Quantum Backaction on kg-Scale Mirrors: Observation of Radiation Pressure Noise in the Advanced Virgo Detector

The quantum radiation pressure and the quantum shot noise in laser-interferometric gravitational wave detectors constitute a macroscopic manifestation of the Heisenberg inequality. If quantum shot noise can be easily observed, the observation of quantum radiation pressure noise has been elusive, so far, due to the technical noise competing with quantum effects. Here, we discuss the evidence of quantum radiation pressure noise in the Advanced Virgo gravitational wave detector. In our experiment, we inject squeezed vacuum states of light into the interferometer in order to manipulate the quantum backaction on the 42 kg mirrors and observe the corresponding quantum noise driven displacement at frequencies between 30 and 70 Hz. The experimental data, obtained in various interferometer configurations, is tested against the Advanced Virgo detector quantum noise model which confirmed the measured magnitude of quantum radiation pressure noise

Innovative Biomimetic Collagen-based Scaffolds for Enhanced and Longer Lasting Cartilage Repair

This thesis has led to the development of a novel highly porous collagen-based scaffold for enhanced and longer lasting cartilage repair, by incorporating type II collagen (CII) and hyaluronic acid (HyA) within a type I collagen (CI) framework. This newly developed CI/II-HyA scaffold biomaterial has demonstrated to effectively regenerate high-quality cartilage-like tissue in vitro with promise to provide stable and long-term performance in vivo for cartilage repair. Furthermore, this platform was successfully adapted to deliver gene therapy, specifically involving the development of an innovative microRNA-activated scaffold which offers greater control of the mesenchymal stem cell (MSC) chondrogenic processes, and possibly enhanced cartilage repair in the clinic. These scaffold systems show good promise for simple and effective “off the shelf” application in patients for cartilage repair.</div

Highly Porous Type II Collagen-Containing Scaffolds for Enhanced Cartilage Repair with Reduced Hypertrophic Cartilage Formation

The ability to regenerate damaged cartilage capable of long-term performance in an active joint remains an unmet clinical challenge in regenerative medicine. Biomimetic scaffold biomaterials have shown some potential to direct effective cartilage-like formation and repair, albeit with limited clinical translation. In this context, type II collagen (CII)-containing scaffolds have been recently developed by our research group and have demonstrated significant chondrogenic capacity using murine cells. However, the ability of these CII-containing scaffolds to support improved longer-lasting cartilage repair with reduced calcified cartilage formation still needs to be assessed in order to elucidate their potential therapeutic benefit to patients. To this end, CII-containing scaffolds in presence or absence of hyaluronic acid (HyA) within a type I collagen (CI) network were manufactured and cultured with human mesenchymal stem cells (MSCs) in vitro under chondrogenic conditions for 28 days. Consistent with our previous study in rat cells, the results revealed enhanced cartilage-like formation in the biomimetic scaffolds. In addition, while the variable chondrogenic abilities of human MSCs isolated from different donors were highlighted, protein expression analysis illustrated consistent responses in terms of the deposition of key cartilage extracellular matrix (ECM) components. Specifically, CI/II-HyA scaffolds directed the greatest cell-mediated synthesis and accumulation in the matrices of type II collagen (a principal cartilage ECM component), and reduced deposition of type X collagen (a key protein associated with hypertrophic cartilage formation). Taken together, these results provide further evidence of the capability of these CI/II-HyA scaffolds to direct enhanced and longer-lasting cartilage repair in patients with reduced hypertrophic cartilage formation

I cipressi di Bolgheri. Riqualificazione paesaggistica del viale di Bolgheri. Studio progettuale per il suo recupero e gestione

On the cover: CypMed Interreg III B Medocc. Bolgheri 27 settembre 2003Consiglio Nazionale delle Ricerche - Biblioteca Centrale - P.le Aldo Moro, 7 , Rome / CNR - Consiglio Nazionale delle RichercheSIGLEITItal

A highly porous type II collagen containing scaffold for the treatment of cartilage defects enhances MSC chondrogenesis and early cartilaginous matrix deposition.

A major challenge in cartilage tissue engineering (TE) is the development of instructive and biomimetic scaffolds capable of driving effective mesenchymal stem cell (MSC) chondrogenic differentiation and robust de novo matrix formation. Type I collagen-based scaffolds are one of the most commonly selected materials given collagen's intrinsic ability to act as an instructive and active biomaterial. However, the chondrogenic potential of these scaffolds does not offer significant improvement over traditional treatments. We propose that taking a biomimetic approach to scaffold development might lead to an improved outcome for enhanced cartilage repair. Therefore, this study aimed to develop innovative type II collagen (CII)-containing scaffolds for enhanced cartilage repair, by incorporating CII and/or hyaluronic acid (HyA) into a type I collagen (CI) framework. Moreover, focus was placed on understanding the potential synergistic effects played by CII in combination with HyA, in terms of MSC chondrogenesis and cartilage-like formation, when both molecules are incorporated into scaffold biomaterials. The newly developed CII-containing scaffold exhibited a highly porous interconnected structure with 99% porosity and similar mechanical properties to previously optimised collagen-based scaffolds. Although all scaffold variants sustained early cartilaginous matrix deposition, the CII-containing scaffolds in the presence of HyA performed best, offering enhanced deposition and distribution of sulphated glycosaminoglycans (sGAG) in vitro by day 28. Taken together, the combination of CII and HyA resulted in the development of a biomimetic scaffold with improved chondrogenic benefits. These simple "off-the-shelf" implants hold great promise to direct enhanced tissue regeneration for the treatment of focal cartilage defects

An innovative miR-activated scaffold for the delivery of a miR-221 inhibitor to enhance cartilage defect repair

The development of treatments to restore damaged cartilage that can provide functional recovery with minimal risk of revision surgery remains an unmet clinical need. Gene therapy shows increased promise as an innovative solution for enhanced tissue repair. Within this study a novel microRNA (miR)-activated scaffold is developed for enhanced mesenchymal stem/stromal cells (MSC) chondrogenesis and cartilage repair through the delivery of an inhibitor to microRNA-221 (miR-221), which is known to have a negative effect of chondrogenesis. To fabricate the miR-activated scaffolds, composite type II collagen-containing scaffolds designed specifically for cartilage repair are first manufactured by lyophilization and then functionalized with glycosaminoglycan-binding enhanced transduction (GET) system nanoparticles (NPs) encapsulating the miR-221 inhibitor. Subsequently, scaffolds are cultured with human-derived MSCs in vitro under chondrogenic conditions for 28 days. The miR-activated scaffolds successfully transfect human MSCs with the miR-221 cargo in a sustained and controlled manner up to 28 days. The silencing of miR-221 in human MSCs using the miR-activated scaffold promotes an improved and more robust cell-mediated chondrogenic response with repressed early-stage events related to MSC hypertrophy. Taken together, this innovative miR-activated scaffold for the delivery of a miR-221 inhibitor demonstrates capability to improve chondrogenesis with promise to enhance cartilage defect repair. </p

3D-printed chitosan-based scaffolds: An in vitro study of human skin cell growth and an in-vivo wound healing evaluation in experimental diabetes in rats

The fabrication of porous 3D printed chitosan (CH) scaffolds for skin tissue regeneration and their behavior in terms of biocompatibility, cytocompatibility and toxicity toward human fibroblasts (Nhdf) and keratinocytes (HaCaT), are presented and discussed. 3D cell cultures achieved after 20 and 35 days of incubation showed significant in vitro qualitative and quantitative cell growth as measured by neutral red staining and MTT assays and confirmed by scanning electron microphotographs. The best cell growth was obtained after 35 days on 3D scaffolds when the Nhdf and HaCaT cells, seeded together, filled the pores in the scaffolds. An early skin-like layer consisting of a mass of fibroblast and keratinocyte cells growing together was observed. The tests of 3D printed scaffolds in wound healing carried out on streptozotocin-induced diabetic rats demonstrate that 3D printed scaffolds improve the quality of the restored tissue with respect to both commercial patch and spontaneous healing

Emerging role of Lipopolysaccharide binding protein in sepsis-induced acute kidney injury

Sepsis remains a serious cause of morbidity and mortality in critically ill patients, with limited therapeutic options available. Of the several disorders connected with sepsis, acute kidney injury (AKI) is one of the major complications. The pathophysiology of sepsis-induced AKI is characterized by severe inflammation in renal parenchyma with endothelial dysfunction, intra-glomerular thrombosis and tubular injury. Endothelial dysfunction is regulated by several mechanisms implicated in cellular de-differentiation, such as endothelial-to-mesenchymal transition (EndMT). Gram-negative bacteria and their cell wall component lipopolysaccharides (LPSs) are frequently involved in the pathogenesis of AKI. The host recognition of LPS requires a specific receptor, which belongs to the Toll-like receptor (TLR) family of proteins, called TLR4, and two carrier proteins, namely the LPS-binding protein (LBP) and cluster of differentiation 14 (CD14). In particular, LBP is released as a consequence of Gram-negative infection and maximizes the activation of TLR4 signalling. Recent findings regarding the emerging role of LBP in mediating sepsis-induced AKI, and the possible beneficial effects resulting from the removal of this endogenous adaptor protein, will be discussed in this review