Sherborne and Claeyssens


               Ref  [61]  [57]  [87]  [64]  [65]  [67]  [66]  [24]  [68]  [69]  [70,71]  [73]  [72]  [74]  [82]  [27]  [29]










               Characteristics  High thermal resistance  Heparin functionalized to purify   Enterovirus 71 (EV71) Kaolin-loaded, 3D-printed cure   on dispense 3D printed  Surface epoxy groups can be   chemically modified Flexible polyHIPE membranes  that can be rolled into a module  Proteins recovery with no   obvious sign of unfolding  High column efficiency and   protein-binding capacity Redox-initiated polymerization for  in situ polymerization of a filter Made using r










                  functionalization  Amino (–NH2)   Modified to bear weak   anion exchange groups  Surface functionalized   to create weak anion   exchange supports  Anion exchange   functionality using   Surface modified by  Air oxidation produces   hydroperoxide species  Sulfonated to produce   hydrophilic surface  In situ functionalization   using sodium acrylate  amphiphilic block   copolymers for potential   surface functionalization


               Surface   functionalized  Heparin  -  iodomethane  diethylamine  -  -  -  -  Stabilized with   -  -




               Interconnect   (μm)  1.1–2.4  0.2–0.5  ≈0.75  0.1–0.5  1 – 3  -  -  2.4–6.4  7.8–13.5  -  -  -  0.19–0.59  0.1–3  1–5  0.2–5.9  - The monomer abbreviations used are: MMA, methyl methacrylate; EGDMA, ethylene glycol dimethacrylate, DVB, divinylbenzene; GMA, glycidyl methacrylate; EHA, ethylhexyl acrylate; BeMA, benzyl  methacrylate, TEOS, tetraethyl orthosilicate; St, styrene; DCPD, dicyclopentadiene, P4VP, polyvinylpyridine; PEG, polyethylene glycol; SA, so







               Pore size   (μm)  3.0–7.4  0.5–2  ≈3  1–10  3 – 10  -  0.6–0.1  16–29  82.3–145.6  -  1–4  23.9±16.4  -  1.08–1.12  1–80  5–50  0.8–25 and  0.6–4.5  1.6–9.3





                        Column to purify virus for   3D-printed hemostatic and  absorbent polyHIPE wound   Protein separation through   Protein purification by   Protein separation by   In situ cured open pored   Decontamination of chemical   warfare agent and self-  decontaminating air filter  Chromatographic separation   Ultrafiltration of microalgae  Bacteria filter and its   inactivation using NIR   Improved mechanical   properties of polyHIPE





               Application  Air filter  vaccine production  dressing  chromatography  chromatography  Ion exchange   chromatography  chromatography  filter  Oil recovery  Oil spill recovery  Microfiltration  of nanoparticles  sterilization  Ultra-low-density   polyHIPE


            Table 2. PolyHIPE filter-based applications  Poly(St-MMA-DVB)  Poly(St-GMA-DVB)  PEGMA-SA-PEGDA  Poly(GMA -EGDMA)  Poly(GMA -EGDMA-EHA)  Epoxy resin-based monolith   with GMA brushes  Poly(GMA -co-EGDMA)  Poly(MMA-co-EGDMA) and   poly(BeMa-co-EGDMA) Sulfonated polystyrene, EGDMA,   TEOS, and butyl acrylate  Poly(St-DVB) with EHA or   ethyl vinyl benzene  Poly(St-DVB) and   poly(EGDMA) Poly(butyl acrylate- EGDMA)  Poly(St-b -P4VP)  Poly(MMA-EGDMA)  PEGMA, polye










                                                                   Poly(St-DVB)
                                                                    Poly(DCPD)






               Material                International Journal of Bioprinting (2021)–Volume 7, Issue 1   Poly(St-DVB)  53