BMF, a global leader in micro scale 3D printing, is set to launch its upgraded S150 BIO system in the APAC region. Tailored for life science and biomedical research, the new S150 BIO combines high optical precision of 25 μm with compatibility for biomaterials and hydrogel printing, delivering a powerful solution for researchers seeking precision, flexibility, and cell-friendly performance.

Building upon BMF’s industry-leading Projection Micro-Stereolithography (PµSL) technology, the S150 BIO is engineered to meet the stringent demands of biological and bioengineering laboratories. It introduces a series of user-oriented enhancements that make high-resolution bioprinting more accessible and reliable.

 

Key Highlights of the S150 BIO:

1. Cell-friendly Heating System:

Designed to maintain a constant printing temperature of 37°C, the S150 BIO provides an optimal thermal environment to support the activity and viability of living cells during the printing process.

2. Micro Resin Vats:

Available in T5 ml and T20 ml options, the modular resin vat design enables users to flexibly choose between small-scale material testing and larger experimental runs, reducing waste while supporting diverse research needs.

3. Fresh Air Filtration System:

Equipped with a HEPA13 filter and UV-C (253.7 nm) sterilization, the S150 BIO ensures a clean and contamination-free printing environment—an essential safeguard when working with sensitive biological materials.

4. Compact Desktop Design:

The system’s compact form factor allows it to be placed directly inside a biological safety cabinet, ensuring convenient operation within controlled lab environments while maintaining biosafety compliance.

 

 

With these features, the S150 BIO is positioned as an ideal platform for researchers exploring tissue engineering, organ-on-a-chip, hydrogel scaffolds, and other biofabrication applications requiring both precision and biocompatibility.

The upcoming release underscores BMF’s ongoing commitment to advancing micro-scale additive manufacturing for biomedical innovation, bridging the gap between engineering precision and biological functionality.