Modulating Biofunctional starPEG Heparin Hydrogels by Varying Size and Ratio of the Constituents

Welzel, Petra B.; Prokoph, Silvana; Zieris, Andrea; Grimmer, Milauscha; Zschoche, Stefan; Freudenberg, Uwe; Werner, Carsten

doi:10.3390/polym3010602

Cited by 73 publications

(79 citation statements)

References 55 publications

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“…39,47 The higher modulus and crosslinking density is also reflected in a higher gel content that for the low modulus gels is 75% and for the higher modulus gels almost approached 90%. The robust nature of thiol-Michael addition click reaction has unique advantages as compared to traditional coupling strategies offering high bio-orthogonality that involve only thiols and methacrylates/acrylates to form stable thio-ether bonds without forming any side product.…”

Section: Please Do Not Adjust Marginsmentioning

confidence: 97%

“…S1 and S2 of the ESI ¶. 38,39 Adjustment of pH (≈ 8-8.2), generated thiolate anions and promoted faster nucleophilic attack on MAC to form stable hydrogels in short tenure compared to formulations without the catalyst (pH 6.6 ͌ 6-8). [34][35]40 Fig.…”

Section: Construction Of Covalently Cross-linked Hydrogels Using Bio-mentioning

confidence: 99%

“…Several reports had explored the major factors affecting hydrogel mechanical properties 44,45 including concentration of components, crosslinking density, molecular weight 38 that supports our strategy to easily modulate the stiffness of hydrogel by (1) varying the final concentration of MAC, (2) varying the degree of collagen modification, (3) varying the molecular weight and molecular architecture of crosslinking components. Several authors have already shown the parameters influencing the crosslinking density and mechanical properties of hydrogel 38,39 for e.g. the maximum stiffness reported by crosslinking hyaluronic acid functional groups using thiol-Michael addition click reaction was about 8.2 kPa after 456 h of post gelation 46 ; but we are first to design collagen derived hydrogels with relatively high modulus of 100kPa using thiol-Michael Addition Click reaction in a very short time (3-4h).…”

Section: Construction Of Covalently Cross-linked Hydrogels Using Bio-mentioning

confidence: 99%

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Functionalised type-I collagen as a hydrogel building block for bio-orthogonal tissue engineering applications

et al. 2016

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In this study, we derivatized type I collagen without altering its triple helical conformation to allow for facile hydrogel formation via Micheal addition of thiols to methacrylates without the addition of other crosslinking agents. This method provides the flexibility needed for fabrication of injectable hydrogels or pre-fabricated implantable scaffolds, using the same components by tuning the modulus from Pa to kPa. Enzymatic degradability of the hydrogels can be also easily fine tuned by variation of the ratio and type of cross-linking component. The structural morphology reveals lamellar structure mimicking native collagen fibrils. The versatility of this material is demonstrated by its use as a pre-fabricated substrate for culturing human corneal epithelial cells, and as an injectable hydrogel for 3-D encapsulation of cardiac progenitor cells.Keywords: bio-orthogonal chemistry, tissue engineering, pre-fabricated scaffolds, injectable scaffolds, cell compatible. IntroductionThe extracellular matrix (ECM) provides mechanical support as well as instructive signals for cell development, migration, proliferation, survival and function. Natural biopolymers derived from the ECM are therefore by nature, very biocompatible and bio-interactive. [1][2][3] The most abundant is collagen that has extensively been used to prepare scaffolds for tissue repair and engineering. This structural ECM component has, however limited number of functional groups that can be used for direct crosslinking. 4, 5 The main functional groups are amine and carboxylic acids, which allows collagen to crosslinked (e.g. via UV, thermal heating, carbodiimides, epoxy or aldehyde crosslinkers). Conversely, synthetic polymers such as poly (ethylene) glycols, poly (lactic acids), poly (methacryl/acryl amides) etc.), are easily chemically modified for facile processing than collagen.6 However, synthetic polymers have issues with biocompatibility, degradability and do not completely integrate within the host.7-9 Hence, synthetic routes to introduce biocompatible crosslinkable modifications on the protein structure, (reactive moieties), are highly desirable for the development of the next generation of regenerative materials for tissue engineering. Particularly, introducing reactive moieties in collagen would expand its functionality allowing for development of a wider range of scaffolds that can serve as regeneration templates. 10, 11 Several routes to render collagen more processable while retaining its in vitro/ in vivo or clinical bio interactive capacity for promoting tissue regeneration have been explored. [12][13][14] The simplest method is blending collagen with natural or synthetic polymers (such as hyaluronic acid, chitosan, poly(ethylene oxide), polylactic acid, and polyglycolic acid) to fabricate scaffolds. 5, 15 Crosslinked collagen-chitosan hydrogels, which were mechanically stronger than collagen alone, promoted angiogenesis and has been used for islet transplantations in murine models. 16 Li et al.co-polymerized collagen with lam...

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Section: Please Do Not Adjust Marginsmentioning

confidence: 97%

Section: Construction Of Covalently Cross-linked Hydrogels Using Bio-mentioning

confidence: 99%

Section: Construction Of Covalently Cross-linked Hydrogels Using Bio-mentioning

confidence: 99%

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Functionalised type-I collagen as a hydrogel building block for bio-orthogonal tissue engineering applications

et al. 2016

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“…[ 22 , 30 , 31 ] The average mesh size (distance between two crosslinks or entanglement points) ξ was calculated based on rubber elastic theory that can be applied on hydrogels that has elastic character. [ 31 ] The Mc and ξ parameters were derived from the following Equations 1 and 2 :…”

Section: Discerning Hydrazone Stability By Fine-tuning Electronic Chamentioning

confidence: 99%

Smart Design of Stable Extracellular Matrix Mimetic Hydrogel: Synthesis, Characterization, and In Vitro and In Vivo Evaluation for Tissue Engineering

Oommen

Wang

Kisiel

et al. 2012

Adv Funct Materials

114

127

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The simplicity and versatility of hydrazone crosslinking has made it a strategy of choice for the conjugation of bioactive molecules. However, the labile nature of hydrazone linkages and reversibility of this coupling reaction restricts its full potential. Based on the fundamental understanding of hydrazone stability, this problem is circumvented by resonance‐stabilization of a developing N2 positive charge in a hydrazone bond. A novel chemistry is presented to develop a resilient hydrazone bond that is stable and non‐ reversible under physiological conditions. A carbodihydrazide (CDH) type hydrazide derivative of the biomolecule forms intrinsically stabilized hydrazone‐linkages that are nearly 15‐fold more stable at pH 5 than conventional hydrazone. This chemoselective coupling reaction is catalyst‐free, instantaneous, and virtually non‐cleavable under physiological conditions, therefore can serve as a catalyst‐free alternative to click chemistry. This novel crosslinking reaction is used to tailor a hyaluronan hydrogel, which delivered exceptional hydrolytic stability, mechanical properties, low swelling, and controlled enzymatic degradation. These desired characteristics are achieved without increasing the chemical crosslinking. The in vivo evaluation of this hydrogel revealed neo‐bone with highly ordered collagen matrix mimicking natural bone regeneration. The proximity ligation assay or PLA is used to detect blood vessels, which highlighted the quality of engineered tissue.

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“…These composite polymers fabricated with HDDA as a crosslinker, and starPEG, a precursor to compliant hydrogels [19,20], are two orders of magnitude more compliant than poly(HDDA) (78.15 ± 1.5 kPa and 2.59 ± 0.11 MPa, respectively) as measured by AFM-enabled nanoindentation (Figure 5a). Previously reported E of poly(HDDA) are two orders of magnitude higher, likely due to differences in fitting models (e.g.…”

Section: Bulk Mechanics Of Poly(hdda)-starpeg Are Relevant In the Conmentioning

confidence: 99%

Poly(HDDA)-Based Polymers for Microfabrication and Mechanobiology

Espinosa-Hoyos

Fang

et al. 2017

MRS Advances

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Materials processing and additive manufacturing afford exciting opportunities in biomedical research, including the study of cell-material interactions. However, some of the most efficient materials for microfabrication are not wholly suitable for biological applications, require extensive post-processing or exhibit high mechanical stiffness that limits the range of applications. Conversely, materials exhibiting high cytocompatibility and low stiffness require long processing times with typically decreased spatial resolution of features. Here, we investigated the use of hexanediol diacrylate (HDDA), a classic and efficient polymer for stereolithography, for oligodendrocyte progenitor cell (OPC) culture. We developed composite HDDA-polyethylene glycol acrylate hydrogels that exhibited high biocompatibility, mechanical stiffness in the range of muscle tissue, and high printing efficiency at ~5 μm resolution.

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Modulating Biofunctional starPEG Heparin Hydrogels by Varying Size and Ratio of the Constituents

Cited by 73 publications

References 55 publications

Functionalised type-I collagen as a hydrogel building block for bio-orthogonal tissue engineering applications

Functionalised type-I collagen as a hydrogel building block for bio-orthogonal tissue engineering applications

Smart Design of Stable Extracellular Matrix Mimetic Hydrogel: Synthesis, Characterization, and In Vitro and In Vivo Evaluation for Tissue Engineering

Poly(HDDA)-Based Polymers for Microfabrication and Mechanobiology

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