Supragel-mediated efficient generation of pancreatic progenitor clusters and functional glucose-responsive islet-like clusters.

Although several synthetic hydrogels with defined stiffness have been developed to facilitate the proliferation and maintenance of human pluripotent stem cells (hPSCs), the influence of biochemical cues in lineage-specific differentiation and functional cluster formation has been rarely reported. Here, we present the application of Supragel, a supramolecular hydrogel formed by synthesized biotinylated peptides, for islet-like cluster differentiation. We observed that Supragel, with a peptide concentration of 5 mg/mL promoted spontaneous hPSCs formation into uniform clusters, which is mainly attributable to a supporting stiffness of ∼1.5 kPa as provided by the Supragel matrix. Supragel was also found to interact with the hPSCs and facilitate endodermal and subsequent insulin-secreting cell differentiation, partially through its components: the sequences of RGD and YIGSR that interacts with cell membrane molecules of integrin receptor. Compared to Matrigel and suspension culturing conditions, more efficient differentiation of the hPSCs was also observed at the stages 3 and 4, as well as the final stage toward generation of insulin-secreting cells. This could be explained by 1) suitable average size of the hPSCs clusters cultured on Supragel; 2) appropriate level of cell adhesive sites provided by Supragel during differentiation. It is worth noting that the Supragel culture system was more tolerance in terms of the initial seeding densities and less demanding, since a standard static cell culture condition was sufficient for the entire differentiation process. Our observations demonstrate a positive role of Supragel for hPSCs differentiation into islet-like cells, with additional potential in facilitating germ layer differentiation.

Versatile Design of NO-Generating Proteolipid Nanovesicles for Alleviating Vascular Injury.

Vascular injury is central to the pathogenesis and progression of cardiovascular diseases, however, fostering alternative strategies to alleviate vascular injury remains a persisting challenge. Given the central role of cell-derived nitric oxide (NO) in modulating the endogenous repair of vascular injury, NO-generating proteolipid nanovesicles (PLV-NO) are designed that recapitulate the cell-mimicking functions for vascular repair and replacement. Specifically, the proteolipid nanovesicles (PLV) are versatilely fabricated using membrane proteins derived from different types of cells, followed by the incorporation of NO-generating nanozymes capable of catalyzing endogenous donors to produce NO. Taking two vascular injury models, two types of PLV-NO are tailored to meet the individual requirements of targeted diseases using platelet membrane proteins and endothelial membrane proteins, respectively. The platelet-based PLV-NO (pPLV-NO) demonstrates its efficacy in targeted repair of a vascular endothelium injury model through systemic delivery. On the other hand, the endothelial cell (EC)-based PLV-NO (ePLV-NO) exhibits suppression of thrombosis when modified onto a locally transplanted small-diameter vascular graft (SDVG). The versatile design of PLV-NO may enable a promising therapeutic option for various vascular injury-evoked cardiovascular diseases.

Prenatal prednisone exposure disturbs fetal kidney development and its characteristics.

Prednisone is a synthetic glucocorticoid that is commonly used in both human and veterinary medication. Now, it is also recognized as an emerging environmental contaminant. Pregnant women may be exposed to prednisone actively or passively through multiple pathways and cause developmental toxicity to the fetus. However, the impact of prenatal prednisone exposure (PPE) on fetal kidney development remains unclear. In this study, pregnant mice were administered prednisone intragastrically during full-term pregnancy with different doses (0.25, 0.5, or 1 mg/(kg·day)), or at the dose of 1 mg/(kg·day) in different gestational days (GD) (GD0-9, GD10-18, or GD0-18). The pregnant mice were euthanized on GD18. HE staining revealed fetal kidney dysplasia, with an enlarged glomerular Bowman's capsule space and a reduced capillary network in the PPE groups. The expression of the podocyte and the mesangial cell marker genes was significantly reduced in the PPE groups. However, overall gene expression in renal tubules and collecting ducts were markedly increased. All of the above effects were more pronounced in high-dose, full-term pregnancy, and female fetuses. Studies on the mechanism of the female fetal kidney have revealed that PPE reduced the expression of Six2, increased the expression of Hnf1ß, Hnf4α, and Wnt9b, and inhibited the expression of glial cell line-derived neurotrophic factor (GDNF) and Notch signaling pathways. In conclusion, this study demonstrated that there is a sex difference in the developmental toxicity of PPE to the fetal kidney, and the time effect is manifested as full-term pregnancy > early pregnancy > mid-late pregnancy.

Functionalization of in vivo tissue-engineered living biotubes enhance patency and endothelization without the requirement of systemic anticoagulant administration.

Vascular regeneration and patency maintenance, without anticoagulant administration, represent key developmental trends to enhance small-diameter vascular grafts (SDVG) performance. In vivo engineered autologous biotubes have emerged as SDVG candidates with pro-regenerative properties. However, mechanical failure coupled with thrombus formation hinder translational prospects of biotubes as SDVGs. Previously fabricated poly(ε-caprolactone) skeleton-reinforced biotubes (PBs) circumvented mechanical issues and achieved vascular regeneration, but orally administered anticoagulants were required. Here, highly efficient and biocompatible functional modifications were introduced to living cells on PB lumens. The 1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine-N-methoxy (DMPE)-PEG-conjugated anti-coagulant bivalirudin (DPB) and DMPE-PEG-conjugated endothelial progenitor cell (EPC)-binding TPS-peptide (DPT) modifications possessed functionality conducive to promoting vascular graft patency. Co-modification of DPB and DPT swiftly attained luminal saturation without influencing cell viability. DPB repellent of non-specific proteins, DPB inhibition of thrombus formation, and DPB protection against functional masking of DPT's EPC-capture by blood components, which promoted patency and rapid endothelialization in rat and canine artery implantation models without anticoagulant administration. This strategy offers a safe, facile, and fast technical approach to convey additional functionalization to living cells within tissue-engineered constructs.

Exposure to melamine cyanuric acid in adult mice induced thyroid dysfunction and circadian rhythm disorder.

MCA is a halogen-free flame retardant. It can cause damage to other tissues such as the kidneys and liver. However, the effects on the circadian rhythm and thyroid in adult mice have not been studied. In this article, adult male mice received MCA at concentrations of 0, 10, 20, 30 mg/kg. The results showed that the time spending on wheel-running and rest bouts changed in different period after MCA exposure. MCA disrupted the T3 and T4 hormone homeostasis and decreased the expression of thyroid hormone synthesis genes. The histological morphology of the thyroid gland was damaged. It was suggested that MCA exposure caused circadian rhythm disorder and thyroid dysfunction.