Literature DB >> 17588654

A scaffold cell seeding method driven by surface acoustic waves.

Haiyan Li1, James R Friend, Leslie Y Yeo.   

Abstract

Surface acoustic waves (SAW) have been employed to drive a particle suspension into a porous scaffold as a means for cell seeding. Straight, simple interdigital electrode structures were fabricated on lithium niobate to permit the generation of Rayleigh SAW radiation. Fluorescent microscopy was used to investigate the seeding process; the SAW-driven seeding process occurred in approximately 10s, much quicker than if the scaffold were to be seeded by gravity-driven diffusional processes alone (>30min). Analysis of high-speed micrographic images demonstrated that the SAW method could also drive particles deeper into the scaffold, thereby significantly improving the uniformity of the particle distribution. The proposed SAW technique therefore offers a promising technology to dramatically improve the speed and uniformity of cell seeding in scaffolds, which might contribute to rapid and uniform tissue regeneration.

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Year:  2007        PMID: 17588654     DOI: 10.1016/j.biomaterials.2007.06.005

Source DB:  PubMed          Journal:  Biomaterials        ISSN: 0142-9612            Impact factor:   12.479


  18 in total

1.  Cytocentrifugation: a convenient and efficient method for seeding tendon-derived cells into monolayer cultures or 3-D tissue engineering scaffolds.

Authors:  Louise Way; Nanette Scutt; Andrew Scutt
Journal:  Cytotechnology       Date:  2011-09-25       Impact factor: 2.058

2.  Focused ion beam milling of microchannels in lithium niobate.

Authors:  Manoj Sridhar; Devendra K Maurya; James R Friend; Leslie Y Yeo
Journal:  Biomicrofluidics       Date:  2012-03-15       Impact factor: 2.800

Review 3.  Microfluidic devices for cell cultivation and proliferation.

Authors:  Masoomeh Tehranirokh; Abbas Z Kouzani; Paul S Francis; Jagat R Kanwar
Journal:  Biomicrofluidics       Date:  2013-10-29       Impact factor: 2.800

4.  Ultrafast microfluidics using surface acoustic waves.

Authors:  Leslie Y Yeo; James R Friend
Journal:  Biomicrofluidics       Date:  2009-01-02       Impact factor: 2.800

5.  Rapid production of protein-loaded biodegradable microparticles using surface acoustic waves.

Authors:  Mar Alvarez; Leslie Y Yeo; James R Friend; Milan Jamriska
Journal:  Biomicrofluidics       Date:  2009-01-21       Impact factor: 2.800

6.  Microfluidics as a functional tool for cell mechanics.

Authors:  Siva A Vanapalli; Michel H G Duits; Frieder Mugele
Journal:  Biomicrofluidics       Date:  2009-01-05       Impact factor: 2.800

7.  A novel μ-fluidic whole blood coagulation assay based on Rayleigh surface-acoustic waves as a point-of-care method to detect anticoagulants.

Authors:  Sascha Meyer Dos Santos; Anita Zorn; Zeno Guttenberg; Bettina Picard-Willems; Christina Kläffling; Karen Nelson; Ute Klinkhardt; Sebastian Harder
Journal:  Biomicrofluidics       Date:  2013-10-04       Impact factor: 2.800

8.  Exploitation of physical and chemical constraints for three-dimensional microtissue construction in microfluidics.

Authors:  Deepak Choudhury; Xuejun Mo; Ciprian Iliescu; Loo Ling Tan; Wen Hao Tong; Hanry Yu
Journal:  Biomicrofluidics       Date:  2011-06-29       Impact factor: 2.800

Review 9.  Surface acoustic wave microfluidics.

Authors:  Xiaoyun Ding; Peng Li; Sz-Chin Steven Lin; Zackary S Stratton; Nitesh Nama; Feng Guo; Daniel Slotcavage; Xiaole Mao; Jinjie Shi; Francesco Costanzo; Tony Jun Huang
Journal:  Lab Chip       Date:  2013-09-21       Impact factor: 6.799

10.  Low-frequency flexural wave based microparticle manipulation.

Authors:  Hunter Bachman; Yuyang Gu; Joseph Rufo; Shujie Yang; Zhenhua Tian; Po-Hsun Huang; Lingyu Yu; Tony Jun Huang
Journal:  Lab Chip       Date:  2020-03-10       Impact factor: 6.799
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