Exploiting Extracellular Vesicles Strategies to Modulate Cell Death and Inflammation in COVID-19

The coronavirus disease (COVID-19) is responsible for more than 5 million deaths worldwide, with respiratory failure being the most common clinical presentation. COVID-19 complications still present a considerable burden on healthcare systems, and signs of the post-COVID syndrome are concerns for potential long-term damages. An increasing body of evidence highlights extracellular vesicles' (EVs) relevance in modulating inflammation and cell death in the diseases related to these processes. Several types of EVs-based investigational new drugs against COVID-19 have been approved by the US Food and Drug Administration to initiate a Phase I/II trial under an Investigational New Drug protocol. EVs can be employed as natural drug delivery nanoparticle-based systems due to their inherent potential in transferring material between cells, their natural origin, and their capability to encapsulate various biological molecules, offering an exciting alternative for administering drugs acting on the cell cycle control. In this context, small-molecule inhibitors of Mouse Double Minute 2 (MDM2) such as Nutlin-3 and Idasanutlin by promoting p53 survival and its antiviral activity might be helpful to modulate the IFN signalling pathway and reduce the overall pro-inflammatory burden

A new tool for investigation platelet activation in endometriosis patients

Objectives: Endometriosis (EM) is a gynecological disease characterized by chronic inflammation, due to the interaction of inflammatory cells with ectopic endometrium (1). Platelets (PLTs), recruited by procoagulant factors released from endometriotic stromal cells, secrete angiogenetic factors and induce overexpression of genes involved in pro-survival/ anti-apoptotic propensity, inflammationand extracellular matrix remodeling (2). We aimed to develop a tool to measure PLT activation (by small extracellular vesicles, s-EVs) in EM peritoneal fluids, as a potential predictive marker of EM severity. Materials & methods: S-EVs were isolated from EM peritoneal fluids and characterized with imaging (Atomic Force Microscopy; AFM) and protein expression analyses (Western blot, WB) (3). We explored gene expression in peritoneum and EM lesions using EndometDB (4). Results: We demonstrated the presence of s-EVs isolated from EM peritoneal fluids by liquid AFM, as showed by contact angle vs diameter scatterplot (Fig.1A-B), and by WB detecting the s-EV markers CD63, CD9, and TSG101 (Fig.1C). Using Endomet-DB, we highlighted the differentially expressed genes between control and EM peritoneum samples (Fig.1D). The protein expression of a panel of biomarkers of PTL in s-EVs was further confirmed by WB (Fig.1E). Conclusions: We propose applying s-EV research to EM investigation, generating a novel biochemical tool for PLT activation assessment and for the development of new diagnostics and therapies

Genetic profiling of autoinflammatory disorders in patients with periodic fever: a prospective study

Periodic fever syndromes (PFS) are an emerging group of autoinflammatory disorders. Clinical overlap exists and multiple genetic analyses may be needed to assist diagnosis. We evaluated the diagnostic value of a 5-gene sequencing panel (5GP) in patients with undiagnosed PFS

Image-guided cancer surgery: a narrative review on imaging modalities and emerging nanotechnology strategies

Abstract Surgical resection is the cornerstone of solid tumour treatment. Current techniques for evaluating margin statuses, such as frozen section, imprint cytology, and intraoperative ultrasound, are helpful. However, an intraoperative assessment of tumour margins that is accurate and safe is clinically necessary. Positive surgical margins (PSM) have a well-documented negative effect on treatment outcomes and survival. As a result, surgical tumour imaging methods are now a practical method for reducing PSM rates and improving the efficiency of debulking surgery. Because of their unique characteristics, nanoparticles can function as contrast agents in image-guided surgery. While most image-guided surgical applications utilizing nanotechnology are now in the preclinical stage, some are beginning to reach the clinical phase. Here, we list the various imaging techniques used in image-guided surgery, such as optical imaging, ultrasound, computed tomography, magnetic resonance imaging, nuclear medicine imaging, and the most current developments in the potential of nanotechnology to detect surgical malignancies. In the coming years, we will see the evolution of nanoparticles tailored to specific tumour types and the introduction of surgical equipment to improve resection accuracy. Although the promise of nanotechnology for producing exogenous molecular contrast agents has been clearly demonstrated, much work remains to be done to put it into practice. Graphical Abstrac

PMM2-CDG: Phenotype and genotype in four affected family members

Abstract Congenital disorders of glycosylation (CDG) are genetic defects in protein and lipid glycosylation. PMM2-CDG is the most prevalent protein N-glycosylation disorder with more than 700 reported patients. Here we report on a large Italian family with four affected members and three mutations. Two young sisters are compound heterozygous for mutations p.Leu32Arg and p.Arg141His, while two paternal great-aunts are compound heterozygosity for p.Leu32Arg and p.Thr237Met. The latter association has not been reported before. The most severely affected member had in addition an ALG6 mutation known to exacerbate the phenotype of patients with PMM2-CDG. Abbreviations CDG, Congenital disorders of glycosylation; PMM2, phosphomannomutase 2; ALG6, alpha-1,3-glucosyltransferase; CDT, carbohydrate-deficient transferri

Potential use of polymeric nanoparticles for drug delivery across the blood-brain barrier.

Nanomedicine is certainly one of the scientific and technological challenges of the coming years. In particular, biodegradable nanoparticles formulated from poly (D,L-lactide-co-glycolide) (PLGA) have been extensively investigated for sustained and targeted delivery of different agents, including recombinant proteins, plasmid DNA, and low molecular weight compounds. PLGA NPs present some very attractive properties such as biodegradability and biocompatibility, protection of drug from degradation, possibility of sustained release, and the possibility to modify surface properties to target nanoparticles to specific organs or cells. Moreover, PLGA NPs have received the FDA and European Medicine Agency approval in drug delivery systems for parenteral administration, thus reducing the time for human clinical applications. This review in particular deals on surface modification of PLGA NPs and their possibility of clinical applications, including treatment for brain pathologies such as brain tumors and Lysosomal Storage Disorders with neurological involvement. Since a great number of pharmacologically active molecules are not able to cross the Blood-Brain Barrier (BBB) and reach the Central Nervous System (CNS), new brain targeted polymeric PLGA NPs modified with glycopeptides (g7-NPs) have been recently produced. In this review several in vivo biodistribution studies and pharmacological proof-of-evidence of brain delivery of model drugs are reported, demonstrating the ability of g7-NPs to create BBB interaction and trigger an efficacious BBB crossing. Moreover, another relevant development of NPs surface engineering was achieved by conjugating to the surface of g7-NPs, some specific and selective antibodies to drive NPs directly to a specific cell type once inside the CNS parenchyma

In vitro treatment of congenital disorder of glycosylation type Ia using PLGA nanoparticles loaded with GDP‑Man

Congenital disorder of glycosylation (CDG) type Ia is a multisystem disorder that occurs due to mutations in the phosphomannomutase 2 (PMM2) gene, which encodes for an enzyme involved in the N‑glycosylation pathway. Mutated PMM2 leads to the reduced conversion of mannose‑6‑P to mannose‑1‑P, which results in low concentration levels of guanosine 5'‑diphospho‑D‑mannose (GDP‑Man), a nucleotide‑activated sugar essential for the construction of protein oligosaccharide chains. In the present study, an in vitro therapeutic approach was used, based on GDP‑Man‑loaded poly (D,L‑lactide‑co‑glycolide) (PLGA) nanoparticles (NPs), which were used to treat CDG‑Ia fibroblast cultures, thus bypassing the glycosylation pathway reaction catalysed by PMM2. To assess the degree of hypoglycosylation in vitro, the present study examined the activities of α‑mannosidase, β‑glucoronidase and β‑galactosidase in defective and normal fibroblasts. GDP‑Man (30 µg/ml GDP‑Man PLGA NPs) was incubated for 48 h with the cells and the specific activities of α‑mannosidase and β‑galactosidase were estimated at 69 and 92% compared with healthy controls. The residual activity of β‑glucoronidase increased from 6.5 to 32.5% and was significantly higher compared with that noted in the untreated CDG‑Ia fibroblasts. The glycosylation process of fibroblasts was also analysed by two‑dimensional electrophoresis. The results demonstrated that treatment caused the reappearance of several glycosylated proteins. The data in vitro showed that GDP‑Man PLGA NPs have desirable efficacy and warrant further evaluation in a preclinical validation animal model

Detection of PLGA-based nanoparticles at single cell level by Synchrotron Radiation FTIR Spectromicroscopy and correlation with X-Ray Fluorescence Microscopy

Poly-lactide-co-glycolide (PLGA) is one of the few polymers approved by the Food and Drug Administration (FDA) as carrier for drug administration in humans and, therefore, it is one of the most used materials in the formulation of polymeric nanoparticles (NPs) for therapeutic purposes. Since the cellular uptake of polymeric NPs is a highlight topic in the nanomedicine field, the development of techniques able to assure an incontrovertible evidence of NPs presence in the cells plays a key role for gaining understanding of their therapeutic potential. On the strength of this premise, this paper aims to evaluate the application of the Synchrotron Radiation-based FTIR (SR-FTIR) spectromicroscopy and the Synchrotron Radiation X-Ray Fluorescence (SR-XRF) microscopy in the study of the in vitro interaction of PLGA NPs with cells. To reach this aim, we used PLGA NPs, sizing around 200 nm and loaded with superparamagnetic iron oxide nanoparticles (Fe3O4; size 10-15 nm) (PLGA-IO-NPs). After having exposed human mesothelial (MeT5A) cells to PLGA-IO-NPs (0.1 mg/ml), the cells were analyzed after fixation both by SR-FTIR spectromicroscopy and SR-XRF microscopy setups. SR-FTIR-SM enabled the detection of PLGA NPs at single cell level allowing the polymer detection inside the biological matrix by the characteristic band in the 1700\u20132000 cm 12 1 region. The precise PLGA IR-signature (1750 cm 12 1 centered pick) was clearly evident also within an area of high amide density. SR-XRF microscopy performed on the same cells investigated under SR-FTIR microscopy allowed to put in evidence the Fe presence in the cells and to emphasize the intracellular localization of the PLGA-IO-NPs. These findings suggest that SR-FTIR and SR-XRF techniques could be two valuable tools to follow the PLGA NPs fate in the in vitro studies on cell cultures