Synthesis of Thermogelling Poly(N-isopropylacrylamide)-graft-chondroitin Sulfate Composites with Alginate Microparticles for Tissue Engineering

Thomas R. Christiani; Katelynn Toomer; Joseph Sheehan; Angelika Nitzl; Amanda Branda; Elizabeth England; Pamela Graney; Cristina Iftode; Andrea J. Vernengo

doi:10.3791/53704

조직 공학 알긴산 미세 입자와 Thermogelling 폴리 (N- 이소 프로필) -graft - 콘드로이틴 황산 복합 재...

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JoVE Journal Bioengineering

Synthesis of Thermogelling Poly(N-isopropylacrylamide)-graft-chondroitin Sulfate Composites with Alginate Microparticles for Tissue Engineering

조직 공학 알긴산 미세 입자와 Thermogelling 폴리 (N- 이소 프로필) -graft - 콘드로이틴 황산 복합 재료의 합성

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12:22 min

October 26, 2016

DOI: 10.3791/53704-v

Thomas R. Christiani¹, Katelynn Toomer², Joseph Sheehan², Angelika Nitzl², Amanda Branda², Elizabeth England², Pamela Graney³, Cristina Iftode², Andrea J. Vernengo¹

¹Department of Chemical Engineering,Rowan University, ²Department of Biological Sciences,Rowan University, ³Department of Biomedical Engineering,Drexel University

Please note that some of the translations on this page are AI generated. Click here for the English version.

Overview

This study presents an injectable tissue engineering scaffold made from a poly(N-isopropylacrylamide)-graft-chondroitin sulfate (PNIPAAm-g-CS)-containing alginate microparticle composite. The research focuses on evaluating the adhesive strength, swelling properties, and in vitro biocompatibility of this novel hydrogel.

Key Study Components

Area of Science

Tissue Engineering
Biomaterials
Hydrogels

Background

Thermal reversible hydrogels are crucial for cell encapsulation in tissue engineering.
Understanding adhesive properties is essential for developing effective scaffolds.
In vitro studies are necessary to assess the biocompatibility of new materials.
This research aims to contribute to the field of intervertebral disc tissue engineering.

Purpose of Study

To assess the adhesive properties of a hydrogel composite for nucleus pulposus tissue engineering.
To evaluate cellular biocompatibility of the proposed hydrogel.
To demonstrate the potential of injectable, thermally-sensitive composites.

Methods Used

Tensile mechanical tests to evaluate adhesive strength.
Cellular viability assays to assess biocompatibility.
Synthesis of bioadhesive hydrogel from purified NIPAAm monomer and mCS.
In vitro studies to demonstrate the hydrogel's effectiveness.

Main Results

The hydrogel demonstrated favorable adhesive properties.
In vitro studies indicated good cellular viability.
The composite showed potential as a replacement for the nucleus pulposus.
Characterization techniques may be applicable to other thermogelling systems.

Conclusions

The PNIPAAm-g-CS hydrogel scaffold is promising for tissue engineering applications.
Further studies are needed to explore its long-term biocompatibility.
This research provides a foundation for future developments in injectable hydrogels.

Frequently Asked Questions

What is the main application of the hydrogel scaffold?

The hydrogel scaffold is designed for intervertebral disc tissue engineering, specifically for the nucleus pulposus.

How does the hydrogel's adhesive property benefit tissue engineering?

The adhesive property allows the hydrogel to effectively bond with surrounding tissues, enhancing integration and functionality.

What methods were used to assess biocompatibility?

Cellular viability assays were conducted to evaluate the biocompatibility of the hydrogel scaffold.

What are the advantages of using thermally-sensitive hydrogels?

Thermally-sensitive hydrogels can be injected in a liquid form and gel upon reaching body temperature, allowing for minimally invasive applications.

Who conducted the biocompatibility assays in the study?

The biocompatibility assays were conducted by students from the departments of Biological Sciences and Biochemistry.

What are the next steps for this research?

Future research will focus on long-term biocompatibility and potential clinical applications of the hydrogel scaffold.

폴리 (N- 이소 프로필 아크릴 아미드) - -graft 콘드로이틴 설페이트 이루어지는 주사 조직 공학적 지지체는 (PNIPAAm-g-CS) 함유 알긴산 미립자를 제조 하였다. 속성 및 생체 적합성 시험 관내에서 팽윤 접착력은 본 연구에서 분석된다. 여기서 개발 된 특성화 기술 thermogelling 다른 시스템들에 적용 할 수있다.

이 방법론의 전반적인 목표는 pulposus 핵의 추간판 조직 공학을 위해 제안된 하이드로겔 복합체의 접착 특성과 세포 생체 적합성을 모두 평가하는 것입니다. 이 방법은 세포 캡슐화를 위한 생체 접착 특성을 가진 열 가역성 하이드로겔을 설계하고 준비하는 방법과 같은 조직 공학 분야의 주요 질문에 답하는 데 도움이 될 수 있습니다. 이 기술의 주요 장점은 주사 가능하고 열에 민감한 복합체를 사용한 체외 연구를 시연하여 pulposus핵의 잠재적 대체품으로서의 사용을 평가할 수

이 현재 연구에서는 인장 기계적 테스트와 세포 생존율 분석을 모두 수행하여 새로운 하이드로겔 스캐폴드를 평가합니다. 생체 적합성 분석을 시연하는 사람은 생물 과학 및 생화학과 학생인 Emily Schmidt, Mark Dittmer, Edward Goldschmidt 및 Frantzeska Giginis입니다. 생체 접착성 하이드로겔을 합성하기 전에 텍스트 프로토콜에 설명된 대로 NIPAAm 단량체 및 mCS를 정제합니다.

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