid is determined from the first series of images. A second series of images of a second fluid is received. A second set of fluid characteristics of the second fluid is determined from the second series of images. A match is determined to be found between the first set of fluid characteristics and the second set of fluid characteristics. The second fluid is identified based upon determining that the first set of fluid characteristics matches the second set of fluid characteristics.