Fabrication of Size-Controlled and Emulsion-Free Chitosan-Genipin Microgels for Tissue Engineering Applications

Michael A. Stager; Christopher B. Erickson; Karin A. Payne; Melissa D. Krebs

doi:10.3791/63857

조직 공학 응용 분야를 위한 크기 조절 및 무유제 키토산-제니핀 마이크로젤 제조

JoVE Journal
Bioengineering

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JoVE Journal Bioengineering

Fabrication of Size-Controlled and Emulsion-Free Chitosan-Genipin Microgels for Tissue Engineering Applications

조직 공학 응용 분야를 위한 크기 조절 및 무유제 키토산-제니핀 마이크로젤 제조

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05:26 min

April 13, 2022

DOI: 10.3791/63857-v

Michael A. Stager¹, Christopher B. Erickson², Karin A. Payne², Melissa D. Krebs¹

¹Department of Chemical and Biological Engineering,Colorado School of Mines, ²Department of Orthopedics,University of Colorado Anschutz Medical Campus

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Overview

This protocol describes a non-emulsion-based method for the fabrication of chitosan microgels that are biocompatible and suitable for tissue engineering applications. The microgels can be precisely controlled in size, exhibit pH-dependent swelling, and allow for sustained release of therapeutic molecules.

Key Study Components

Area of Science

Tissue Engineering
Biomaterials
Drug Delivery Systems

Background

Chitosan is a biodegradable polymer used in various biomedical applications.
Traditional methods for microgel fabrication often involve toxic solvents.
There is a need for biocompatible methods that are translatable to clinical settings.
This protocol aims to address these needs by providing a safer fabrication technique.

Purpose of Study

To develop a non-toxic method for creating chitosan microgels.
To enable the use of these microgels in tissue engineering and drug delivery.
To provide a protocol that is easy to implement without special equipment.

Methods Used

Preparation of a 6% weight-by-volume chitosan solution using acetic acid.
Fabrication of microgels without the use of toxic solvents or emulsion techniques.
Characterization of microgel properties such as size and swelling behavior.
Evaluation of drug loading and release profiles.

Main Results

The microgels can be fabricated with precise size control.
They exhibit pH-dependent swelling behavior.
Microgels degrade in vivo, making them suitable for biological applications.
Therapeutic molecules can be loaded and released in a sustained manner.

Conclusions

This method provides a biocompatible alternative for microgel fabrication.
Chitosan microgels have potential applications in regenerative medicine.
The technique can be adapted for various therapeutic uses.

Frequently Asked Questions

What are chitosan microgels?

Chitosan microgels are small, biodegradable particles made from chitosan that can be used for drug delivery and tissue engineering.

How does the fabrication method work?

The method involves mixing acetic acid with chitosan to create a solution that can be formed into microgels without toxic solvents.

What are the advantages of this method?

This method is non-toxic, does not require special equipment, and allows for precise control over microgel size.

Can these microgels be used in clinical settings?

Yes, the biocompatibility of the microgels makes them suitable for potential clinical applications.

What types of therapeutic molecules can be loaded?

Various therapeutic molecules can be loaded, including drugs for sustained release in tissue engineering applications.

Are there any limitations to this technique?

Further studies are needed to fully explore the range of applications and optimize the loading and release profiles of different therapeutic agents.

본 프로토콜은 키토산-제니핀 마이크로겔의 제조를 위한 비에멀젼 기반 방법을 기술한다. 이러한 마이크로겔의 크기는 정밀하게 조절할 수 있으며, pH 의존적 팽윤을 표시하고, 생체내에서 분해되며, 시간이 지남에 따라 지속적으로 방출되는 치료 분자로 로딩될 수 있어 조직 공학 응용에 매우 적합합니다.

이 프로토콜은 다양한 조직 공학 및 약물 전달 응용 분야에 사용할 수있는 독성 용매없이 키토산 마이크로 젤을 편리하게 제조 할 수 있습니다. 이 기술은 특별한 장비나 훈련이 필요하지 않으며 독성 에멀젼 기술이나 용매 헹굼이 필요하지 않으므로 생체 적합성이 높고 임상 환경으로 번역 할 수 있습니다. 우리는이 기술을 성장 플레이트 부상을 치료하기위한 생체 재료 전략으로 적용했습니다.

그러나 우리는이 기술이 다른 재생 의학 응용 분야에서도 유용 할 것이라고 믿습니다. 이 기술은 지속적인 약물 방출 가능성을 가진 주사 가능, 생분해성, 생체 재료 스캐폴드 시스템의 이점을 누릴 수있는 다른 재생 의학 응용 분야에 적용될 수 있습니다. 아세트산과 정제된 키토산을 10 밀리리터 루어락 주사기에 첨가하여 시작하여 6% 중량 부피 키토산 용액을 형성하였다.

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