A detection method of a target molecule in a specimen includes a (target molecule)-(labeled binding molecule)-(capturing molecule) complex forming step of reacting the target molecule in the specimen, a capturing molecule that binds to the target molecule, and a labeled binding molecule that binds to the target molecule and which is labeled with an enzyme that catalyzes a reaction to produce ATP, to form a complex formed of the target molecule, the capturing molecule, and the labeled binding molecule, a step of removing the labeled binding molecules which did not bind to the target molecule, an ATP production step of producing ATP by reacting the (target molecule)-(labeled binding molecule)-(capturing molecule) complex with a substrate of the enzyme that catalyzes a reaction to produce ATP, an ATP amplification step of amplifying the produced ATP, and an ATP detection step of detecting the amplified ATP.

The present invention relates to several methods to detect gram positive mastitis pathogens in a small sample of bovine milk by luminescence using a combination of specific reagents giving a “cow side” “in-stall” indication of the presence or absence of gram positive mastitis pathogens within a short period of time.

Various embodiments of a light detection device and a method of using the device are disclosed. In one or more embodiments, the light detection device can include a housing that extends along a housing axis between top and bottom surfaces. The device can also include a port that is adapted to receive a sample, and a door connected to the housing. The door can include an actuator portion adapted to selectively move the door between a closed position and an open position, and a cover portion connected to the actuator portion and adapted to close the port when the door is in the closed position and open the port when the door is in the open position to allow external access to the port.

Various embodiments of a light detection device and a method of using the device are disclosed. In one or more embodiments, the light detection device can include a housing that extends along a housing axis between top and bottom surfaces. The device can also include a port that is adapted to receive a sample, and a door connected to the housing. The door can include an actuator portion adapted to selectively move the door between a closed position and an open position, and a cover portion connected to the actuator portion and adapted to close the port when the door is in the closed position and open the port when the door is in the open position to allow external access to the port.

Disclosed herein are methods and systems for rapid detection of microorganisms in a sample. A genetically modified bacteriophage is also disclosed which comprises an indicator gene in the late gene region. The specificity of the bacteriophage, such as Salmonella-specific bacteriophage, allows detection of a specific microorganism, such as Salmonella spp. and an indicator signal may be amplified to optimize assay sensitivity.

Various embodiments of a light detection device and a method of using the device are disclosed. In one or more embodiments, the light detection device can include a housing that extends along a housing axis between top and bottom surfaces. The device can also include a port that is adapted to receive a sample, and a door connected to the housing. The door can include an actuator portion adapted to selectively move the door between a closed position and an open position, and a cover portion connected to the actuator portion and adapted to close the port when the door is in the closed position and open the port when the door is in the open position to allow external access to the port.

A method is described for detecting or determining an amount of microbial contamination in an aqueous preparation. Also described, is a use of a luciferin/luciferase reagent containing at least one lytic agent for detecting or determining an amount of microbial contamination in an aqueous preparation including at least one particulate material. In addition, a use of such a method is described for detecting or determining an amount of microbial contamination in an aqueous preparation.

A method for detecting lactic acid and/or acetic acid bacteria in a food-processing matrix is taught, using microbial flora including a lactic acid and/or acetic acid bacterial flora and a fungal flora. The bacterial flora contains an adenosine triphosphate of bacterial origin, and the fungal flora contains an adenosine triphosphate of fungal origin. The method comprises applying, to the matrix, before a first time limit, an antifungal having an antifungal action which is lethal, on the fungal flora, and at a second time limit, an antibiotic action which is non lethal, at a second time limit after the first time limit, on the bacterial flora. The microbial flora is detected between the first time limit and the second time limit; the lethal antifungal action releases, into the matrix, for the first time limit, adenosine triphosphate of fungal origin and in which the microbial flora is detected between the first time limit and the second time limit.

Disclosed herein are methods and systems for rapid detection of microorganisms in a sample. A genetically modified bacteriophage is also disclosed which comprises an indicator gene in the late gene region. The specificity of the bacteriophage, such as Salmonella-specific bacteriophage, allows detection of a specific microorganism, such as Salmonella spp. and an indicator signal may be amplified to optimize assay sensitivity.

Disclosed herein are methods and systems for rapid detection of microorganisms such as Cronobacter spp. in a sample. A genetically modified bacteriophage is also disclosed which comprises an indicator gene in the late gene region. The specificity of the bacteriophage, such as Cronobacter-specific bacteriophage, allows detection of a specific microorganism, such as Cronobacter spp. and an indicator signal may be amplified to optimize assay sensitivity.