A method and system for formation and withdrawal of a sample from a surface to be analyzed utilizes a collection instrument having a port through which a liquid solution is conducted onto the surface to be analyzed. The port is positioned adjacent the surface to be analyzed, and the liquid solution is conducted onto the surface through the port so that the liquid solution conducted onto the surface interacts with material comprising the surface. An amount of material is thereafter withdrawn from the surface. Pressure control can be utilized to manipulate the solution balance at the surface to thereby control the withdrawal of the amount of material from the surface. Furthermore, such pressure control can be coordinated with the movement of the surface relative to the port of the collection instrument within the X-Y plane.

A sampling device including a body (101) having a sampling chamber (102) adapted to receive a liquid (103) to be sampled. An inlet (104) on the body (101) allows liquid (103) to flow into the sampling chamber (102). A sampling port (105) on the body is adapted to receive a sampling pot or sample receiving container (106) for collecting liquid (103) from the sampling chamber (102) wherein the sampling port includes a safety shield (107) slidaby mounted to the inside (108) of the sampling port, the safety shield slidable between a blocking position in which access to the sampling chamber is restricted and an accessible position in which access to the sampling chamber is allowed.

A medical diagnostic system is provided to automate analysis of samples to predict a medical condition, such as pregnancy or chronic kidney disease. The system may provide test strip usage automation. The medical diagnostic system may include a sample collection component, collection cup contamination protection mechanism, sample volume control component, test strip reader component, which may be manifested as a lateral flow strip reader, flow reader, sample analytic component, data processing component, data communication component, networked data management component, and device cleaning mechanism. A method to automate analysis of samples to predict a medical condition using the medical diagnostic system is also provided.

The present disclosure relates to a portable device for collecting and/or concentrating in situ plankton microbiome, configured for submersion in water. The device herein disclosed is a compact and low-cost autonomous biosampler, with the ability to yield DNA samples for later genomic analysis.

An electrically passive device and method for in-situ acoustic emission, and/or releasing, sampling and/or measuring of a fluid or various material(s) is provided. The device may provide a robust timing mechanism to release, sample and/or perform measurements on a predefined schedule, and, in various embodiments, emits an acoustic signal sequence(s) that may be used for triangulation of the device position within, for example, a hydrocarbon reservoir or a living body.

A water sampling method includes acquiring, by an unmanned aerial vehicle, a sampling depth at which a water sample is to be taken. The sampling depth is sent by a portable electronic device or is a preset default depth. The method further includes calculating a descending distance based on the sampling depth and a distance between the unmanned aerial vehicle and a water surface, controlling the water sampler to descend for the descending distance, sampling, by the water sampler, a water sample, and sending a sampling result to a ground station or the portable electronic device.

A medical diagnostic system is provided to automate analysis of samples to predict a medical condition, such as pregnancy or chronic kidney disease. The system may provide test strip usage automation. The medical diagnostic system may include a sample collection component, collection cup contamination protection mechanism, sample volume control component, test strip reader component, which may be manifested as a lateral flow strip reader, flow reader, sample analytic component, data processing component, data communication component, networked data management component, and device cleaning mechanism. A method to automate analysis of samples to predict a medical condition using the medical diagnostic system is also provided.

Disclosed herein are kits and related methods for testing the oral microbiome of an animal for presence of one or more bacteria, e.g, associated with an oral disease or disorder, such periodontal disease, good oral health, or both, in a sample collected from the animal. The kit includes a sample collection device having a handle and a head opposite the handle. The kit further includes a dry container for storing the sample collection device. The container has an open position for receiving at least a portion of the head and a closed position.

To measure water content of liquid hydrocarbon using dried liquid hydrocarbon solvent, a liquid hydrocarbon sample is received from a flowline carrying the liquid hydrocarbon. The liquid hydrocarbon sample includes liquid hydrocarbon and liquid water at a concentration greater than a water saturation level. The liquid hydrocarbon sample is split into a first portion and a remainder portion. The first portion is dried to remove liquid water in the first portion. The remainder portion is mixed with the dried first portion causing the concentration of liquid water in a mixture of the remainder portion and the dried first portion to be below the water saturation level. After mixing the remainder portion with the dried first portion, a water content in the liquid hydrocarbon sample is determined.

The disclosure discloses a single-handed operable infant heel blood sampling device and its safety mechanism, including a push-pull rod and an actuating rod partially extending outside the blood sampler housing; the actuating rod has a second hook portion that can engage with the first hook portion; to perform blood sampling, push down the push-pull rod to disengage the buckle portion from the housing, causing the first hook portion to engage with the second hook portion on the first end of the actuating rod; then pull up the push-pull rod to pull the actuating rod, and the actuating rod thus releases a pre-compressed spring set inside the blood sampler housing, allowing the blade originally positioned in a first position inside the housing to slide out from a cutting port and then be retracted into a second position inside the housing.