A rapid crosslinking injectable hydrogel for stem cell delivery, from multifunctional hyperbranched polymers via RAFT homopolymerization of PEGDA

Dong, Yixiao; Qin, Yue Mei; Dubaa, Marie; Killion, John A.; Gao, Yongsheng; Zhao, Tianyu; Zhou, Daohong; Duscher, Dominik; Geever, Luke M.; Gurtner, Geoffrey C.; Wang, Wenxian

doi:10.1039/c5py00678c

Cited by 49 publications

(56 citation statements)

References 50 publications

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“…It is difficult to make polymers containing side‐chain methacrylate from dimethacrylate‐based monomers, because of formation of cross‐linked polymeric gels or hyperbranched polymers . Herein, the benefit of trans ‐esterification reaction was proven by incorporation of methacrylate moieties into the side chain of P(MAEO‐ co ‐PFPMA) copolymer by treating CP3 with 2‐hydroxyethyl methacrylate (HEMA).…”

Section: Resultsmentioning

confidence: 99%

“…[44] It is difficult to make polymers containing side-chain methacrylate from dimethacrylate-basedm onomers, because of formation of cross-linked polymeric gels or hyperbranched polymers. [45,46] Herein, the benefit of trans-esterification reaction was provenb yi ncorporation of methacrylate moieties into the side chain of P(MAEO-co-PFPMA) copolymerb yt reating CP3 with 2-hydroxyethyl methacrylate( HEMA). The resultant polymer was characterizedb yt he 1 HNMR spectrum, in which signals for CH 2 =C(CH 3 )À (2 H) protons appeared at 5.12 and 6.12 ppm ( Figure S11B of the Supporting Information).…”

Section: Trans-esterificationmentioning

confidence: 99%

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Functional‐Polymer Library through Post‐Polymerization Modification of Copolymers Having Oleate and Pentafluorophenyl Pendants

Maiti

Haldar

Rajasekhar

et al. 2017

Chemistry A European J

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Poly[2-(methacryloyloxy)ethyl oleate-co-pentafluorophenyl methacrylate] [P(MAEO-co-PFPMA)] random copolymers with oleate and pentafluorophenyl side-chain pendants were synthesized. These copolymers were utilized as dual-reactive polymeric scaffolds in a range of post-polymerization modification strategies involving thiol-ene and para-fluoro-thiol substitution, amidation, trans-esterification, and epoxidation followed by amidation. The 2-(methacryloyloxy)ethyl oleate (MAEO) functional handle in the copolymer is open to functionalization at its internal double bond through thermally initiated thiol-ene reaction, whereas the pentafluorophenyl moiety of the pentafluorophenyl methacrylate (PFPMA) unit undergoes para-fluoro-thiol substitution under basic conditions at room temperature. By means of these modification approaches, the P(MAEO-co-PFPMA) copolymer was orthogonally ligated with thiol compounds having, for example, alkyl, hydroxyl, and protected amine functional groups. Furthermore, different functional groups such as benzyl, allyl, methacrylate, pyrene, and water-soluble poly(ethylene glycol) were easily introduced into the side chain of the P(MAEO-co-PFPMA) copolymer by amidation, trans-esterification, and epoxidation followed by amidation. Functionalization of both the reactive pendants with the various organic substituents was confirmed by H and F NMR spectroscopy, gel permeation chromatography, and fluorescence spectroscopy.

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Section: Resultsmentioning

confidence: 99%

Section: Trans-esterificationmentioning

confidence: 99%

Functional‐Polymer Library through Post‐Polymerization Modification of Copolymers Having Oleate and Pentafluorophenyl Pendants

Maiti

Haldar

Rajasekhar

et al. 2017

Chemistry A European J

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“…Novel methods including chemo-selective crosslinking strategies (e.g. click chemistry) are designed to produce controlled crosslinking of hydrogels in situ under physiological conditions without toxic additives [120, 121]. …”

Section: Fabrication Of Injectable Scaffoldsmentioning

confidence: 99%

Injectable scaffolds: Preparation and application in dental and craniofacial regeneration

Chang

Ahuja

et al. 2017

Materials Science and Engineering: R: Reports

198

170

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Injectable scaffolds are appealing for tissue regeneration because they offer many advantages over pre-formed scaffolds. This article provides a comprehensive review of the injectable scaffolds currently being investigated for dental and craniofacial tissue regeneration. First, we provide an overview of injectable scaffolding materials, including natural, synthetic, and composite biomaterials. Next, we discuss a variety of characteristic parameters and gelation mechanisms of the injectable scaffolds. The advanced injectable scaffolding systems developed in recent years are then illustrated. Furthermore, we summarize the applications of the injectable scaffolds for the regeneration of dental and craniofacial tissues that include pulp, dentin, periodontal ligament, temporomandibular joint, and alveolar bone. Finally, our perspectives on the injectable scaffolds for dental and craniofacial tissue regeneration are offered as signposts for the future advancement of this field.

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“…Hydrogel–host interactions may be decoupled from the delivery process through a needles or catheter by using shear‐thinning hydrogels . Other methods to induce crosslinking with macromolecules to form a hydrogel include chemical crosslinking by click chemistry, Michael addition, Schiff base reaction, and Diels–Alder reaction . Compared with physical crosslinking processes, chemical crosslinking provides better control in mechanical strength and degradation.…”

Section: Design and Fabrication Of Functional Biomaterials For Stem Cmentioning

confidence: 99%

Advanced Functional Biomaterials for Stem Cell Delivery in Regenerative Engineering and Medicine

Wang

Rivera‐Bolanos

Jiang

et al. 2019

Adv Funct Materials

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Stem cell-based therapies can potentially regenerate many types of tissues and organs, thereby providing solutions to a variety of diseases and injuries. However, acute cell death, uncontrolled differentiation, and low functional engraftment yields remain critical obstacles for clinical translation. Advanced functional biomaterial scaffolds that can deliver stem cells to the targeted tissues/organs and promote stem cell survival, differentiation, and integration to host tissues may potentially transform the clinical outcome of stem cellbased regenerative therapies. In this review, the authors briefly summarize sources of stem cells for transplantation, present the current state of the art in biomaterial design for stem cell delivery, and provide critical analysis for existing materials. Applications to the cardiovascular, neural, and musculoskeletal systems are highlighted with recent nonclinical studies and clinical trials. The authors also discuss how advances in biomaterials research can contribute to regenerative medicine research and stem cell therapies. application in the clinical setting. These challenges include the manipulation of stem cell fate pre-and post-transplantation and protection of the cells during and after their delivery to the target site. [3] The microenvironment, also referred to as stem cell niche, plays key roles in stem cell fate determination. [4] In vivo, the interplay among complex microenvironmental cues precisely regulate stem cell function so they may undergo self-renewal to maintain the stem cell pool or to undergo differentiation to regenerate tissue. However, the majority of current stem cell transplant strategies in clinical trials use injections with a buffer fluid, which provides insufficient protection and manipulation of cell fate. [5] As a result, the vast majority of transplanted cells die during their delivery or within a short time thereafter. Engineering approaches, especially in the biomaterials field, offer strategies to address the challenges and current limitations of stem cell therapy. Innovative design of biomaterials enables delicate control of their biophysical and biochemical properties, which provides an artificial niche to regulate stem cell functions. Delivery of cells via engineered biomaterial carriers can promote cell survival by reducing the microenvironmental shock (shear stress, inflammation, etc.), improving cell retention by preventing cell leakage and enhancing regenerative responses from delivered cells by manipulating stem cell fate. [6] In this review, we summarize and provide perspective on stem cell sources and the state of the art in the design, fabrication, and application of advanced functional biomaterials for stem cell delivery. We discuss current stem cell phenotypes and the requirements in biomaterial design and fabrication for successful stem cell transplantation. We also highlight recent nonclinical and clinical studies of stem cell therapy in the cardiovascular, neural, and musculoskeletal systems. Lastly, we conclude with an outlo...

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A rapid crosslinking injectable hydrogel for stem cell delivery, from multifunctional hyperbranched polymers via RAFT homopolymerization of PEGDA

Cited by 49 publications

References 50 publications

Functional‐Polymer Library through Post‐Polymerization Modification of Copolymers Having Oleate and Pentafluorophenyl Pendants

Functional‐Polymer Library through Post‐Polymerization Modification of Copolymers Having Oleate and Pentafluorophenyl Pendants

Injectable scaffolds: Preparation and application in dental and craniofacial regeneration

Advanced Functional Biomaterials for Stem Cell Delivery in Regenerative Engineering and Medicine

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