A system for processing samples from a body of fluid. The system includes one or more sample bottles for acquiring a sample from the body of fluid. Each sample bottle initially retains a pre-filling fluid. Each sample bottle includes a fluidic inlet port and a bottle outlet port. Each sample bottle has an inlet check valve coupled to the fluidic inlet port, the inlet check valve configured to allow fluid from the body of fluid into a sample bottle via the fluidic inlet port when the pressure difference between the body of fluid and fluid within the sample bottle reaches a threshold. The system further includes at least one pump, the bottle outlet port of each sample bottle selectively coupled to the at least one pump via a different control valve. The at least one pump is configured, in a first configuration, to remove prefilling fluid from each selected sample bottle such that, for each selected sample bottle, the pressure difference threshold is reached and a sample from the body of fluid is acquired.

A system for processing samples from a body of fluid. The system includes one or more sample bottles for acquiring a sample from the body of fluid. Each sample bottle initially retains a pre-filling fluid. Each sample bottle includes a fluidic inlet port and a bottle outlet port. Each sample bottle has an inlet check valve coupled to the fluidic inlet port, the inlet check valve configured to allow fluid from the body of fluid into a sample bottle via the fluidic inlet port when the pressure difference between the body of fluid and fluid within the sample bottle reaches a threshold. The system further includes at least one pump, the bottle outlet port of each sample bottle selectively coupled to the at least one pump via a different control valve. The at least one pump is configured, in a first configuration, to remove prefilling fluid from each selected sample bottle such that, for each selected sample bottle, the pressure difference threshold is reached and a sample from the body of fluid is acquired.

A bottle includes a body, a cap mounted to a cap neck of the body. The cap has an outer peripheral portion which is provided with a protrusion. Around the cap, there is provided a position indicator indicating whether the cap is at a correctly closed position, based on the positional relationship between the protrusion and the position indicator.

To provide a culture flask A1, a vessel 1 is made up of a bottom wall 11, standing walls rising from the periphery of the bottom wall 11 such as front and rear walls 12, 13 spaced apart in a front-back direction and a pair of side walls 14 laterally spaced and connected to the front and rear walls 12, 13, and a ceiling wall 15 positioned above the bottom wall 11 to cover a region surrounded by the front wall 12, rear wall 13 and paired side walls 14 as viewed in a vertical direction. A cylindrical neck 2 with an open end is attached to the front wall 12. The ceiling wall 15 includes a low region positioned offset in the vertical direction toward the bottom wall 11 from an upper end P1 of the neck 2 attached to the front wall 12.

The present invention relates to a biological sample collection kit, which uses a unique dry preservative for the preservation of nucleic acids, DNA and RNA, for collection, stabilization, transportation and long-term room temperature storage of biological samples that can be from sources such as saliva for molecular diagnostic applications. The invention features a collection device for biological samples such as saliva containing nucleic acids, and dry preservatives that are affixed directly or to a carrier substrate and placed within the collection device such that the samples come into contact with the dry preservatives resulting in the preservation and stabilization of the nucleic acids.

The present invention relates to a biological sample collection kit, which uses a unique dry preservative for the preservation of nucleic acids, DNA and RNA, for collection, stabilization, transportation and long-term room temperature storage of biological samples that can be from sources such as saliva for molecular diagnostic applications. The invention features a collection device for biological samples such as saliva containing nucleic acids, and dry preservatives that are affixed directly or to a carrier substrate and placed within the collection device such that the samples come into contact with the dry preservatives resulting in the preservation and stabilization of the nucleic acids.

The shock tube comprises a tube, a first electrode, a second electrode and a stopple, wherein the tube is internally provided with a cavity for accommodating a target liquid sample. The first electrode is arranged at one end of the tube. The second electrode is arranged in the stopple, and the outer end of the second electrode can be electrically connected with the exterior via an opening of the stopple. The stopple is internally provided with an elastic piece connected with the second electrode. The outer side of the elastic piece is connected with the stopple, and the inner side of the elastic piece is connected with the second electrode. The invention further provides a cell electroporation device where the shock tube can be placed.

The shock tube comprises a tube, a first electrode, a second electrode and a stopple, wherein the tube is internally provided with a cavity for accommodating a target liquid sample. The first electrode is arranged at one end of the tube. The second electrode is arranged in the stopple, and the outer end of the second electrode can be electrically connected with the exterior via an opening of the stopple. The stopple is internally provided with an elastic piece connected with the second electrode. The outer side of the elastic piece is connected with the stopple, and the inner side of the elastic piece is connected with the second electrode. The invention further provides a cell electroporation device where the shock tube can be placed.

Provided herein are devices, systems, and methods for measuring the presence of an analyte of interest in a sample. Certain embodiments of the present disclosure are related to culture measurement systems that include a culture vial and a sensor, wherein the sensor is a pH sensor, a responsive label, or an indicator compound, such that the sensor is incorporated into the culture vial for measurement of the pH of the sample.

In alternative embodiments, provided are genetically or recombinantly engineered nitrogen-fixing, nitrogenase expressing bacteria capable of enzymatically synthesizing hydrocarbons, and methods for making and using them. In alternative embodiments, provided are genetically or recombinantly engineered nitrogen-fixing, nitrogenase expressing bacteria including nitrogen-fixing diazotrophs such as nitrogen-fixing bacteria of the family Pseudomonadaceae, or the genus Azotobacter, for the whole cell synthesis of hydrocarbons and carbon-carbon bonds. In alternative embodiments, nitrogen-fixing, nitrogenase-expressing bacteria used to practice the invention are genetically or recombinantly engineered to express an exogenous nitrogenase express more endogenous nitrogenase or have increased nitrogenase, activity. In alternative embodiments, nitrogen-fixing, nitrogenase-expressing bacteria used to practice the invention are genetically or recombinantly engineered to lack or have decreased molybdenum transporter activity. In alternative embodiments, provided are culture systems, fermenters and bioreactors using nitrogen-fixing, nitrogenase-expressing bacteria for enzymatically synthesizing hydrocarbons.