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Poster
P 38

Gelatin microparticles cross-linked with second generation anhydride-containing amphiphilic oligomers – cross-linking characteristics by confocal Raman microscopy

Appointment

Date: 14/09/2023

Time: 18:45 – 18:45

Talk time: 0 Min.

Discussion time: 0 Min.

Location / Stream:

Foyer

Session

Poster Exhibition

Topics

Biofabrication
Tissue regeneration/regenerated medicine

Authors

Burak Demir (Düsseldorf, DE), Dr. Björn Fischer (Düsseldorf, DE), Julia C. Matros (Düsseldorf, DE), Prof. Dr. Michael C. Hacker (Düsseldorf, DE)

Abstract

Abstract text (incl. figure legends and references)

Introduction: Gelatin-based microparticles (GM) are versatile biomaterials that can serve as enzymatically degradable templates for microtissue assembly and drug delivery [1]. This study explores using second-generation anhydride-containing oligomers as cross-linkers for fabrication of cross-linked GM (cGM). We aim to assess cross-linking density and intraparticle cross-linking characteristics.

Materials and Methods: We adopted a two-step strategy to fabricate oligomer-cross-linked cGM [2]. Initially, GMs (gelatin type A, 300 Bloom) were fabricated using a surfactant-free water-in-oil emulsion method. Subsequently, post-fabrication chemical cross-linking of GM was performed with self-synthesized anhydride-containing oligomers with different anhydride contents. The comonomers constituting these oligomers are stearyl acrylate, acryloyl morpholine, and maleic anhydride. Laser diffractometry was used to analyze cGM size distribution. A trinitrobenzene sulfonic acid assay was used for analyzing degree of cross-linking (DoC), while confocal Raman microscopy (CRM) of individual GM served to extract spectral data and assess cross-linking characteristics.

Results: Particle size and cross-linking density was controlled by the fabrication protocol. We obtained cGM batches with a median size (Dx50) in a size and DoC range of 45-60 μm and 30-60%, respectively. A correlation between higher DoC and increased oligomer concentration or anhydride content was noted. CRM revealed cross-linking by distinct spectral changes, and distinct spectral changes correlated with higher DoC. CRM data from individual cGM suggested cross-linking through the cross-section of the particle.

Conclusion: This study demonstrates effective cGM fabrication using our second- generation oligomers with varying anhydride contents. Intraparticle cross-linking was determined by CRM.

References:

1. Hinkelmann S, et al. MaterialsTodayBio. 2022;13:100190

2. Loth T, et al. Biomacromolecules. 2014;15:2104-2118