Table 1.
Representative click chemistry reaction methods, reactants, cell culture details, and their advantages and disadvantages. (In table format)
| S.no | Hydrogel preparation methods | Reactants | Cells/in vivo/in vitro | Gelation time and degradation | Advantages | Disadvantages | References |
|---|---|---|---|---|---|---|---|
| 1 | Copper-catalyzed click chemistry reactions | HA-hydrazine, collagen, and HA-aldehyde or HA-benzaldehyde, Copper (II) sulfate pentahydrate | hMSCs | Gelation in 5 min | Enhanced focal adhesion, cell spreading, fiber remodeling | Copper ions toxicity, reactive oxygen species generation, regional variation in viscosity due to rapid gelation, non-homogeneous gels | [51] |
| 2 | Diels–Alder click reactions | Furan-linked gelatin against maleimide-linked PEG, chitosan-Pluronic F127) | Cardiomyocyte cells, in vitro and in vivo | Gelation in 2 h, slower degradation rate in vitro | Injectable gels, fully-interpenetrating network, thermosensitive, cell adhesive | Slow gelation, reduced solubility of the functional groups, inability to be injected in vivo in few cases | [59] |
| N-maleoyl alanine terminated F127, furan grafted chondroitin sulfate, oxidized chondroitin sulfate, bone morphogenetic protein-4 | Rat mesenchymal stem cells, bone cells (repair), in vitro and in vivo | Gelation in 3 days, 14 days degradation in vitro | Easily modifiable, improved viscoelastic properties and rheological properties. Swellable, injectable, self-healing ability | [61] | |||
| Sodium alginate, bio glass and modified chondroitin sulphate | Cranial bone defect repair, in vitro and in vivo | Gelation in 3 days, 4 weeks at neutral pH, faster degradation at basic pH in vitro | Triple cross-linked injectable hydrogel, better physio-chemical properties | [60] | |||
| Furfurylamine linked chondroitin sulfate, F127 linked maleimido and PEG-AMI, bone morphogenetic protein-4 | Bone cells (repair) | Gelation in Less than one min | Non-covalent and covalent crosslinking, good biocompatibility | [17] | |||
| Furan linked HA, dexamethasone and maleimide linked HA | Human adipose-derived stem cells, in vitro | Gelation in 60 min, more than 21 days for degradation in vitro | Thermo-responsible hydrogels, dexamethasone-controlled release in local environment, non-cytotoxic, can deliver adipogenic factors | [57] | |||
| HA with furan adipic dihydrazide, HA with furan CHO and followed by addition of dimaleimide PEG | Chondrocyte cells (cartilage), in vitro | Gelation in 5 min | Mechanical properties, tissue adhesive, self-healing, pH responsiveness | [53] | |||
| 3 | Strain-promoted azide-alkyne cycloaddition (SP-AAC) reactions | Azadibenzocyclooctyne-modified dextran and azide-modified dextran | Chondrocyte cells(cartilage), in vitro | Gelation in 1.1 to 10.2 min, slow degradation rate up to 21 days in vitro | Gelation time modifiable using concentration variation and substitution degree of dextran, encapsulation of cells and cell spheroids | Reaction rate is lower than copper catalyzed reactions, alkynes are larger, trigger high perturbation, less ligation rate, high side reactions | [72, 114] |
| Dibenzocyclooctyl (DBCO)-modified HA, 4-arm PEG azide | Chondrocyte cells (cartilage), in vitro and in vivo | Gelation in 10–14 min, slow degradation up to 35 days in vivo | Nontoxic cross linker, good biocompatibility, in situ physical gelation, elastic modulus can be modified by varying concentration | [73] | |||
| Hyperbranched poly(ε-caprolactone) (hyPCL)32-(1R,8S,9 s)-bicyclo[6.1.0]non-4-yn-9-ylmethanol (hyPCL32-BCN) and hyPCL32-azide (hyPCL32-N3) | Bone (MC3T3 preosteoblast) cells | Gelation in 30 min | Injectable hyperbranched PCL, biocompatible, excellent support for cell adhesion and proliferation | [71] | |||
| 4-dibenzocyclooctynol functionalized PEG, 4 arm PEG tetraazide, protein igands (laminin), neurogenic differentiation factor (interferon-γ) | Neural stem cell, In vitro | Gelation in less than 5 min | Additional differentiation factors not required in medium, high cell viability, no UV light required | [16] | |||
| 4 | Thiol-ene-based click chemistry reactions | PEGDA, dithiothreitol, borox | Endothelial cells and neural stem cells, in vitro | Gelation within few min of stirring | Injectable, 3D printable, sacrificial removal enables tubular structure formation | Polymer substrates lack alkenes with electron deficiency, acid condition required for the reaction | [77] |
| 4-arm PEG norbornene, PEG dithiol, Protein array printing of collagen I, collagen III, collagen IV, fibronectin, laminin, elastin and hyaluronan | Smooth muscle cells, in vitro | Cellular stiffness and increased functional contractility, cell attachment and 3D infiltration | UV source needed in radical mediated reactions which may damage cells, oxygen sensitivity may result in disulfide formation; the presence of cysteine and amine group residues may compete with thiol group while hydrogel formation occurs. | [82] | |||
| Alkene-linked (allyl and norbornene residues), poly(oligoethylene glycol methacrylate)), cell adhesive peptides RGD and REDV | Human umbilical vein endothelial cells (HUVECs), in vitro | Photo-patterned peptides at the surface, development of cell array is achieved | [80] | ||||
| Norbornene-linked pectin macromer, monocysteine RGD peptide, biscysteine peptide with matrix metalloproteinase cleavage site | Human neonatal dermal fibroblasts, in vitro | Degradation9 h in enzymatic treatment in vitro | Cell surface receptors in pectin may increase cell attachment and integration, simple, fast, robust, independent modification of the biochemical or biophysical cues in the system is possible | [79] | |||
| 8-arm-PEG thiol macromer, thioester di(vinyl ether), caged thioester catalyst, norbornene RGD | Primary hMSCs, in vitro | Dynamic, modifiable visco-elastic properties, using pH, stoichiometry and crosslinker structure the hydrogel network can be modified, thiol-ester resembles biological reactions | [78] | ||||
| 5 | Oxime based click chemistry reactions | Aminooxy-terminated PEGs, aldehyde modified HA and collagen I | Schwann cells, HMSCs, in vitro | Less toxic to the cells, tunable properties, peptide, protein bonding is easier | Not bio-orthogonal | [22] |