An overview of additive manufacturing strategies of enzyme-immobilized nanomaterials with application incatalysis and biomedicine.

Sood, A.; Das, S.S.; Singhmar, R.; Sahoo, S.; Wahajuddin; Naseem, Zaiba; Choi, S.; Kumar, A.; Han, S.S.

Publication

An overview of additive manufacturing strategies of enzyme-immobilized nanomaterials with application incatalysis and biomedicine.

Sood, A.
;
Das, S.S.
;
Singhmar, R.
;
Sahoo, S.
;
Wahajuddin
;
Naseem, Zaiba
;
Choi, S.
;
Kumar, A.
;
Han, S.S.

Publication Date

2024-12-28

Keywords

Nanobiocomposites, Additive manufacturing, Enzymes, Enzyme immobilized nanomaterials, 3D printing

Peer-Reviewed

Yes

Open Access status

restrictedAccess

Accepted for publication

2024-12-23

Collections

Life Sciences Publications

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Abstract

Meticulous and bespoke fabrication of structural materials with simple yet innovative outlines along with on-demand availability is the imperative aspiration for numerous fields. The alliance between nanotechnology and enzymes has led to the establishment of an inimitable and proficient class of materials. With the advancement in the field of additive manufacturing, the fabrication of some complex biological architects is achievable with similitude to the instinctive microenvironment of the biological tissue. Rendering these enzymes-linked nanomaterials through 3D printing for biosensing, catalytic, and biomedical applications is challenging due to the need for a precise controlled, regulated system with scaleup capability for commercialization. The current review highlights the importance of nanomaterials as a persuasive matrix for enzyme immobilization along with the key parameters that regulate the rate of immobilization and the activity of the concerned enzyme. Precise attention has been devoted to the different strategies for immobilizing enzymes in the nanomaterial's matrix. The present review offers a comprehensive discussion on the utility of 3D printing technology for enzyme-immobilized nanomaterials in biosensing, catalysis, and biomedical applications. The employment of 3D printing grants new developments and avenues in the vast field of enzyme- immobilized nanomaterials.

URI

https://bradscholars.brad.ac.uk/handle/10454/20502

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Citation

Sood A, Das SS, Singhmar R, et al (2024) An overview of additive manufacturing strategies of enzyme-immobilized nanomaterials with application incatalysis and biomedicine. International Journal of Biological Macromolecules. 292: 139174.

Link to Version of Record

https://doi.org/10.1016/j.ijbiomac.2024.139174

Type

Article

An overview of additive manufacturing strategies of enzyme-immobilized nanomaterials with application incatalysis and biomedicine.

Sood, A.
;
Das, S.S.
;
Singhmar, R.
;
Sahoo, S.
;
Wahajuddin
;
Naseem, Zaiba
;
Choi, S.
;
Kumar, A.
;
Han, S.S.

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Accepted for publication

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An overview of additive manufacturing strategies of enzyme-immobilized nanomaterials with application incatalysis and biomedicine.

Sood, A. ; Das, S.S. ; Singhmar, R. ; Sahoo, S. ; Wahajuddin; Naseem, Zaiba ; Choi, S. ; Kumar, A. ; Han, S.S.

Publication Date

End of Embargo

Supervisor

Keywords

Rights

Peer-Reviewed

Open Access status

Accepted for publication

Institution

Department

Awarded

Embargo end date

Collections

Additional title

Abstract

URI

Version

Citation

Link to publisher’s version

Link to published version

Link to Version of Record

Type

Qualification name

Notes

Sood, A.
;
Das, S.S.
;
Singhmar, R.
;
Sahoo, S.
;
Wahajuddin
;
Naseem, Zaiba
;
Choi, S.
;
Kumar, A.
;
Han, S.S.