Research oriented microfluidic control backup device

NegotiableUpdate on 01/18

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Nature of the Manufacturer: Producers

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Place of Origin

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Overview

The research oriented microfluidic control preparation instrument MPE Lab is a tool based microfluidic control preparation system, which is an important tool for laboratory scale preparation, quality evaluation, and utility assessment of micro and nano particles. It is also an important helper for the application research of new technologies.

Product Details

科研型微流控制备仪

Research oriented microfluidic control backup deviceDescription

MPE-LabThe scientific research microfluidic control preparation instrument is a tool based microfluidic control preparation system, which is an important tool for laboratory scale preparation, quality evaluation, and utility assessment of micro and nano particles. It is also an important helper for the application research of new technologies. MPE Lab provides a fundamental and necessary solution for exploring various micro nano carriers such as liposomes, lipid nanoparticles, microspheres, micelles, etc. Compared with traditional preparation processes and related hardware solutions, MPE Lab experimental processes are efficient, easy to operate, stable in results, and have good reproducibility. The most important thing is that the MPE Lab microfluidic control backup device greatly reduces the possible impact of different operators and experimental periods on the results, ensuring the objectivity and independence of the research work.

Microfluidic chip:

Microfluidic chips are customized special channel structure components based on application processes, whose channel structure and size are combined with project process requirements, and belong to customized structural components. Specifically, the following four functions can be achieved:

Mixing and emulsification of two phases
Incubation after particle formation;
Particle size control after particle formation;
Secondary mixing or emulsification.

Technical Specifications:

model	MPE-Lab
Applicable carrier	Liposomes, lipid nanoparticles, microspheres, micelles and other micro nano particles/carriers
Applicable system	Suitable for solvent systems that are miscible or immiscible
Minimum working volume	≤200uL
Maximum experimental volume per experiment	40mL
Maximum total flow rate of equipment	≥180mL/min
Equipment parameter settings	Syringe type/specification, total flow rate, flow rate ratio, waste volume, etc
Operation method	Integrated touch screen operation
operating software	MPE Microfluidic Control Backup System (Lab Type), supports lifelong support·Free upgrade
compatibility	Compatible with imported and domestic syringes, compatible with multiple structural chips
other	Support chip customization

Microfluidic technology:

Microfluidic technology is a technique based on (micro) fluid mechanics theory that enables sample preparation and processing in pipelines. finish·Midea combines the physical and chemical models of microfluidics with fluid mechanics theory to achieve functions such as mixing, emulsification, separation, and purification of samples.

Microfluidic technology combines Process Control Technology (PCT) with Process Analytical Technology (PAT) to achieve excellent Online Preparation Technology (OPT) for sample preparation. During the continuous preparation process of the sample, the process parameters are complete·Fully controllable and with good reproducibility, it is more scalable compared to traditional step-by-step and batch production methods.

It can achieve functions such as initial emulsification, re emulsification, and particle size control of the sample.

The microfluidic control preparation system is connected to the microfluidic chip through a preparation pump and a high-pressure delivery pump. Phase A and phase B can be delivered to the chip at a constant speed in a certain proportion for mixing and emulsification. By designing different flow channel structures and controlling different speeds in microfluidic chips, the sample can achieve turbulent, laminar, or atomized states in the microfluidic chip, which can meet the requirements of sample colostrum or re emulsification.

The prepared sample is transported to a high-pressure microfluidic chip through a high-pressure pump, and the particle size is controlled by impact and shear forces to achieve the desired range. The minimum particle size can reach within 100nm, and the PDI is below 0.1.

Typical chip: