Acoustic Holographic Cell Patterning in a Biocompatible Hydrogel
- Postdoctoral Researcher
Acoustophoresis is promising as a rapid, biocompatible, non-contact cell manipulation method, where cells are arranged along the nodes or antinodes of the acoustic field. Typically, the acoustic field is formed in a resonator, which results in highly symmetric regular patterns. However, arbitrary, non-symmetrically shaped cell assemblies are necessary to obtain the irregular cellular arrangements found in biological tissues. We show that arbitrarily shaped cell patterns can be obtained from the complex acoustic field distribution defined by an acoustic hologram. Attenuation of the sound field induces localized acoustic streaming and the resultant convection flow gently delivers the suspended cells to the image plane where they form the designed pattern. We show that the process can be implemented in a biocompatible collagen solution, which can then undergo gelation to immobilize the cell pattern inside the viscoelastic matrix. The patterned cells exhibit F-actin-based protrusions, which indicates that the cells grow and thrive within the matrix. Cell viability assays and brightfield imaging after one week confirm cell survival and that the patterns persist. Acoustophoretic cell manipulation by holographic fields thus holds promise for non-contact, long-range, long-term cellular pattern formation, with a wide variety of potential applications in tissue engineering and mechanobiology.
| Author(s): | Ma, Z. and Holle, A. and Melde, K. and Qiu, T. and Poeppel, K. and Kadiri, V.M. and Fischer, P. |
| Journal: | Adv. Mat. |
| Volume: | 32 |
| Number (issue): | 1904181 |
| Year: | 2019 |
| Month: | October |
| Day: | 12 |
| Bibtex Type: | Article (article) |
| DOI: | https://doi.org/10.1002/adma.201904181 |
| URL: | https://onlinelibrary.wiley.com/doi/full/10.1002/adma.201904181 |
| Electronic Archiving: | grant_archive |
BibTex
@article{Ma2019,
title = {Acoustic Holographic Cell Patterning in a Biocompatible Hydrogel},
journal = {Adv. Mat.},
abstract = {Acoustophoresis is promising as a rapid, biocompatible, non-contact cell manipulation method, where cells are arranged along the nodes or antinodes of the acoustic field. Typically, the acoustic field is formed in a resonator, which results in highly symmetric regular patterns. However, arbitrary, non-symmetrically shaped cell assemblies are necessary to obtain the irregular cellular arrangements found in biological tissues. We show that arbitrarily shaped cell patterns can be obtained from the complex acoustic field distribution defined by an acoustic hologram. Attenuation of the sound field induces localized acoustic streaming and the resultant convection flow gently delivers the suspended cells to the image plane where they form the designed pattern. We show that the process can be implemented in a biocompatible collagen solution, which can then undergo gelation to immobilize the cell pattern inside the viscoelastic matrix. The patterned cells exhibit F-actin-based protrusions, which indicates that the cells grow and thrive within the matrix. Cell viability assays and brightfield imaging after one week confirm cell survival and that the patterns persist. Acoustophoretic cell manipulation by holographic fields thus holds promise for non-contact, long-range, long-term cellular pattern formation, with a wide variety of potential applications in tissue engineering and mechanobiology.},
volume = {32},
number = {1904181},
month = oct,
year = {2019},
slug = {ma2019},
author = {Ma, Z. and Holle, A. and Melde, K. and Qiu, T. and Poeppel, K. and Kadiri, V.M. and Fischer, P.},
url = {https://onlinelibrary.wiley.com/doi/full/10.1002/adma.201904181},
month_numeric = {10}
}