Bioremediation for Sustainable Environmental Cleanup (Anju Malik, Vinod Kumar Garg)

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Bioremediation for Sustainable Environmental Cleanup

Along with sol-gel, spray drying and other advanced techniques like 3D bioprinting and

microfluidics could be applied for developing efficient biohybrids. Using these techniques,

biohybrids in various morphologies such as microparticles, sheet, fibre and scaffold could be

understood. Depending on their morphology, biohybrids could be used for various applications like

drug/gene delivery, biosensing, biomedical and environmental remediation.

Though a lot of advances have been made in the field of synthesis and application of biohybrids,

there are yet some challenges involved in synthesizing biohybrids in large quantities with accurate

precision and design, and understanding applications of biohybrids for constant monitoring and

applying them for continuous reactors. For this purpose, there is need to work in an interdisciplinary

way, where scientists from different areas like material science, biological sciences, chemical

sciences could come together. Regarding biocomponents, there is need for developing engineered

biomolecules with high biological activity, which could be associated with suitable supports. Till

today, as support organic and nanoparticle materials have been used , now there is need to develop

biogenic supports with extraordinary characteristics like intricate design of the surface structure and

chemical moieties. There is also a need to develop suitable fabricating process/techniques which

have precise control over operational parameters and in which the potential of both components

could be fully utilized.

In summary, the combination of biomolecules with supports enables biohybrid materials to act

as biomimetic material which results in a dynamic smart material. One can clearly see that advanced

characteristics (biocompatibility, flexibility, sensitivity towards analytes) associated with biohybrid

materials will enable them to achieve the desired results not only in biosensing and remediation but

also in several research areas.

References

Agriculture & Environment Research Unit, University of Hertfordshire, PPDB: The Pesticide Properties Database,

2012. http://sitem.herts.ac.uk/aeru/footprint/en/index.htm accessed in June 2012.

Ana, S. S., L. F. Santos, M. C. Mendes and J. F. Mano. 2020. Multi-layer pre-vascularized magnetic cell sheets for

bone regeneration. Biomater. 231: 119664.

Ashly, P. C., M. J. Joseph and P. V. Mohanan. 2011. Activity of diastase a-amylase immobilized on polyanilines

(PANIs). Food Chem. 127: 1808–1813.

Avnir, D., S. Braun, O. Lev and M. Ottolenghi. 1994. Enzymes and other proteins entrapped in sol-gel Materials.

Chem. Mater. 6: 1605.

Basso, A., P. Braiuca, S. Cantone, C. Ebert, P. Linda, P. Spizzo, P. Caimi, U. Hanefeld, G. Degrassi and L. Gardossi.

2007. In silico analysis of enzyme surface and glycosylation effect as a tool for efficient covalent immobilisation

of CalB and PGA on Sepabeads. Adv. Synth. Catal. 349: 877–886.

Betigeri, S. S. and S. H. Neau. 2002. Immobilization of lipase using hydrophilic polymers in the form of hydrogel

beads. Biomater. 51: 3627.

Bergna, H. E. and W. O. Roberts. 2006. Colloidal science in colloidal silica fundamentals and applications.

pp. 575–588. CRC Press: Boca Raton.

Boldridge, D. 2010. Morphological characterization of fumed silica aggregates. Aerosol. Sci. Technol. 44: 182.

Cahyaningrum, S. E., N. Herdyastusi and D. K. Maharani. 2014. Immobilization of glucose isomerase in surface-

modified chitosan gel beads. Res. J. Pharm. Biol. Chem. Sci. 5: 104.

Capulli, A. K., M. Y. Emmert, F. S. Pasqualini, D. Kehl, E. Caliskan, J. U. Lind, S. P. Sheehy, S. J. Park, S. Ahn, B.

Weber, J. A. Goss, S. P. Hoerstrup, K. K. Parker. 2017. JetValve: rapid manufacturing of biohybrid scaffolds

for biomimetic heart valve replacement. Biomaterials 133: 229–241.

Chen, L., J. Hu, Z. Fang, Y. Qi and R. Richards. 2011. Gold nanoparticles intercalated into the walls of mesoporous

silica as a versatile redox catalyst. Ind. Eng. Chem. Res. 50: 13642.

Chen, Xi, L. Mahadevan, A. Driks and O. Sahin. 2014. Bacillus spores as building blocks for stimuli-responsive

materials and nanogenerators. Nat. Nanotechnol. 9(2): 137.

Chang-Hyung., C., H. Wang, H. Lee, J. H. Kim, L. Zhang, A. Mao, D. J. Mooney and D. A. Weitz. 2016. One-step

generation of cell-laden microgels using double emulsion drops with a sacrificial ultra-thin oil shell. Lab Chip.

16(9): 1549.