Flexible shape-memory scaffold for minimally invasive delivery of functional tissues

Montgomery, Miles; Ahadian, Samad; Huyer, Locke Davenport; Rito, Mauro Lo; Civitarese, Robert; Vanderlaan, Rachel D.; Wu, Jun; Reis, Lewis A.; Momen, Abdul; Akbari, Saeed; Pahnke, Aric; Li, Ren‐Ke; Caldarone, Christopher A.; Radišić, Milica

doi:10.1038/nmat4956

Cited by 300 publications

(251 citation statements)

References 39 publications

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“…Ideally, scaffolds should promote cell–material interactions, support the movement of nutrients and waste, possess good biocompatibility, and have appropriate mechanical properties [49]. However, their placement in the body remains a challenge and often requires performing an invasive surgical procedure [73]. Previously developed injectable strategies that rely on in situ gelation post-injection often face limitations such as inflammation or poor biophysical properties [74].…”

Section: Discussionmentioning

confidence: 99%

Injectable Hyaluronic Acid-co-Gelatin Cryogels for Tissue-Engineering Applications

et al. 2018

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Polymeric scaffolds such as hydrogels can be engineered to restore, maintain, or improve impaired tissues and organs. However, most hydrogels require surgical implantation that can cause several complications such as infection and damage to adjacent tissues. Therefore, developing minimally invasive strategies is of critical importance for these purposes. Herein, we developed several injectable cryogels made out of hyaluronic acid and gelatin for tissue-engineering applications. The physicochemical properties of hyaluronic acid combined with the intrinsic cell-adhesion properties of gelatin can provide suitable physical support for the attachment, survival, and spreading of cells. The physical characteristics of pure gelatin cryogels, such as mechanics and injectability, were enhanced once copolymerized with hyaluronic acid. Reciprocally, the adhesion of 3T3 cells cultured in hyaluronic acid cryogels was enhanced when formulated with gelatin. Furthermore, cryogels had a minimal effect on bone marrow dendritic cell activation, suggesting their cytocompatibility. Finally, in vitro studies revealed that copolymerizing gelatin with hyaluronic acid did not significantly alter their respective intrinsic biological properties. These findings suggest that hyaluronic acid-co-gelatin cryogels combined the favorable inherent properties of each biopolymer, providing a mechanically robust, cell-responsive, macroporous, and injectable platform for tissue-engineering applications.

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Section: Discussionmentioning

confidence: 99%

Injectable Hyaluronic Acid-co-Gelatin Cryogels for Tissue-Engineering Applications

et al. 2018

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“…For example, by advanced new 3D stamping technique, POMC has recently been fabricated into a AngioChip scaffold with built-in branching microchannel networks to generate perusable vasculature enabling direct surgical anastomosis [20]. Meanwhile, POMC enables the microfabricated lattice design into scaffold with shape memory, using a combination of soft-lithography and injection molding, for functional tissue delivery via injection [21]. Notably, incorporation of maleic anhydride in POMC also enabled the ultra-finely tuning of optical properties to possess a higher refractive index than POC with an index difference of ~0.003, comparable to that between the cladding and the core of conventional silica optical fibers.…”

Section: Chemistry Considerations For Citrate-based Biomaterials Designmentioning

confidence: 99%

“…More importantly, together with either human embronic stem cells (hESC) derived or neonatal rate cardiomyocytes, AngioChip scaffolds confer the engineering of fully endothelialized cardiac tissues with the thickness of 1.75–2 mm, with high cell viability under perfusion, and with the capability of surgical anastomosis to host vasculature [20]. In another study, POMC, when fabricated into injectable cardiac patches with microfabricated lattice design and loaded with cardiomyocytes, have shown to significantly improve cardiac function following myocardial infarction in a rat, serving as a flexible scaffold for invasive delivery of functional cardiac tissues [21]. …”

Section: Biology Considerations For Biomaterials Design and Applicationmentioning

confidence: 99%

Citrate chemistry and biology for biomaterials design

Gerhard

Lü

et al. 2018

Biomaterials

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Leveraging the multifunctional nature of citrate in chemistry and inspired by its important role in biological tissues, a class of highly versatile and functional citrate-based materials (CBBs) has been developed via facile and cost-effective polycondensation. CBBs exhibiting tunable mechanical properties and degradation rates, together with excellent biocompatibility and processability, have been successfully applied in vitro and in vivo for applications ranging from soft to hard tissue regeneration, as well as for nanomedicine designs. We summarize in the review, chemistry considerations for CBBs design to tune polymer properties and to introduce functionality with a focus on the most recent advances, biological functions of citrate in native tissues with the new notion of degradation products as cell modulator highlighted, and the applications of CBBs in wound healing, nanomedicine, orthopedic, cardiovascular, nerve and bladder tissue engineering. Given the expansive evidence for citrate's potential in biology and biomaterial science outlined in this review, it is expected that citrate based materials will continue to play an important role in regenerative engineering.

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“…Scaffolds made of injectable shape‐memory biomaterials may allow non‐invasive implantation surgery based on the use of small catheters. Indeed, cardiac patches performed with these flexible materials may significantly improve cardiac function and are promising for clinical translation …”

Section: Stem Cell Vulnerability Requires a Smooth Deliverymentioning

confidence: 99%

“…Indeed, cardiac patches performed with these flexible materials may significantly improve cardiac function and are promising for clinical translation. 129…”

Section: S Tem Cell V Ulner Ab Ilit Y Requ Ire S a S Mooth Deliverymentioning

confidence: 99%

Turning regenerative technologies into treatment to repair myocardial injuries

Carotenuto

Teodori

Maccari

et al. 2019

J Cellular Molecular Medi

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Regenerative therapies including stem cell treatments hold promise to allow curing patients affected by severe cardiac muscle diseases. However, the clinical efficacy of stem cell therapy remains elusive, so far. The two key roadblocks that still need to be overcome are the poor cell engraftment into the injured myocardium and the limited knowledge of the ideal mixture of bioactive factors to be locally delivered for restoring heart function. Thus, therapeutic strategies for cardiac repair are directed to increase the retention and functional integration of transplanted cells in the damaged myocardium or to enhance the endogenous repair mechanisms through cell‐free therapies. In this context, biomaterial‐based technologies and tissue engineering approaches have the potential to dramatically impact cardiac translational medicine. This review intends to offer some consideration on the cell‐based and cell‐free cardiac therapies, their limitations and the possible future developments.

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Flexible shape-memory scaffold for minimally invasive delivery of functional tissues

Cited by 300 publications

References 39 publications

Injectable Hyaluronic Acid-co-Gelatin Cryogels for Tissue-Engineering Applications

Injectable Hyaluronic Acid-co-Gelatin Cryogels for Tissue-Engineering Applications

Citrate chemistry and biology for biomaterials design

Turning regenerative technologies into treatment to repair myocardial injuries

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