Multilayer dual-porosity 3D printed scaffolds to recreate the anisotropic microenvironment of the hyaline cartilage

IF 10.2 1区医学 Q1 ENGINEERING, BIOMEDICAL

Materials Today Bio Pub Date : 2025-09-03 DOI:10.1016/j.mtbio.2025.102280

Sandra Ramos-Díez , Luis Diaz-Gomez , Maria Paulis , Sandra Camarero-Espinosa

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Abstract

Articular cartilage accounts for a multizonal structure with distinct matrix composition and chondrogenic phenotypes, responsible for the tissue's load-bearing ability. Upon damage, cartilage is clinically treated by microfracture, which allows bone marrow exudation to the previously abraded zone. However, mesenchymal stem cells (hMSC) of the marrow cannot differentiate into specific chondrogenic phenotypes and the resulting tissue is isotropic and non-functional. Here, we developed multilayer dual-porosity scaffolds with defined in-fiber and structural porosities that were able to steer hMSC's differentiation into specific chondrogenic phenotypes. A library of inks prepared from poly-(L)lactide-co-caprolactone and sacrificial gelatine microspheres of three different diameters (13 ± 8 μm, 24 ± 14 μm, and 47 ± 27 μm) were used to 3D print structures with different patterns (90°, 60° and 45°), giving rise to dual-porosity structures of tunable in-fiber and structural porosities. This pallet of structures allowed control over porosity, topography and mechanical properties (ranging from 3.1 ± 0.1 to 9.1 ± 1.8 kPa), which modulated cell adhesion, proliferation and differentiation. Multilayer scaffolds were fabricated from selected structures that promoted chondrogenic differentiation with distinct expression of collagen type I, type II (up to 9.9 fold-increase), aggrecan and versican genes, resulting on a tissue with characteristic collagen I and II deposition patterns, abundant glycosaminoglycan deposition (15.4 ± 2.0 μg _GAG · μg⁻¹ _DNA) and similar compression modulus to native cartilage (501.5 ± 72.7 kPa).

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多层双孔3D打印支架，重建透明软骨的各向异性微环境

关节软骨具有不同的基质组成和软骨表型的多区结构，负责组织的承重能力。软骨损伤后，临床采用微骨折治疗，使骨髓渗出到先前磨损的区域。然而，骨髓间充质干细胞（hMSC）不能分化为特定的软骨细胞表型，由此产生的组织是各向同性的，无功能。在这里，我们开发了多层双孔隙支架，具有明确的纤维内孔隙度和结构孔隙度，能够引导hMSC分化为特定的软骨表型。用三种不同直径（13±8 μm， 24±14 μm和47±27 μm）的聚(L)乳酸-co-己内酯和牺牲明胶微球制备的墨水库用于3D打印不同形状（90°，60°和45°）的结构，产生可调节的纤维内孔隙度和结构孔隙度的双重孔隙结构。这种托盘结构可以控制孔隙度、地形和机械性能（范围从3.1±0.1到9.1±1.8 kPa），从而调节细胞的粘附、增殖和分化。选择促进软骨分化的I型胶原、II型胶原（增加9.9倍）、聚集蛋白和versican基因表达的结构构建多层支架，形成具有典型的I型和II型胶原沉积模式、丰富的糖胺聚糖沉积（15.4±2.0 μg·μg−1 DNA）和与天然软骨相似的压缩模量（501.5±72.7 kPa）的组织。

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来源期刊

Materials Today Bio Multiple-

CiteScore

8.30

自引率

4.90%

发文量

303

审稿时长

30 days

期刊介绍： Materials Today Bio is a multidisciplinary journal that specializes in the intersection between biology and materials science, chemistry, physics, engineering, and medicine. It covers various aspects such as the design and assembly of new structures, their interaction with biological systems, functionalization, bioimaging, therapies, and diagnostics in healthcare. The journal aims to showcase the most significant advancements and discoveries in this field. As part of the Materials Today family, Materials Today Bio provides rigorous peer review, quick decision-making, and high visibility for authors. It is indexed in Scopus, PubMed Central, Emerging Sources, Citation Index (ESCI), and Directory of Open Access Journals (DOAJ).