18668787. TWO-PHASE FLUSHING SYSTEMS AND METHODS simplified abstract (ILLUMINA, INC.)
Contents
- 1 TWO-PHASE FLUSHING SYSTEMS AND METHODS
- 1.1 Organization Name
- 1.2 Inventor(s)
- 1.3 TWO-PHASE FLUSHING SYSTEMS AND METHODS - A simplified explanation of the abstract
- 1.4 Simplified Explanation
- 1.5 Key Features and Innovation
- 1.6 Potential Applications
- 1.7 Problems Solved
- 1.8 Benefits
- 1.9 Commercial Applications
- 1.10 Prior Art
- 1.11 Frequently Updated Research
- 1.12 Questions about Two-Phase Flushing Systems
- 1.13 Original Abstract Submitted
TWO-PHASE FLUSHING SYSTEMS AND METHODS
Organization Name
Inventor(s)
Nicholas Watson of San Diego CA (US)
Wesley A. Cox-muranami of Middleton WI (US)
Minsoung Rhee of San Diego CA (US)
TWO-PHASE FLUSHING SYSTEMS AND METHODS - A simplified explanation of the abstract
This abstract first appeared for US patent application 18668787 titled 'TWO-PHASE FLUSHING SYSTEMS AND METHODS
Simplified Explanation
The patent application describes a method for using a two-phase flushing system in biochemical reactions. This involves connecting different reagent reservoirs to a flow cell to perform reactions, expel reagents, and introduce buffer solutions.
Key Features and Innovation
- Utilizes a valve to control the flow of reagents, gas, and buffer solutions in a biochemical reaction setup.
- Enables the efficient performance of biochemical reactions by flushing out unwanted reagents and introducing buffer solutions.
- Provides a systematic approach to managing reagents in a flow cell, improving the overall reaction process.
Potential Applications
The technology can be applied in various fields such as biotechnology, pharmaceuticals, and research laboratories where precise control of reagents is crucial for successful biochemical reactions.
Problems Solved
- Efficiently expels unwanted reagents from a biochemical reaction setup.
- Introduces buffer solutions to stabilize and optimize the reaction conditions.
- Provides a systematic and controlled approach to managing reagents in a flow cell.
Benefits
- Improves the efficiency and accuracy of biochemical reactions.
- Reduces wastage of reagents by effectively flushing out unwanted substances.
- Enhances the overall quality of results obtained from biochemical experiments.
Commercial Applications
Two-Phase Flushing System for Biochemical Reactions
This technology can be commercialized as a specialized system for biochemical laboratories, biotech companies, and pharmaceutical research facilities to optimize their biochemical reaction processes.
Prior Art
There may be prior art related to valve-controlled systems in biochemical reactions, fluid dynamics in flow cells, and reagent management techniques in laboratory settings. Researchers can explore these areas for more information.
Frequently Updated Research
Researchers are continuously exploring new methods and technologies to improve the efficiency and precision of biochemical reactions. Stay updated on the latest advancements in valve-controlled systems, reagent management, and flow cell technologies for biochemical applications.
Questions about Two-Phase Flushing Systems
How does the two-phase flushing system improve the efficiency of biochemical reactions?
The two-phase flushing system enhances efficiency by allowing precise control over the introduction and removal of reagents, gases, and buffer solutions in a flow cell setup, optimizing reaction conditions.
What are the potential applications of the two-phase flushing system in different industries?
The two-phase flushing system can be applied in biotechnology, pharmaceuticals, and research laboratories to improve the accuracy and quality of biochemical reactions.
Original Abstract Submitted
Two-phase flushing systems and methods. An example method includes moving a valve to a first position to fluidly connect a first reagent reservoir containing a first reagent to a flow cell and flowing the first reagent from the first reagent reservoir to the flow cell to perform a biochemical reaction. The method includes moving the valve to a second position to fluidly connect a gas to the flow cell and flowing gas into the flow cell to expel at least a portion of the first reagent from the biochemical reaction from the flow cell. The method includes moving the valve to a third position to fluidly connect a buffer reagent reservoir containing a buffer reagent to the flow cell and flowing the buffer reagent into the flow cell.