FLUIDIC CARTRIDGE MODULE, BIOSENSOR DEVICE, METHOD OF DETECTING ANALYTE IN SAMPLE

Organization Name

Taiwan Semiconductor Manufacturing Co., Ltd.

Inventor(s)

Yi-Hsing Hsiao of Hsinchu City (TW)

Yu-Jie Huang of Kaohsiung City (TW)

Tung-Tsun Chen of Hsinchu City (TW)

FLUIDIC CARTRIDGE MODULE, BIOSENSOR DEVICE, METHOD OF DETECTING ANALYTE IN SAMPLE - A simplified explanation of the abstract

This abstract first appeared for US patent application 17873146 titled 'FLUIDIC CARTRIDGE MODULE, BIOSENSOR DEVICE, METHOD OF DETECTING ANALYTE IN SAMPLE

Simplified Explanation

The abstract describes a fluidic cartridge module that consists of a casing, a biosensor package, and a fluidic channel. The casing has a sample inlet and a buffer inlet, while the biosensor package is placed inside the casing and includes a sensor array and a reference electrode. The fluidic channel is positioned over the biosensor package and connected to the sample inlet and the buffer inlet. It has a first opening aligned with the sensor array and a second opening aligned with the reference electrode.

• The invention is a fluidic cartridge module for use in biosensing applications.
• The module includes a casing, a biosensor package, and a fluidic channel.
• The casing has a sample inlet and a buffer inlet for introducing samples and buffers.
• The biosensor package is disposed inside the casing and comprises a sensor array and a reference electrode.
• The fluidic channel is placed over the biosensor package and connected to the sample and buffer inlets.
• The fluidic channel has openings aligned with the sensor array and the reference electrode.

Potential applications of this technology:

• Medical diagnostics: The fluidic cartridge module can be used for rapid and accurate detection of various biomarkers in patient samples, enabling early diagnosis of diseases.
• Environmental monitoring: The module can be utilized to analyze water or air samples for pollutants, providing real-time data for environmental monitoring and ensuring safety.
• Food safety testing: The cartridge can be employed to detect contaminants or pathogens in food samples, ensuring the quality and safety of food products.
• Biotechnology research: Researchers can use the module to study biological samples and analyze specific molecules or compounds, aiding in the development of new drugs or therapies.

Problems solved by this technology:

• Time-consuming analysis: The fluidic cartridge module enables quick and efficient analysis of samples, reducing the time required for testing and providing rapid results.
• Complex sample handling: The module simplifies the process of sample introduction and analysis, making it easier for users to perform biosensing experiments without extensive training.
• Cross-contamination risk: The design of the cartridge minimizes the risk of cross-contamination between samples, ensuring accurate and reliable results.

Benefits of this technology:

• Portability: The compact and self-contained nature of the fluidic cartridge module allows for easy transport and use in various settings, including point-of-care testing or field applications.
• Cost-effective: The module's design and integration of multiple components into a single unit reduce the need for separate equipment, lowering overall costs.
• High sensitivity and accuracy: The biosensor package, with its sensor array and reference electrode, provides precise and reliable measurements, enhancing the sensitivity and accuracy of the analysis.
• User-friendly: The simplified design and straightforward operation of the module make it accessible to users with different levels of expertise, promoting widespread adoption and usability.

Original Abstract Submitted

A fluidic cartridge module includes a casing, a biosensor package, and a fluidic channel. The casing includes a sample inlet and a buffer inlet, a biosensor package disposed in the casing and comprising a sensor array and a reference electrode. The fluidic channel is disposed over the biosensor package and connected to the sample inlet and the buffer inlet, wherein the fluidic channel includes a first opening aligned with the sensor array and a second opening aligned with the reference electrode.