Injectable, cryopreservable mesenchymal stromal cell-loaded microbeads for pro-angiogenic therapy:proof-of-concept.

Despite their recognized potential for ischemic tissue repair, the clinical use of human mesenchymal stromal cells (hMSC) is limited by the poor viability of cells after injection and the variability of their paracrine function. In this study, we show how the choice of biomaterial scaffolds and the addition of cell preconditioning treatment can address these limitations and establish a proof-of-concept for cryopreservable hMSC-loaded microbeads. Injectable microbeads in chitosan, chitosan-gelatin, and alginate were produced using stirred emulsification to obtain a similar volume moment mean diameter (D[4,3] ∼ 500 µm).

Injectable chitosan hydrogel effectively controls lesion growth in a venous malformation murine model.

Purpose: The purpose of this study was to evaluate the safety and efficacy of intralesional injection of chitosan hydrogel (CH) combined with sodium tetradecyl sulfate (STS) to sclerose and embolize venous malformations (VMs) by comparison with 3% STS foam and placebo in a mouse model.

Materials And Methods: Subcutaneous VMs were created by injecting HUVEC_TIE2-L914F cells, mixed with matrigel, into the back of athymic mice (Day [D] 0). After VM-like lesions were established at D10, 70 lesions were randomly assigned to one of six treatment groups (untreated, saline, 3% STS-foam, CH, 1% STS-CH, 3% STS-CH).

How to Design Catechol-Containing Hydrogels for Cell Encapsulation Despite Catechol Toxicity.

Catechol (cat) is a highly adhesive diphenol that can be chemically grafted to polymers such as chitosan (CH) to make them adhesive as well. However, catechol-containing materials experimentally show a large variability of toxicity, especially in vitro. While it is unclear how this toxicity emerges, most concerns are directed toward the oxidation of catechol into quinone that releases reactive oxygen species (ROS) which can, in turn, cause cell apoptosis through oxidative stress.

T cell-loaded injectable chitosan scaffold shows short-term efficacy in localised cancer immunotherapy in mice.

Adoptive cell therapy (ACT) shows success against treatment-resistant cancers, but is limited by the large number of intravenously delivered T cells required and toxicity related to systemic administration. In this work, we hypothesized that localized T cell delivery in an gelling chitosan hydrogel will allow similar treatment efficacy despite delivering fewer cells than systemic intravenous delivery. A rapidly gelling chitosan gel with good mechanical properties was used for this study.