The present disclosure relates generally to the field of analyzing a nucleic acid, such as RNA, in particular to the determination of at least one parameter of a sample composition comprising a nucleic acid, especially RNA, and optionally particles.

An optical particle detector is configured to simultaneously detect at least two particles within a useful detection volume. The detector includes a retina capable of receiving light rays scattered by the particles and a dark reticle interposed between the useful detection volume and the retina. The dark reticle includes at least one optical aperture allowing a passage towards the retina of a part of first scattered light rays and of a part of second scattered light rays, and an opaque surface on a periphery of the at least one aperture, preventing a passage towards the retina of another part of the first and second scattered light rays so as to project onto the retina first and second scattering diagrams separated from each other.

The present invention comprises methods and apparatus utilizing multiple detectors to measure properties related to light scattered by particles. Characteristics of particles are determined from the measured properties.

A particle detector including at least one channel intended to receive at least one fluid comprising particles and configured to receive at least one light beam emitted by a light source. The particle detector further including at least one photodetector network configured such that at least some photodetectors receive light beams emitted by the source and scattered by the particles present in the channel. The detector further comprises at least one optical system, each optical system s associated with a photodetector network and has at least one image focal plane and an optical axis. The detector is configured such that the image focal plane of the optical system is optically coupled to the photodetector network.

The present invention relates to a method for measuring characteristics of particles in solution and to a device for performing the same, wherein said method comprises the steps of providing a vessel comprising a sample of said particles in solution, wherein the sample has preferably a volume between 0.1 μL and 15 μL, providing a monochromatic light source and a light detector, transmitting light from the monochromatic light source to the vessel comprising the sample, detecting light emitted from the vessel with the light detector, and determining characteristics of said particles in solution comprised in the sample based on a dynamic light scattering (DLS) measurement.

According to an embodiment of the disclosure, a device for measuring a turbidity of a solution containing fine particles comprises a laser module emitting a laser beam of a predetermined wavelength band, a coupler outputting the laser beam along a first laser path and a second laser path divided from each other, a probe outputting the laser beam output along the first laser path to a container containing the solution, a light receiving element receiving, through the first laser path, the laser beam reflected or scattered by the fine particles in the solution and detecting the received laser beam, and a controller calculating the turbidity based on a strength of the laser beam detected by the light receiving element.

A liquid droplet and solid particle sensing device is provided that can measure the average droplet size in a spray. The present device uses a swirling flow to draw a particulate or a spry into the device for sizing and counting. The swirling flow is configured to keep all the particles away from the walls of the device and to concentrate them at the center of a flow channel to pass through the center of a light beam for high sensitivity and repeatability of the measurement.

A flow passage is irradiated with irradiation light, and light scattered from a particle contained in a sample passing through a detection region that is formed in a prescribed section is condensed at a position obtained by extending the prescribed section in a flow direction of the sample and captured at a prescribed frame rate. Then movement amount of the particle due to Brownian motion in directions perpendicular to the flow direction on the basis of captured plural frame images. Furthermore, a particle size of the particle is determined by correcting the movement amount using correction values that were obtained in advance corresponding to each of defocus positions for correcting errors of movement amount in the images caused by magnification.

A particle detection device includes a detection tube, a light emitter, a light receiver, and a processing unit. The detection tube is for a detection solution to pass through. The light emitter generates a detection light and emits the detection light to the detection solution. The light receiver receives the detection light scattered from the detection solution. The processing unit generates a received light intensity value according to the detection signal generated by the light receiver, and determines whether the received light intensity value is greater than a first threshold value: if greater, generating a detection result of particles; otherwise, generating a detection result of no particles. Then it provides a basis for semiconductor manufacturing companies to evaluate whether the detection solution can be used in a high-precision manufacturing processes, thereby optimizing the manufacturing process and improving the yield rate of the high-precision manufacturing process.

A nebulizer system capable of identifying when activation has occurred and aerosol is being produced. The nebulizer system monitors the inhalation and exhalation flow generated by the patient and communicates proper breathing technique for optimal drug delivery. The nebulizer system may monitor air supply to the nebulizer to ensure it is within the working range and is producing, or is capable of producing, acceptable particle size and drug output rate. When a patient, caregiver or other user deposits or inserts medication into the nebulizer, the nebulizer system is able to identify the medication and determine the appropriate delivery methods required to properly administer the medication as well as output this information into a treatment log to ensure the patient is taking the proper medications. The system is able to measure the concentration of the medication and volume of the medication placed within the medication receptacle, e.g., bowl.