Methods and devices for testing a biological sample are provided. A tape includes multiple channels or reservoirs having inlet and outlet ports. One tape having biological sample disposed in its channels is temporarily mated with another tape having reagents disposed in its channels via a serpentine belt and compression roller assembly. Pulsed fluidic operations combine the reagents and the biological sample for subsequent observation, detection, storage and/or disposal. Fluidic transfer is provided in a uniform operation or in conjunction with a sensory feedback assembly.

A method for analyzing a sample collected from a surface, the method comprising placing at least a portion of a substrate having a pressure sensitive adhesive layer containing the sample in a holder, adding a spray solvent to the sample-containing pressure sensitive adhesive layer, and analyzing the sample contained in the pressure sensitive adhesive layer and the spray solvent using paper spray mass spectrometry.

Condensation associated with the collection and identification of airborne particles is detected. Upon the detection, one or more condensation countermeasures are triggered to address the condensation.

An airborne biological particle monitoring device collects particles floating in air. The monitoring device includes a processor, a camera sensor, and a set of approximately monochromatic illumination sources that correspond to a set of spectral curves. The camera sensor captures images of the particles providing a spectral analysis of the particles. The processor analyzes the images to identify the collected particles.

A trace analyte collection swab having a collection surface at least partially coated with a microscopically tacky substance to enhance pick-up efficiency is described. In embodiments, the truce analyte collection swab comprises a substrate including a surface having a trace analyte collection area and a coating disposed on the surface of the substrate in the trace analyte collection area. The coating is configured to be microscopically adhesive to collect particles of the trace analyte from a surface when the trace analyte collection area is placed against the surface. In one embodiment, the coating comprises Polyisobutylene.

Provided here are systems and methods for microtomy, including a microtome and a transfer tape system. The microtome can be used for sectioning a tissue section from a tissue block. The transfer tape system can include a transfer tape configured to adhere to a front face of the tissue block and collect one or more tissue sections sectioned by the microtome and to transfer the one or more tissue sections to one or more slides; and at least one tension device for controlling tension and an angle of the transfer tape relative the tissue block or the one or more slides. The at least one tension device can be configured to maintain the transfer tape at a predetermined tension or maintain the transfer tape at a predetermined angle relative to the tissue block or the one or more slides.

Assay system including assay apparatus and handheld single use assay devices for ElectroMagnetic Radiation (EMR) examination of a specimen. The assay devices include a housing, a specimen slide for elevation from an initial lowermost specimen introduction position to a final uppermost specimen examination position and a built-in liquid reagent dispensing arrangement for dispensing liquid reagent on the specimen slide. The assay apparatus automatically actuates an assay device and includes an imaging arrangement for obtaining specimen images.

Provided is an adhesive tape for collecting skin indigenous microorganisms, the adhesive tape being capable of providing improved collection yields of skin indigenous microorganisms on a skin surface. This adhesive tape is for collecting skin indigenous microorganisms, is used to collect skin indigenous microorganism on a skin surface, and comprises a base material and an adhesive layer provided on at least a portion of a surface of the base material, wherein the adhesive layer contains an adhesive, and the adhesive contains a rubber adhesive. The adhesive tape has an adhesive strength of 10.0 N or more when a 12 mm-wide test piece thereof is pressure-bonded to a Bakelite plate by one reciprocation of a 2 kg roller and then measured for adhesive strength at a pulling speed of 300 mm/min and a pulling angle of 90° according to JIS Z 0237: 2009, and the adhesive tape has a peel strength of 0.25 N or more when a 12 mm-wide test piece thereof is measured using a silicone-treated fine paper sheet as a release sheet and measured for peel strength at a pulling speed of 300 mm/min and a pulling angle of 180° according to JIS Z 0237: 2009.

The present subject matter relates to systems, devices, and methods for agricultural sample collection. In one aspect, a sample collection system includes an aerial robotic platform, an arm assembly coupled to the aerial robotic platform and comprising an arm that extends away from the aerial robotic platform, and a sample collector connected to a distal end of the arm, wherein the sample collector is configured to selectively remove one or more samples of agricultural material from a plant to be analyzed.

Various implementations, systems and methods are disclosed for continuous, near real-time, hands-off sampling of airborne particulate matter, and qualification and/or quantification of biomolecules in the sample representative for biologic or microbial contamination. The systems and methods may utilize an electrostatic precipitator for sampling the matter; and a measurement assembly configured to illuminate, excite, or breakdown the sampled matter by electromagnetic radiation, and to detect a spectrum, or one or more wavelength bands of the scatter emitted by the sample. In an exemplary implementation, a sputter deposition process is employed to configure the sample for an enhanced plasmon resonance. The measurement data may be transferred via wireless communication means for cloud storage and signal processing.