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Related Concept Videos

Bioreactor Design and Operational System01:29

Bioreactor Design and Operational System

Bioreactors are engineered vessels designed to cultivate microorganisms under controlled conditions for industrial bioprocessing. They maintain sterility and allow precise regulation of pH, temperature, oxygen, and nutrient levels to optimize microbial growth and metabolite production. Bioreactors range from small laboratory units of 1 liter to industrial systems holding up to 500,000 liters, though only about 75% of their volume is actively used for fermentation. The remaining headspace...
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Growth media provide essential nutrients that support cell growth and metabolism, thereby enhancing the yield of valuable products such as enzymes, antibiotics, and biomass. Designing an effective growth medium involves balancing all components to prevent nutrient limitations or toxic excesses, both of which can impair growth and reduce product yields.Composition of a Typical Growth MediumA typical growth medium contains carbon and nitrogen sources, salts, vitamins, trace elements, and...
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A Gradient-generating Microfluidic Device for Cell Biology
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Programmable acoustofluidic engineering for creating gradient biomaterials.

Yujing Lu1, Ye He1, Jianping Xia1

  • 1The Thomas Lord Department of Mechanical Engineering and Materials, Duke University, Durham, NC 27708, USA.

Science Advances
|December 17, 2025
PubMed
Summary
This summary is machine-generated.

Gradient biomaterials are crucial for tissue engineering and drug delivery. A new acoustofluidic system, GRADE, offers precise, versatile fabrication of these gradient biomaterials, overcoming limitations of current methods.

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Area of Science:

  • Biomaterials Science
  • Bioengineering
  • Acoustofluidics

Background:

  • Gradient biomaterials with spatially varying properties are essential for applications like tissue engineering and drug delivery.
  • Existing fabrication methods lack precision, material compatibility, and reproducibility.

Purpose of the Study:

  • To introduce a programmable system, Gradient Regulation via Acoustofluidic Dynamic Engineering (GRADE), for high-fidelity gradient biomaterial fabrication.
  • To overcome limitations of current gradient material fabrication techniques.

Main Methods:

  • Utilized focused interdigital transducers and pulsed surface acoustic wave actuation for tunable acoustic streaming.
  • Employed an open microchannel design for nondestructive extraction of centimeter-scale gradients.
  • Demonstrated composition-independent fluid manipulation for diverse biomaterials and cross-linking methods.

Main Results:

  • Achieved tunable and directional acoustic streaming (0-22 mm/s) for precise gradient control.
  • Fabricated centimeter-scale gradients non-destructively, enabling device reuse.
  • Showcased GRADE's versatility with various biomaterials and cross-linking techniques.
  • Validated platform usability by demonstrating stem cell stiffness-dependent mechanosensation on gradient substrates.

Conclusions:

  • GRADE is a powerful and versatile platform for fabricating high-fidelity gradient biomaterials.
  • The system offers enhanced precision, material compatibility, and scalability compared to existing methods.
  • GRADE has broad potential to advance fundamental mechanobiology research and translational biomedical applications.