Guiding Cell Network Assembly using Shape‐Morphing Hydrogels

Viola, John M.; Porter, Catherine M.; Gupta, Ananya; Alibekova, Mariia; Prahl, L.; Hughes, Alex J.

doi:10.1002/adma.202002195

Cited by 38 publications

(63 citation statements)

References 69 publications

(85 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Compared with 3D scaffolds, 4D scaffolds with the ability to reconfigure their shapes during culture show huge potential for morphodynamic tissue engineering. Hydrogels that harness non-uniform swelling [ 43 , 54 , [56] , [57] , [58] ], post-programmed anisotropic internal strains [ 59 , 60 ], or cell contractile forces [ [61] , [62] , [63] ] can accomplish this task. However, in addition to the stringent requirements regarding material cytocompatibility, the fabrication process, and imposed stimulation, complexity in fabrication and lack of controllability present a significant impedance to 4D tissue engineering.…”

Section: Resultsmentioning

confidence: 99%

4D biofabrication via instantly generated graded hydrogel scaffolds

Ding

Lee

Ayyagari

et al. 2022

Bioactive Materials

View full text Add to dashboard Cite

Formation of graded biomaterials to render shape-morphing scaffolds for 4D biofabrication holds great promise in fabrication of complex structures and the recapitulation of critical dynamics for tissue/organ regeneration. Here we describe a facile generation of an adjustable and robust gradient using a single- or multi-material one-step fabrication strategy for 4D biofabrication. By simply photocrosslinking a mixed solution of a photocrosslinkable polymer macromer, photoinitiator (PI), UV absorber and live cells, a cell-laden gradient hydrogel with pre-programmable deformation can be generated. Gradient formation was demonstrated in various polymers including poly(ethylene glycol) (PEG), alginate, and gelatin derivatives using various UV absorbers that present overlap in UV spectrum with that of the PI UV absorbance spectrum. Moreover, this simple and effective method was used as a universal platform to integrate with other hydrogel-engineering techniques such as photomask-aided microfabrication, photo-patterning, ion-transfer printing, and 3D bioprinting to fabricate more advanced cell-laden scaffold structures. Lastly, proof-of-concept 4D tissue engineering was demonstrated in a study of 4D bone-like tissue formation. The strategy's simplicity along with its versatility paves a new way in solving the hurdle of achieving temporal shape changes in cell-laden single-component hydrogel scaffolds and may expedite the development of 4D biofabricated constructs for biological applications.

show abstract

Section: Resultsmentioning

confidence: 99%

4D biofabrication via instantly generated graded hydrogel scaffolds

Ding

Lee

Ayyagari

et al. 2022

Bioactive Materials

View full text Add to dashboard Cite

show abstract

“…Microfluidic approaches as well as engineered matrices offer a cell-extrinsic based control for signaling cues ( Brassard and Lutolf, 2019 ). For instance, shape-morphing materials dubbed kinomorphs can rationally control the shape and size of multicellular networks ( Viola et al., 2020 ). Additionally, self-organization of intestinal organoids-on-a-chip using scaffold was shown to enable regulation of morphological specifications.…”

Section: Significant Advances So Farmentioning

confidence: 99%

Synthetic living machines: A new window on life

Ebrahimkhani

Levin

2021

iScience

View full text Add to dashboard Cite

Summary Increased control of biological growth and form is an essential gateway to transformative medical advances. Repairing of birth defects, restoring lost or damaged organs, normalizing tumors, all depend on understanding how cells cooperate to make specific, functional large-scale structures. Despite advances in molecular genetics, significant gaps remain in our understanding of the meso-scale rules of morphogenesis. An engineering approach to this problem is the creation of novel synthetic living forms, greatly extending available model systems beyond evolved plant and animal lineages. Here, we review recent advances in the emerging field of synthetic morphogenesis, the bioengineering of novel multicellular living bodies. Emphasizing emergent self-organization, tissue-level guided self-assembly, and active functionality, this work is the essential next generation of synthetic biology. Aside from useful living machines for specific functions, the rational design and analysis of new, coherent anatomies will greatly increase our understanding of foundational questions in evolutionary developmental and cell biology.

show abstract

“…62,63 These traction forces are ubiquitous and implicated in dynamic tissue processes (e.g. contraction), [62][63][64] and they may induce remodeling of the supramolecular coiled coil system. Since the conjugated T-peptide provides open and dynamic sites for coiled coil complexes to form, we postulate that cells may be able to reorganize the physical locations of the A-peptide motifs on the NorHA hydrogel surface through traction forcesthus providing a dynamic surface that leads to increased cell area.…”

Section: Papermentioning

confidence: 99%