Crosslinking method of hyaluronic-based hydrogel for biomedical applications

Abstract

In the field of tissue engineering, there is a need for advancement beyond conventional scaffolds and preformed hydrogels. Injectable hydrogels have gained wider admiration among researchers as they can be used in minimally invasive surgical procedures. Injectable gels completely fill the defect area and have good permeability and hence are promising biomaterials. The technique can be effectively applied to deliver a wide range of bioactive agents, such as drugs, proteins, growth factors, and even living cells. Hyaluronic acid is a promising candidate for the tissue engineering field because of its unique physicochemical and biological properties. Thus, this review provides an overview of various methods of chemical and physical crosslinking using different linkers that have been investigated to develop the mechanical properties, biodegradation, and biocompatibility of hyaluronic acid as an injectable hydrogel in cell scaffolds, drug delivery systems, and wound healing applications.

Keywords: Hyaluronic acid; crosslinking method; tissue engineering.

Figure 1.

Hyaluronic acid structure showing the disaccharide repeat units and sites for chemical modification.

Figure 2.

Coupling reagents for the activation of hyaluronic acid (HA)-COOH.

Figure 3.

Crosslinking agents for modification of –OH groups.

Figure 4.

Synthesis of oxidized hyaluronic acid (HA)-gelatin hydrogels: (a) crosslinking of HA and gelatin by ethyl(dimethylaminopropyl) carbodiimide/N-hydroxysuccinimide (EDC/NHS), (b) HAG polymer oxidation by sodium periodate, and (c) Oxi-HAG-ADH hydrogel synthesis, with imines bonding oxi-HAG and ADH.

Figure 5.

Commonly utilized vinyl groups in thiol-Michael addition reactions.

Figure 6.

(a) Synthesis protocol of thiol-modified hyaluronic acid (HA-SH). (b) ¹H-NMR (D₂O) spectra of HA and HA-SH (Mw = 0.1 MDa, Ds = 37.47%). (c) Biocompatibility of HA-SH polymers (Mw = 0.3 MDa, Ds = 55.44%) for chondrocytes, 3T3 cells and L929 cells after 48 h of co-culture (n = 3). (d) SEM micrograph of HA-SH hydrogel (Mw = 0.3 MDa, Ds = 55.44%, 3.0% (w/v)). (e) Image of HA-SH solution (Mw = 0.3 MDa, Ds = 55.44%, 3.0% (w/v)). (f) Image of HA-SH hydrogel. (g) Image of HA-SH solution derived from the decomposition of HA-SH hydrogel with DTT (100 mM). Source: Reproduced with permission. Copyright 2016, Elsevier B.V.

Figure 7.

(a) Schematic illustration to show formation of a hydrogel through click chemistry. (b) Gelation time of the hyaluronic acid/chondroitin sulfate (HA/CS)/gelatin click hydrogel as a function of CuCl concentration. (c) Macroscopic and (d) microscopic images of the hydrogel taken with a digital camera and by cryo-SEM at −195°C, respectively. (e) ¹H HR-MAS NMR spectra of the hydrogel. Source: Reproduced with permission. Copyright 2011 Acta Materialia Inc.

Figure 8.

Schematic representation of hyaluronic acid (HA)/pluronic hydrogels. (a) Slightly crosslinked three-dimensional network formation of HA/Pluronic hydrogels and their sol-gel transition behavior. (b) Sol-gel transition curves of HA/Pluronic hydrogels (∇) and HADN-L + Plu-SH hydrogels (○). Pluronic F127 hydrogel (●) was used as control. Source: Reproduced with permission. Copyright 2010, Royal Society of Chemistry.

Figure 9.

Reaction scheme and idealized structure of the Fe-hyaluronic acid (FeHA) network.

Figure 10.

Hematoxylin and eosin (H&E) and immunohistochemistry (IHC) staining of collagen type II in hADSC after 14 days of in vitro culture in hyaluronic acid (HA) and HA/sodium alginate (SAL) interpenetrating polymeric network (IPN) scaffolds. Scale bar = 20 μm. Source: Reproduced with permission. Copyright 2013, Elsevier B.V.

Figure 11.

Intracellular uptake and distribution of UnTHCPSi and UnTHCPSi–HA⁺ nanoparticles. TEM images and the corresponding numerically organized magnifications of ultra-thin sections of MDA-MB-231 and MCF-7 breast cancer cells exposed to UnTHCPSi and UnTHCPSi–HA⁺ at a concentration of 50 μg/mL, for 6 h at 37°C are shown. The conjugation of HA⁺ onto the surface of the UnTHCPSi nanoparticles has been shown to significantly enhance the interaction and consequently the uptake of the nanoparticles by both MDA-MB-231 and MCF-7 breast cancer cells. The nanoparticles associated with the cells are highlighted by blue arrows. Scale bars are 5 μm. Source: Reproduced with permission. Copyright 2014, Royal Society of Chemistry.

Figure 12.

Representative photographs of antimicrobial activities of PVA-HA membranes showing the appearance of microbial inhibition zones formed against seeded Staphylococcus aureus, Candida albicans, and Escherichia coli. Source: Reproduced with permission. Copyright 2015, Sociedade Brasileira de Quimica.