The present invention relates to a kit with which a user can conveniently and hygienically collect bio-samples using a collecting rod. A collection kit for collecting a bio-sample using a collection rod according to the present invention comprises: a cap on the lower part of the central part of which a filter is detachably mounted, wherein a cover is formed on the upper part of the filter; a collection rod having a collection unit and a handle part; and a tube fastened with the cap and for accommodating the extraction solution.

The present invention relates to devices and methods for collecting liquid samples such as for removing a target liquid sample fraction from a larger liquid sample, e.g., from a biological sample. These devices and methods are particularly useful for rapidly and cost-effectively removing the buffy coat layer from an anticoagulated blood sample. These devices and methods have the advantage that the removal can be made on blood sample processed by ordinary centrifugation and do not require more complicated or costly processing techniques such as density gradient centrifugation.

The present disclosure relates to a sampling and sensing device and a method of using the sampling and sensing device for collecting and sensing chemical or biological analytes. The sampling and sensing device comprises a handle and a foldable head having a sampling region and a sensing region. A sensor chip may be disposed in the sensing region and a sampling wipe may be disposed in the sensing region. The sampling region is configured to collect an analyte. After the analyte is collected on the sampling region, the sampling and sensing device can be folded to make the sampling region in contact with or face the sensing region to transfer the analyte to the sensing region for analysis.

An all-in-one self test kit includes: a test tool having a reagent container adapted to store a diagnosis reagent therein and a diagnosis kit with a casing constituted of a first body and a second body and a diagnosis strip disposed inside the casing and having a sucking part for sucking the diagnosis reagent and a diagnosis part reacting to the diagnosis reagent sucked to the sucking part; a sub-body having a container insertion portion for inserting the reagent container thereinto and a kit insertion portion for inserting the diagnosis kit thereinto; a main body for inserting the sub-body thereinto; and a cap fastened and unfastened with an entrance of the main body to open and close the main body.

A biochemical detection device is revealed. The biochemical detection device includes a cap and a base arranged at two ends of a test tube correspondingly and a driving member disposed on the base. A sample-mounting slot and a test-paper-mounting slot separated from each other are formed in the test tube. After sampling, a sample obtained is placed into the sample-mounting slot and mixed with an extraction solution therein. A thin-film on the sample-mounting slot is penetrated by the driving member to allow the extraction solution mixed with the sample flowing into a cavity of the test tube to react with a test strip in the test-paper-mounting slot. The test cost is reduced and the detection efficiency is improved due to simple structure and easy operation. Moreover, the sample and the extraction solution are sealed in the test tube to prevent environmental pollution caused by spread of viruses.

A system and method facilitates transfers of specimen containers (e.g., vials with caps) between storage cassettes and carrier cassettes. The storage cassettes are designed to be stored in cryogenic refrigerators while the carrier cassettes are designed to be temporarily stored in a portable carrier. Identification information is read from wireless transponders carried by the specimen containers. Visual mappings of the positions of the specimen container in the cassettes is provided. Presence and position of the specimen containers in the cassettes is verified, and alerts of inconsistencies provided along with corrective commands. Inventories of specimen container and even specific specimen holders are provided.

The invention relates to a direct sample collection pad for assay diagnosis of a sample without introducing an additional sampling device into the assay method. This simplifies the system and method of sample collection and assay diagnosis, thus reducing waste and potential for patient irritation or injury during diagnosis.

A releasing stopper for a container, the stopper including a first body configured to be directly coupled with the container and comprising a coupling element for allowing the removable fastening of the stopper on the container; a second body, axially movable with respect to the first body along a predefined axis of the stopper and cooperating with the first body for defining a reservoir at least temporarily insulated from the outer environment, a membrane or collapsible septum constituting at least a portion of the reservoir wall, openable and/or breakable for allowing the communication of the reservoir with the outer environment. The stopper includes a first closed configuration, wherein the reservoir is insulated from the outer environment, and a second open configuration, wherein the reservoir is in communication with the outer environment, and wherein the membrane or collapsible septum is opened by a perforation or opening element distinct from the stopper.

A device for detecting nucleic acids in a biological sample has a sample port, a lysis station and a sample conduit configured to mix a sample and lysis agent to form a sample-lysis mixture, pass the sample-lysis mixture across a solid-state membrane to capture nucleic acids in the biological sample therein, and receive the remainder of the sample-lysis mixture in a waste chamber. The wash station is configured to introduce the wash solution following the sample-lysis mixture, pass the wash solution across the solid-state membrane to purify nucleic acids captured therein, and receive the wash solution from the solid-state membrane in the waste chamber. The elution station is configured to pass the eluent across the solid-state membrane, elute captured nucleic acids from the solid-state membrane, and pass the captured nucleic acids into one or more reaction chambers for amplifying and detecting the captured nucleic acids.

In some embodiments, the present invention is a device, including: a swab including an absorptive component attached to a stem, an extraction chamber configured to receive the swab and position the absorptive component of the swab configured to be in fluid communication with an extraction reagent, a test strip configured to be brought in fluid communication with the extraction reagent following extraction of the analyte from the biological sample, including: a sample receiving portion configured to accept a sample, a site on the strip where the analyte-specific labeled reagent has been incorporated, such reagent configured to bind the analyte from the biological sample, a capture portion configured to receive: the analyte from the biological sample and the analyte-specific labeled reagent so as to result in displaying a positive or negative result at the completion of the assay, and an adsorbent pad attached to the test strip.