AI Article Synopsis
- Cellular alignment is crucial for the function of various human tissues, and traditional 3D scaffolds for this purpose often require invasive surgical implantation.
- Researchers developed a novel injectable hydrogel that incorporates magnetic nanoparticles, allowing for precise control of the hydrogel's structure using a low-intensity magnetic field.
- The hydrogel demonstrated mechanical properties similar to soft human tissues and promoted cell growth while being safe and biocompatible, highlighting its potential for non-invasive treatment options in tissue regeneration.
Article Abstract
Cellular alignment plays a pivotal role in several human tissues, including skeletal muscle, spinal cord and tendon. Various techniques have been developed to control cellular alignment using 3D biomaterials. However, the majority of 3D-aligned scaffolds require invasive surgery for implantation. In contrast, injectable hydrogels provide a non-invasive delivery method, gaining considerable attention for the treatment of diverse conditions, including osteochondral lesions, volumetric muscle loss, and traumatic brain injury. We engineered a biomimetic hydrogel with magnetic responsiveness by combining gellan gum, hyaluronic acid, collagen, and magnetic nanoparticles (MNPs). Collagen type I was paired with MNPs to form magnetic collagen bundles (MCollB), allowing the orientation control of these bundles within the hydrogel matrix through the application of a remote low-intensity magnetic field. This resulted in the creation of an anisotropic architecture. The hydrogel mechanical properties were comparable to those of human soft tissues, such as skeletal muscle, and proof of the aligned hydrogel concept was demonstrated. findings confirmed the absence of toxicity and pro-inflammatory effects. Notably, an increased fibroblast cell proliferation and pro-regenerative activation of macrophages were observed. The study further validated the hydrogel biocompatibility and demonstrated the feasibility of injection with rapid gelation. Consequently, this magnetically controlled injectable hydrogel exhibits significant promise as a minimally invasive, rapid gelling and effective treatment for regenerating various aligned human tissues.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11360152 | PMC |
| http://dx.doi.org/10.1016/j.mtbio.2024.101110 | DOI Listing |
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