Synthesis of silica vesicles with controlled entrance size for high loading, sustained release, and cellular delivery of therapeutical proteins

Jun Zhang; Surajit Karmakar; Meihua Yu; Neena Mitter; Jin Zou; Chengzhong Yu

doi:10.1002/smll.201401538

Synthesis of silica vesicles with controlled entrance size for high loading, sustained release, and cellular delivery of therapeutical proteins

Jun Zhang
, Surajit Karmakar
, Meihua Yu
, Neena Mitter
, Jin Zou
, Chengzhong Yu^*

^*Corresponding author for this work

University of Queensland

Research output: Contribution to journal › Article › peer-review

54 Scopus citations

Abstract

A rationally designed two-step synthesis of silica vesicles is developed with the formation of vesicular structure in the first step and fine control over the entrance size by tuning the temperature in the second step. The silica vesicles have a uniform size of ≈50 nm with excellent cellular uptake performance. When the entrance size is equal to the wall thickness, silica vesicles after hydrophobic modification show the highest loading amount (563 mg/g) towards Ribonuclease A with a sustained release behavior. Consequently, the silica vesicles are excellent nano-carriers for cellular delivery applications of therapeutical biomolecules.

Original language	English
Pages (from-to)	5068-5076
Number of pages	9
Journal	Small
Volume	10
Issue number	24
DOIs	https://doi.org/10.1002/smll.201401538
State	Published - 29 Dec 2014
Externally published	Yes

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10.1002/smll.201401538

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title = "Synthesis of silica vesicles with controlled entrance size for high loading, sustained release, and cellular delivery of therapeutical proteins",

abstract = "A rationally designed two-step synthesis of silica vesicles is developed with the formation of vesicular structure in the first step and fine control over the entrance size by tuning the temperature in the second step. The silica vesicles have a uniform size of ≈50 nm with excellent cellular uptake performance. When the entrance size is equal to the wall thickness, silica vesicles after hydrophobic modification show the highest loading amount (563 mg/g) towards Ribonuclease A with a sustained release behavior. Consequently, the silica vesicles are excellent nano-carriers for cellular delivery applications of therapeutical biomolecules.",

author = "Jun Zhang and Surajit Karmakar and Meihua Yu and Neena Mitter and Jin Zou and Chengzhong Yu",

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AU - Zhang, Jun

AU - Karmakar, Surajit

AU - Yu, Meihua

AU - Mitter, Neena

AU - Zou, Jin

AU - Yu, Chengzhong

PY - 2014/12/29

Y1 - 2014/12/29

N2 - A rationally designed two-step synthesis of silica vesicles is developed with the formation of vesicular structure in the first step and fine control over the entrance size by tuning the temperature in the second step. The silica vesicles have a uniform size of ≈50 nm with excellent cellular uptake performance. When the entrance size is equal to the wall thickness, silica vesicles after hydrophobic modification show the highest loading amount (563 mg/g) towards Ribonuclease A with a sustained release behavior. Consequently, the silica vesicles are excellent nano-carriers for cellular delivery applications of therapeutical biomolecules.

AB - A rationally designed two-step synthesis of silica vesicles is developed with the formation of vesicular structure in the first step and fine control over the entrance size by tuning the temperature in the second step. The silica vesicles have a uniform size of ≈50 nm with excellent cellular uptake performance. When the entrance size is equal to the wall thickness, silica vesicles after hydrophobic modification show the highest loading amount (563 mg/g) towards Ribonuclease A with a sustained release behavior. Consequently, the silica vesicles are excellent nano-carriers for cellular delivery applications of therapeutical biomolecules.

UR - https://www.scopus.com/pages/publications/84919715000

U2 - 10.1002/smll.201401538

DO - 10.1002/smll.201401538

M3 - 文章

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AN - SCOPUS:84919715000

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SP - 5068

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JO - Small

JF - Small

IS - 24

ER -

Synthesis of silica vesicles with controlled entrance size for high loading, sustained release, and cellular delivery of therapeutical proteins

Abstract

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