Biomimetic silk nanoparticle manufacture: calcium ion-mediated assembly

Napaporn Roamcharern; Saphia A. L. Matthew; Daniel J. Brady; John A. Parkinson; Zahra Rattray; F. Philipp Seib

doi:10.1021/acsbiomaterials.4c02175

Biomimetic silk nanoparticle manufacture: calcium ion-mediated assembly

Napaporn Roamcharern, Saphia A. L. Matthew, Daniel J. Brady, John A. Parkinson, Zahra Rattray^*, F. Philipp Seib^*

^*Corresponding author for this work

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Abstract

Silk has emerged as an interesting candidate among protein-based nanocarriers due to its favorable properties, including biocompatibility and a broad spectrum of processing options to tune particle critical quality attributes. The silk protein conformation during storage in the middle silk gland of the silkworm is modulated by various factors, including the most abundant metallic ion, calcium ion (Ca2+). Here, we report spiking of liquid silk with calcium ions to modulate the silk nanoparticle size. Conformational and structural analyses of silk demonstrated Ca2+-induced silk assemblies that resulted in a liquid crystalline-like state, with the subsequent generation of β-sheet-enriched silk nanoparticles. Thioflavin T studies demonstrated that Ca2+ effectively induces self-assembly and conformation changes that also increased model drug loading. Ca2+ incorporation in the biopolymer feed significantly increased the nanoparticle production yield from 16 to 89%, while simultaneously enabling Ca2+ concentration-dependent particle-size tuning with a narrow polydispersity index and altered zeta potential. The resulting silk nanoparticles displayed high biocompatibility in macrophages with baseline levels of cytotoxicity and cellular inflammation. Our strategy for manufacturing biomimetic silk nanoparticles enabled overall tuning of particle size and improved yields-features that are critical for 16 particle-based nanomedicines.

Original language	English
Pages (from-to)	1847–1856
Number of pages	10
Journal	ACS Biomaterials Science & Engineering
Volume	11
Issue number	3
Early online date	30 Jan 2025
DOIs	https://doi.org/10.1021/acsbiomaterials.4c02175
Publication status	Published - 10 Mar 2025

Funding

N.R. acknowledges funding from the Office of Educational Affairs, UK, and the Royal Thai Embassy, Thailand, and Office of the Civil Service Commission, Thailand, who provided a PhD scholarship. Z.R. and F.P.S. acknowledge funding from the Engineering and Physical Sciences Research Council (EP/V028960/1). J.A.P. and F.P.S. acknowledge funding from the Biotechnology and Biological Sciences Research Council (BB/X019594/1). D.J.B. acknowledges that this project has received funding from the European Union\u2019s Horizon Europe research and innovation programme under the Marie Sk\u0142odowska-Curie grant agreement no. 101148220 (GEMSilk). F.P.S. acknowledges support from a DFG Heisenberg grant (SE 3307/1-1), and funding from the Free State of Thuringia and European Fonds for Regional Development (EFRE) with grant no. 2024FGI0005. This work was supported by the Fraunhofer Internal Programs under Grant No. Attract 40-04900. F.P.S. holds the endowed CZS Professorship for Pharmaceutical Technology and Biopharmaceutics funded by the Carl-Zeiss-Stiftung. The authors acknowledge that the scanning electron microscopy work was carried out at the Advanced Materials Research Laboratory, housed within the University of Strathclyde.

Keywords

Bombyx mori
silk fibroin
antisolvent precipitation
desolvation
metal ion
nanomedicine

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1021/acsbiomaterials.4c02175Licence: CC BY 4.0

Roamcharern-etal-ACS-BSE-2025-Biomimetic-silk-nanoparticle-manufactureFinal published version, 4.25 MBLicence: CC BY 4.0

Data for: "Biomimetic Silk Nanoparticle Manufacture: Calcium Ion-Mediated Assembly "
ROAMCHARERN, N. (Creator) & Rattray, Z. (Supervisor), University of Strathclyde, 21 Jan 2025
DOI: 10.15129/88da6654-2b38-432f-b5c1-7693ca101645
Dataset

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title = "Biomimetic silk nanoparticle manufacture: calcium ion-mediated assembly",

abstract = "Silk has emerged as an interesting candidate among protein-based nanocarriers due to its favorable properties, including biocompatibility and a broad spectrum of processing options to tune particle critical quality attributes. The silk protein conformation during storage in the middle silk gland of the silkworm is modulated by various factors, including the most abundant metallic ion, calcium ion (Ca2+). Here, we report spiking of liquid silk with calcium ions to modulate the silk nanoparticle size. Conformational and structural analyses of silk demonstrated Ca2+-induced silk assemblies that resulted in a liquid crystalline-like state, with the subsequent generation of β-sheet-enriched silk nanoparticles. Thioflavin T studies demonstrated that Ca2+ effectively induces self-assembly and conformation changes that also increased model drug loading. Ca2+ incorporation in the biopolymer feed significantly increased the nanoparticle production yield from 16 to 89%, while simultaneously enabling Ca2+ concentration-dependent particle-size tuning with a narrow polydispersity index and altered zeta potential. The resulting silk nanoparticles displayed high biocompatibility in macrophages with baseline levels of cytotoxicity and cellular inflammation. Our strategy for manufacturing biomimetic silk nanoparticles enabled overall tuning of particle size and improved yields-features that are critical for 16 particle-based nanomedicines.",

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AU - Roamcharern, Napaporn

AU - Matthew, Saphia A. L.

AU - Brady, Daniel J.

AU - Parkinson, John A.

AU - Rattray, Zahra

AU - Seib, F. Philipp

PY - 2025/3/10

Y1 - 2025/3/10

N2 - Silk has emerged as an interesting candidate among protein-based nanocarriers due to its favorable properties, including biocompatibility and a broad spectrum of processing options to tune particle critical quality attributes. The silk protein conformation during storage in the middle silk gland of the silkworm is modulated by various factors, including the most abundant metallic ion, calcium ion (Ca2+). Here, we report spiking of liquid silk with calcium ions to modulate the silk nanoparticle size. Conformational and structural analyses of silk demonstrated Ca2+-induced silk assemblies that resulted in a liquid crystalline-like state, with the subsequent generation of β-sheet-enriched silk nanoparticles. Thioflavin T studies demonstrated that Ca2+ effectively induces self-assembly and conformation changes that also increased model drug loading. Ca2+ incorporation in the biopolymer feed significantly increased the nanoparticle production yield from 16 to 89%, while simultaneously enabling Ca2+ concentration-dependent particle-size tuning with a narrow polydispersity index and altered zeta potential. The resulting silk nanoparticles displayed high biocompatibility in macrophages with baseline levels of cytotoxicity and cellular inflammation. Our strategy for manufacturing biomimetic silk nanoparticles enabled overall tuning of particle size and improved yields-features that are critical for 16 particle-based nanomedicines.

AB - Silk has emerged as an interesting candidate among protein-based nanocarriers due to its favorable properties, including biocompatibility and a broad spectrum of processing options to tune particle critical quality attributes. The silk protein conformation during storage in the middle silk gland of the silkworm is modulated by various factors, including the most abundant metallic ion, calcium ion (Ca2+). Here, we report spiking of liquid silk with calcium ions to modulate the silk nanoparticle size. Conformational and structural analyses of silk demonstrated Ca2+-induced silk assemblies that resulted in a liquid crystalline-like state, with the subsequent generation of β-sheet-enriched silk nanoparticles. Thioflavin T studies demonstrated that Ca2+ effectively induces self-assembly and conformation changes that also increased model drug loading. Ca2+ incorporation in the biopolymer feed significantly increased the nanoparticle production yield from 16 to 89%, while simultaneously enabling Ca2+ concentration-dependent particle-size tuning with a narrow polydispersity index and altered zeta potential. The resulting silk nanoparticles displayed high biocompatibility in macrophages with baseline levels of cytotoxicity and cellular inflammation. Our strategy for manufacturing biomimetic silk nanoparticles enabled overall tuning of particle size and improved yields-features that are critical for 16 particle-based nanomedicines.

KW - Bombyx mori

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KW - antisolvent precipitation

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KW - metal ion

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DO - 10.1021/acsbiomaterials.4c02175

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Biomimetic silk nanoparticle manufacture: calcium ion-mediated assembly

Abstract

Funding

Keywords

UN SDGs

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Data for: "Biomimetic Silk Nanoparticle Manufacture: Calcium Ion-Mediated Assembly "

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