Array Permeation Chip is a cutting-edge technology that has garnered widespread attention in the fields of biology, chemistry, and medicine, providing an innovative tool for laboratory research.
This article will delve into the principles, design features, application areas, and potential impact of the Array Permeation Chip in scientific research.
1 Principles and Structure
The core of the array osmotic chip lies in the combination of its microarray structure and the principles of osmotic hydrodynamics.
Microarrays contain hundreds to thousands of tiny wells, each used to process a single sample. The size and arrangement of these wells can be precisely adjusted to meet experimental needs.
Osmotic fluid dynamics, on the other hand, enables efficient and precise processing of samples through a carefully designed fluid dynamics system, allowing biomolecules to be effectively analyzed and detected.
2. Design Features
Array Permeation Chips are highly customizable. The pores of its microarrays can be customized to suit different types of experiments according to research purposes.
The chip's osmotic hydrodynamic system can also be adjusted as needed to ensure optimal sample processing. This flexibility allows the array osmotic chip to be used in a wide range of applications.
3.Application Areas
Array-permeable microarrays have a wide range of applications in gene sequencing, protein analysis, cellular research, and other fields.
In gene sequencing, the high-throughput performance of microarrays has enabled researchers to perform DNA sequencing experiments more quickly, thus advancing genomics.
In protein analysis, array permeabilized microarrays provide researchers with an efficient tool to analyze multiple protein samples simultaneously. In cellular research, the technology can be used for single-cell analysis, providing a new way to deeply understand cellular heterogeneity.
4 Potential Impact on Scientific Research
The introduction of the Array Permeation Chip signifies a new era in laboratory research. Its characteristics of high throughput and efficient sample processing significantly accelerate scientific experiments, providing researchers with greater experimental freedom.
The application of this technology is expected to drive advancements in life sciences, medicine, and chemistry, deepening our understanding of the complexity of biological systems and opening up new possibilities for discoveries and applications.
In summary, array osmotic microarrays, as an advanced laboratory technology, not only lead the frontiers of scientific research in theory, but also provide scientists with powerful tools in practice.
Its wide range of applications in gene sequencing, protein analysis, cellular research, etc. predicts that it will play an increasingly important role in scientific research, driving continuous innovation and progress in laboratory research.
Dxfluidics Products
| Product Code | Microcolumn dimensions | Channel height (um) | Thickness (mm) | Chip material | price(CNY) | |
| Diameter (um) | Space (um) | |||||
| 900001 | 120/360 | 60/110 | 90 | 4+1 | PDMS+Glass | 300 |
| 900002 | 120/360 | 60/110 | 90 | 4+1 | PDMS+Glass | 300 |
| 900003 | 300/560 | 30/110 | 40 | 4+1 | PDMS+Glass | 300 |
| 900004 | 300/560 | 30/110 | 40 | 4+1 | PDMS+Glass | 300 |
| 900005 | 300 | 40 | 40 | 4+1 | PDMS+Glass | 300 |
| 900006 | 420 | 80 | 40 | 4+1 | PDMS+Glass | 300 |
| 900007 | Various specifications | 40 | 4+1 | PDMS+Glass | 300 | |
| 900008 | 350 | 150 | 40 | 4+1 | PDMS+Glass | 300 |
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