Next-Generation Biochips Made of Glass
Advantages Over Plastic Substrates
Unlike conventional polymer substrates, glass offers unmatched stability, precision, and chemical durability.
Our microfluidic components integrate complex tasks like mixing, reaction, sensing, and separation in ultra-compact formats.
Where Our Glass Microfluidics
Glass microfluidic chips enable compact, multifunctional platforms with excellent precision and stability.
Their chemical resistance, optical clarity, and dimensional control make them ideal for sensitive biomedical and diagnostic workflows.
From analysis to storage, these chips ensure reliability across every stage of micro-scale fluid manipulation.
ELISA & Immunoassays
Glass chips offer low signal noise and excellent transparency, ideal for fluorescence or absorbance detection. Precisely aligned micro wells support multiplexed assays.
PCR & Genetic Screening
Glass endures high temperatures for accurate thermal cycling. Microchannels allow efficient, small-volume PCR and qPCR reactions.
Pathogen Detection
Glass chips enable integrated extraction, amplification, and detection on one platform. Their inert surface minimizes contamination and preserves reagents.
Lab on a Chip
Glass integrates complex fluidic tasks into compact, multi functional systems. Its durability suits automation and chemical-intensive applications.
Glass offers superior chemical resistance, thermal stability, and optical clarity compared to conventional plastic substrates like PDMS or PMMA.
Its non porous surface ensures minimal sample absorption and high precision in microfluidic applications.
Why Glass? Advantages Over Plastic Substrates
Chemical Resistance
Withstands harsh solvents, acids, and bases without degradation, ensuring long-term stability in demanding environments.
Optical Transparency
Delivers clear, distortion-free light transmission ideal for fluorescence, absorbance, and high resolution imaging.
Thermal Stability
Performs reliably under high temperature processes, including autoclaving and thermal cycling.
Non-porous Surface
Prevents sample absorption and cross contamination, enabling accurate and repeatable microfluidic operations.
Key Technical Advantages of Glass Microfluidics
Glass microfluidic devices offer exceptional performance through superior chemical, thermal, and mechanical properties.
Their precision structuring and optical clarity enable reliable operation in complex biomedical and analytical applications.
| Category | Glass Advantage | Description |
|---|---|---|
| Chemical Resistance | High chemical resistance | Stable in solvents, acids, and bases |
| Optical Clarity | Optical clarity | Ideal for high-resolution optical analysis |
| Mechanical Strength | Superior durability | Scratch & deformation resistant, maintains high precision |
| Thermal Stability | Thermal stability | Withstands autoclaving and high temperature |
| Precision Structuring | Precision structuring | Enables complex shapes like microchannels, microwells |
| Low Adsorption | Low adsorption | Minimizes sample loss and improves analytical accuracy |
Looking for tailored microfluidic designs or glass chip specifications? Our team is ready to support your R&D and prototyping needs with expert precision.
Let’s Engineer Your Custom Biochip
Engineered Glass Chips, Customized for Your Application
Every glass microfluidic chip is precision designed to align with your device architecture, detection system, and fluidic requirements.
From initial concept to production, our engineering team ensures seamless compatibility and high-performance integration.
Microfluidic Glass Chip
Discover our high-precision glass microfluidic chips, designed for advanced biomedical and diagnostic applications.
With customizable structures and superior material properties, they offer exceptional reliability and integration into complex workflows.
Start Your Project with YEKGLASS
Request a quote or connect with our global team for scalable production, sampling, or long-term collaboration. We deliver glass-based solutions for next-generation biomedical platforms.