The present disclosure provides an apparatus for sampling at least one analyte from a sampling fluid. The apparatus includes: a solid-phase microextraction (SPME) sampling instrument. A connector is attached to the SPME sampling instrument and is coupleable to an aerial drone. The apparatus includes a protective cover that is sized and shaped to at least partially surround the SPME sampling instrument. The SPME sampling instrument and the protective cover are movable in relation to each other between a protecting configuration and a sampling configuration. The SPME sampling instrument and the protective cover are (i) biased in the protecting configuration when the density of the fluid surrounding the SPME sampling instrument is less than the density of the sampling fluid; and (ii) biased in the sampling configuration when the density of the fluid surrounding the SPME sampling instrument is equal to or greater than the density of the sampling fluid.

Sampling probe devices, systems and methods for sampling frozen or solid meltable products. Such systems can include a heating element for placing against the frozen or solid product and a sampler with a cover fabricated at least partly from a microbial sampling medium so the cover absorbs a liquid sample from the product. Methods of sampling include heating the product and contacting the product with the cover until sufficient liquid sample is absorbed by the cover of the sampler. The cover can be weighed after sampling and compared to a before-sampling weight to confirm sufficient liquid was obtained. The sample can be tested as an aggregate sample that is representative of the lot or batch of product being sampled, including testing without an enrichment procedure. Systems utilizing automated heated-sampling plates and radiative heaters are also described.

Provided is a specimen collection tip having a novel structure, with which it is possible to collect a trace amount of a specimen with good quantitative precision. Also provided is a specimen preparation container having a novel structure, with which it is possible to dilute and prepare the specimen collected with the specimen collection tip with good quantitative precision. A specimen collection tip 10, wherein a specimen holding region 12 having a predetermined volume is provided inside the specimen collection tip 10, and in a distal end portion extending from a support part 15, there is formed a specimen collection hole 22 and an air vent hole 24 placing the specimen holding region 12 in communication with a surface 23. Also, a specimen preparation container 26 with a cap 30, wherein the specimen collection tip 10 is attached to the cap 30 at the support part 15.

A contact lens according to an embodiment of the present disclosure includes a lens section attachable to an eyeball, and one or a plurality of structure portions provided in the lens section and intended to accumulate tears. This makes it possible to, for example, measure an absorption spectrum of the tears, by emitting light toward the tears accumulated in the one or plurality of structure portions.

A sampling device comprises a handle and a collector. The collector is connected to the handle. The collector has a capillary function and is able to automatically suction a liquid reagent or sample. The sampling device is able to suction a required amount of the reagent or sample quickly, conveniently and quantitatively. The sampling device can be product conveniently, and may achieve micro-quantitative sampling. The reagent is stored in the collector of the sampling device in the form of a dry powder, which may achieve the individual packaging of the detection reagent.

Sampling probe devices and methods for sampling frozen or solid meltable products are provided herein. Such devices can include a sampling probe with heating element and a cover fabricated at least partly from a microbial sampling medium that fits over the probe and heating element so that when the heated probe is placed against the frozen or solid product, the cover absorbs a liquid sample from the product. Methods of sampling include heating the probe and contacting the product with the cover until sufficient liquid sample is absorbed by the cover. The cover can be weighed after sampling and compared to a before-sampling weight to confirm sufficient liquid was obtained. The sample can be tested as an aggregate sample that is representative of the lot or batch of product being sampled, including testing without an enrichment procedure. Systems utilizing automated heated-sampling plates and radiative heaters are also described.

The technology in part relates to diagnostic test devices and in part relates to test devices that include a lateral flow test strip. The technology in part relates to a test device system that incorporates sample collection, delivery, measuring, processing, incubation, flow regulation and analyzing a sample of interest in a single assembly.

Various methods and systems are provided for monitoring and control of soil conditions. In one example, among others, a method includes obtaining one or more aqueous sample from at least one suction probe within a soil substrate and analyzing the one or more aqueous sample to determine a chemical composition of the soil substrate. Amounts of an additive may be determined to adjust the chemical composition of the soil substrate. In another example, a method includes installing at least one suction probe within a soil substrate; drawing a vacuum to induce hydraulic conduction of at least one aqueous solution from the soil substrate; extracting one or more aqueous sample; and analyzing the one or more aqueous sample to determine a chemical composition.

The invention discloses an atomic fluorescence analysis method and device using water as a carrier fluid, belonging to the atomic fluorescence analysis in the field of analytical chemistry; the method is to replace hydrochloric acid and a reducing agent with water as the carrier fluid in the conventional sampling and fluid delivery process to carry the test liquid and reagent into the reactor to complete a reaction. The invention effectively overcomes the memory effect by using water as the carrier fluid and improves the determination sensitivity and accuracy, which saves a large amount of high-purity hydrochloric acid and reducing agent at the same time, greatly reducing the analysis cost, and significantly improving the operating environment, which is the innovation of atomic fluorescence analysis technology.

A device including a casing first part; a casing second part; a test strip having a sample pad; and a capillary sample collector, wherein the capillary sample collector has an open distal end configured to collect a fluid sample by capillary action and an open proximal end configured to dispense the fluid sample therefrom, wherein, the device is assembled such that the casing first part and the casing second part are joined, wherein a distal end of the casing first part and a distal end of the casing second part are sealed together in a fluid-tight manner, wherein the sample pad is positioned in proximity to the capillary dispensing end, wherein the dispensing end is positioned such that a dispensed fluid sample will be dispensed onto the sample pad, and wherein a dispensing angle between the dispensing and the sample pad of the test strip is less than 10 degrees.