System for conducting the identification of bacteria in biological samples
First Claim
1. A method for circumferentially aligning samples within a magazine to optimize an emitted light signal across the samples, said magazine including a carousel base assembly containing at least one of a plurality of samples, said method comprising providing a light source for applying light to a sample, measuring the light emittance from the sample, and rotating the carousel base assembly in at least a first direction along an arc to adjust a location of the sample with respect to the applied light until the light emitted from the sample produces a maximum signal so that the light emittance signal received by a receiver is maximized and brought to its highest level of performance defining a fine-tuned position of the sample, wherein the method includes providing the light source for applying the light to the sample and providing the receiver for receiving the emitted light and measuring the light emittance from the sample wherein both the light source and the receiver are located above the sample, emitting light at a first wavelength to the sample at the fine-tuned position, and measuring fluorescence emitted from the sample at a second wavelength.
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Accused Products
Abstract
The present invention relates to a system for conducting the identification and quantification of micro-organisms, e.g., bacteria in biological samples. More particularly, the invention relates to a system comprising a cooling, heating and fan arrangement for maintaining a predetermined optimum temperature of the samples during testing; a visual, circumferential and axial alignment system for aligning the samples within the carousel; a transfer system for transferring the samples from the carousel to the centrifuge; a balancing system of minimizing the rotational vibrations of the centrifuge; a safety system and anti-tipping design for the sample containing system; liquid dispensing arms for dispensing the buffered saline solution; and discharge ports for discharging and disposing of the liquid removed from the samples to a location external of the system.
85 Citations
14 Claims
- 1. A method for circumferentially aligning samples within a magazine to optimize an emitted light signal across the samples, said magazine including a carousel base assembly containing at least one of a plurality of samples, said method comprising providing a light source for applying light to a sample, measuring the light emittance from the sample, and rotating the carousel base assembly in at least a first direction along an arc to adjust a location of the sample with respect to the applied light until the light emitted from the sample produces a maximum signal so that the light emittance signal received by a receiver is maximized and brought to its highest level of performance defining a fine-tuned position of the sample, wherein the method includes providing the light source for applying the light to the sample and providing the receiver for receiving the emitted light and measuring the light emittance from the sample wherein both the light source and the receiver are located above the sample, emitting light at a first wavelength to the sample at the fine-tuned position, and measuring fluorescence emitted from the sample at a second wavelength.
- 10. A method for circumferentially aligning samples within a magazine to optimize an emitted light signal across the samples, wherein each of the samples are contained within an optical cup or cuvette, wherein the optical cup or cuvette includes at least one of a reflective coating and a reflective liner, and further includes a tapered end to assist with optical analysis of the sample contained therein, wherein said magazine includes a carousel base assembly, and wherein said method comprises providing a light source for applying light to a sample, measuring the light emittance from the sample, rotating the carousel base assembly in at least a first direction along an arc to adjust a location of the sample with respect to the applied light until the light coming from the sample produces a maximum signal so that the light emittance signal received by the receiver is maximized and brought to its highest level of performance defining a fine-tuned position of the sample, emitting light at a first wavelength to the sample at the fine-tuned position, and measuring fluorescence emitted from the sample at a second wavelength, wherein both the light source and receiver are located above the sample.
- 12. A testing system for circumferentially aligning samples within a magazine to optimize an emitted light signal across the samples, said system comprising a magazine including a carousel base assembly, means for applying light to a sample, means for measuring the light emittance from the sample, means for rotating the carousel base assembly in at least a first direction along an arc to define a fine-tuned location of the sample with respect to the applied light until the light coming from the sample produces a maximum signal and the light emittance signal received by a receiver is maximized, and means for performing the testing of the sample at the fine-tuned position, wherein both the means for applying light to the sample and the receiver are positioned above the samples.
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14. A method for aligning samples within a magazine to optimize an emitted light signal across the samples, said magazine including a base assembly containing at least one of a plurality of samples, said method comprising providing a light source for applying light to a sample, providing a member to measure the light emittance from the sample, and moving the base assembly in at least a first direction and a second direction which is opposite the first direction to fine-tune and precisely adjust a location of the sample with respect to the applied light until the light coming from the sample produces a maximum signal so that the light emittance signal received by a receiver is maximized and brought to its highest level of performance defining a fine-tuned position, and then performing testing to the sample at the fine-tuned position, and wherein both the light source and receiver are located above the sample.
Specification