Translational Applications of Hydrogels

Correa, Santiago; Grosskopf, Abigail K.; Hernandez, Hector Lopez; Chan, Doreen; Yu, Anthony C.; Stapleton, Lyndsay M.; Appel, Eric A.

doi:10.1021/acs.chemrev.0c01177

Cited by 496 publications

(355 citation statements)

References 644 publications

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“…PNP hydrogels of different formulations exhibit tunable shear-thinning, self-healing, yield-stress, and viscoelastic properties that enable them to create a lubricious barrier between organs and tissues that reduces the incidence and severity of adhesions. 22 – 24 We have previously demonstrated that hydrogels that are too soft and weak flow too easily when perturbed in the body, leaving target tissues too quickly while adhesions are still developing. Hydrogels that are too stiff are easily dislodged from target tissues as the yield stress of such materials exceeds their adhesion strength to the tissue.…”

Section: Resultsmentioning

confidence: 99%

PNP Hydrogel Prevents Formation of Symblephara in Mice After Ocular Alkali Injury

Swarup

Grosskopf

Stapleton

et al. 2022

Trans. Vis. Sci. Tech.

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Purpose To create an alkali injury symblephara mouse model to study conjunctival fibrosis pathophysiology and test polymer nanoparticle (PNP) hydrogel as a preventative therapeutic. Methods Mice were injured using NaOH-soaked filter paper to determine the optimal NaOH concentration to induce the formation of symblephara. Injured mice were observed for 7 days to detect the formation of symblephara. Forniceal shortening observed on hematoxylin and eosin (H&E)-stained tissue sections was used as a symblephara marker. Alpha-smooth muscle actin (α-SMA) expression, Masson's trichrome assay, and periodic acid–Schiff (PAS) staining were used to determine myofibroblast expression, collagen deposition, and goblet cell integrity. PNP hydrogel, with multivalent, noncovalent interactions between modified biopolymers and nanoparticles, was applied immediately after alkali injury to determine its ability to prevent the formation of symblephara. Results Forniceal shortening was observed in H&E images with 1N NaOH for 2 minutes after 7 days without globe destruction. PNP hydrogel prevented forniceal shortening after alkali injury as observed by H&E histology. α-SMA expression and collagen deposition in eye tissue sections were increased in the fornix after injury with 1N NaOH compared with uninjured controls. PNP hydrogel treatment immediately after injury reduced α-SMA expression and collagen deposition in the forniceal region. Mucin-secreting goblet cells stained with PAS were significantly lower in alkali-injured and PNP hydrogel–treated conjunctivas than in uninjured control conjunctivas. Conclusions We observed that 1N NaOH for 2 minutes induced maximal forniceal shortening and symblephara in mice. PNP hydrogel prevented forniceal shortening and conjunctival fibrosis after injury. This first murine model for symblephara will be useful to study fibrosis pathophysiology after conjunctival injury and to determine therapeutic targets for cicatrizing diseases. Translational Relevance This mouse model of symblephara can be useful for studying conjunctival scarring disease pathophysiology and preventative therapeutics. We tested PNP hydrogel, which prevented the formation of symblephara after injury.

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Section: Resultsmentioning

confidence: 99%

PNP Hydrogel Prevents Formation of Symblephara in Mice After Ocular Alkali Injury

Swarup

Grosskopf

Stapleton

et al. 2022

Trans. Vis. Sci. Tech.

Self Cite

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“…In addition to the implantable form, an injectable hydrogel has shown impressive therapeutic effects as a carrier for cancer vaccine and anti-PD-1 monoclonal antibodies ( Li et al, 2020 ). A recent review covers this area in depth from the hydrogel materials, therapeutic strategies as well as clinical perspectives ( Correa et al, 2021 ).…”

Section: Moving Towards Clinical Translationmentioning

confidence: 99%

Polysaccharide-Based Hydrogels for Microencapsulation of Stem Cells in Regenerative Medicine

Lee

Khoo

et al. 2021

Front. Bioeng. Biotechnol.

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Stem cell-based therapy appears as a promising strategy to induce regeneration of damaged and diseased tissues. However, low survival, poor engraftment and a lack of site-specificity are major drawbacks. Polysaccharide hydrogels can address these issues and offer several advantages as cell delivery vehicles. They have become very popular due to their unique properties such as high-water content, biocompatibility, biodegradability and flexibility. Polysaccharide polymers can be physically or chemically crosslinked to construct biomimetic hydrogels. Their resemblance to living tissues mimics the native three-dimensional extracellular matrix and supports stem cell survival, proliferation and differentiation. Given the intricate nature of communication between hydrogels and stem cells, understanding their interaction is crucial. Cells are incorporated with polysaccharide hydrogels using various microencapsulation techniques, allowing generation of more relevant models and further enhancement of stem cell therapies. This paper provides a comprehensive review of human stem cells and polysaccharide hydrogels most used in regenerative medicine. The recent and advanced stem cell microencapsulation techniques, which include extrusion, emulsion, lithography, microfluidics, superhydrophobic surfaces and bioprinting, are described. This review also discusses current progress in clinical translation of stem-cell encapsulated polysaccharide hydrogels for cell delivery and disease modeling (drug testing and discovery) with focuses on musculoskeletal, nervous, cardiac and cancerous tissues.

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“…Polymeric structures importantly allow for local and/or sustained release of active therapeutics and have been long a subject of investigation in gliomas, particularly as implants in the post-resection cavity [45][46][47][48][49][50][51][52][53][54]. BCNU wafers were approved for local delivery of carmustine to the glioma resection cavity in 1996, leading the pack on implantable local therapeutics for brain tumors [55,56].…”

Section: Polymeric Structures and Hydrogelsmentioning

confidence: 99%

Applying Synthetic Biology with Rational Design to Nature’s Greatest Challenges: Bioengineering Immunotherapeutics for the Treatment of Glioblastoma

Mashouf

Shah

et al. 2021

Immuno

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Improvements in bioengineering methodology and tools have allowed for significant progress in the development of therapeutics and diagnostics in medicine, as well as progress in many other diverse industries, such as materials manufacturing, food and agriculture, and consumer goods. Glioblastomas present significant challenges to adequate treatment, in part due to their immune-evasive and manipulative nature. Rational-design bioengineering using novel scaffolds, biomaterials, and inspiration across disciplines can push the boundaries in treatment development to create effective therapeutics for glioblastomas. In this review, we will discuss bioengineering strategies currently applied across diseases and disciplines to inspire creative development for GBM immunotherapies.

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Translational Applications of Hydrogels

Cited by 496 publications

References 644 publications

PNP Hydrogel Prevents Formation of Symblephara in Mice After Ocular Alkali Injury

PNP Hydrogel Prevents Formation of Symblephara in Mice After Ocular Alkali Injury

Polysaccharide-Based Hydrogels for Microencapsulation of Stem Cells in Regenerative Medicine

Applying Synthetic Biology with Rational Design to Nature’s Greatest Challenges: Bioengineering Immunotherapeutics for the Treatment of Glioblastoma

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