Fibrin gel: a new scaffold for cardiovascular applications

Aims: Peripheral blood endothelial progenitor cells (EPC) are promising therapies for irreversible myocardial damage, heart failure and peripheral ischemia disease. Natural biopolymers as fibrin are appealing in tissue engineering, because fibrin is biocompatible and bioresorbable. In vitro studies indicate that fibrin can support the growth migration and proliferation of several cells types. Up to date numerous studies have proved the potential of fibrin based injectable cell delivery systems. No studies are available with fibrin as scaffold for EPC. The goal of this study was to investigate if fibrin is a suitable matrix for EPC culture as compared with fibronectin and if different concentrations of fibrinogen (Fb) and thrombin (Th) can influence fibrin structure and EPC behaviour. Methods: Fibrin (Kedrion S.p.a. Lucca, Italy) was prepared mixing Fb (final 4.5-9-18-36 mg/ml) and Th (final 6-12.5-25-50 U/ml). The scaffolds were maintained for 1 hour at 37?C, 5% CO2 before cell seeding. The ultrastructure of fibrin was investigated by scanning electron microscopy (SEM), cryogenic SEM (CRYO-SEM) and atomic force microscopy (AFM) that allow the hydratating analysis of the sample, to evaluate fibre diameter and density. EPC were obtained from peripheral blood of healthy donors and cultured for 1 week on fibrin at the concentration of 1x106 cell/ml in endothelial growth medium. EPC seeded on fibronectin were used as control. Metabolic cell activity on the different scaffolds was assessed after 7 and 14 days by WST1 while cell viability by confocal microscopy (Calcein AM incorporation). Results: Fibrin polymerization rate ranged between 17 and 68 seconds and increased at higher Fb or Th concentrations. Both AFM and SEM analysis revealed a nanometric fibrous structure, with a decrease in fiber diameter with higher fibrinogen concentrations (4.5 mg/ml: 166?4 nm. vs. 36 mg/ml: 119?3 nm, p<0.005, n=5). Different concentrations of Th didn\u27t affect fibre diameter and density. CRYO-SEM suggested a reticulate structure with mesh-size up to 10?m. WST1 assay showed that EPC metabolic activity was better with lower fibrinogen concentrations (4.5 mg/ml: 0.890?0.134 a.u. vs. 36 mg/ml 0.234?0.046 a.u., p<0.05, n=5), while Th had no significant effect. Calcein staining demonstrated that EPC were viable at 14 days and even organised in cluster. Conclusions: Fibrin combines important properties of an ideal biological scaffold, like the nanometric structure, important for the growth and migration of cells. Fibrin is also an ideal scaffold for EPC but the ratio between fibrinogen and thrombin is important for cell viability

Tympanic Membrane Collagen Expression by Dynamically Cultured Human Mesenchymal Stromal Cell/Star-Branched Poly(ε-Caprolactone) Nonwoven Constructs

The tympanic membrane (TM) primes the sound transmission mechanism due to special fibrous layers mainly of collagens II, III, and IV as a product of TM fibroblasts, while type I is less represented. In this study, human mesenchymal stromal cells (hMSCs) were cultured on star-branched poly("-caprolactone) (*PCL)-based nonwovens using a TM bioreactor and proper dierentiating factors to induce the expression of the TM collagen types. The cell cultures were carried out for one week under static and dynamic conditions. Reverse transcriptase-polymerase chain reaction (RT-PCR) and immunohistochemistry (IHC) were used to assess collagen expression. A Finite Element Model was applied to calculate the stress distribution on the scaolds under dynamic culture. Nanohydroxyapatite (HA) was used as a filler to change density and tensile strength of *PCL scaolds. In dynamically cultured *PCL constructs, fibroblast surface marker was overexpressed, and collagen type II was revealed via IHC. Collagen types I, III and IV were also detected. Von Mises stress maps showed that during the bioreactor motion, the maximum stress in *PCL was double that in HA/*PCL scaolds. By using a *PCL nonwoven scaold, with suitable physico-mechanical properties, an oscillatory culture, and proper dierentiative factors, hMSCs were committed into fibroblast lineage-producing TM-like collagens

Design, fabrication and characterization of composite piezoelectric ultrafine fibers for cochlear stimulation

Sensorineural hearing loss, primed by dysfunction or death of hair cells in the cochlea, is the main cause of severe or profound deafness. Piezoelectric materials work similarly to hair cells, namely, as mechano-electrical transducers. Polyvinylidene fluoride (PVDF) films have demonstrated potential to replace the hair cell function, but the obtained piezoresponse was insufficient to stimulate effectively the auditory neurons. In this study, we reported on piezoelectric nanocomposites based on ultrafine PVDF fibers and barium titanate nanoparticles (BTNPs), as a strategy to improve the PVDF performance for this application. BTNP/PVDF fiber meshes were produced via rotating-disk electrospinning, up to 20/80 weight composition. The BTNP/PVDF fibers showed diameters ranging in 0.160-1.325 μm. Increasing collector velocity to 3000 rpm improved fiber alignment. The piezoelectric β phase of PVDF was well expressed following fabrication and the piezoelectric coefficients increased according to the BTNP weight ratio. The BTNP/PVDF fibers were not cytotoxic towards cochlear epithelial cells. Neural-like cells adhered to the composite fibers and, upon mechanical stimulation, showed enhanced viability. Using BTNP filler for PVDF matrices, in the form of aligned ultrafine fibers, increased the piezoresponse of PVDF transducers and favored neural cell contact. Piezoelectric nanostructured composites might find application in next generation cochlear implants

Development of a new technology for 3-D nanostructured scaffolds with potential cardiovascular applications

Aims The in situ release and maintaining of cells to promote revascularization is a new goal of cardiovascular therapy. Endothelial progenitor cells (EPC) may contribute to the process of vascular repair. Medical devices realized according to tissue engineering are composed by a cellular component and by an artificial component, usually made of a biocompatible polymer. Scaffolds may be coated with bio-polymers like fibrin to enhance cell adhesion and growth. Aim of this study was to realize nanocomposite 3D scaffolds composed by a synthetic polymer coated with fibrin to support EPC growth and to promote in vivo angiogenesis. Methods 3D PEtU-PDMS scaffolds were studied in vitro for their biocompatibility (viability and proliferation tests; citokine release). In vivo biocompatibility was studied by intramuscular implant in a rabbit model. The scaffolds were fabricated by spray-phase inversion technique. 25U/mL thrombin was sprayed during the fabrication process. The composite scaffold was then incubated o.n. at 37?C with 18mg/mL fibrinogen. The scaffold morphology was analysed by stereo-microscopy and by scanning electron microscopy (SEM). EPC obtained from peripheral blood were cultured for 1 week on the scaffolds at the concentration of 1x106 cell/ml. Fibronectin coating was used as a control. Cell viability was assessed by confocal laser (Calcein-AM incorporation). To test in vivo angiogenesis, EPC-seeded scaffolds were subcutaneously implanted into the back of rats for 14 days. After harvesting, the scaffolds were examined histologically and immunohistochemically to evaluate inflammatory response and neovascularization. Results In vitro and in vivo biocompatibility data demonstrated absence of any citotoxic effect, immunocompatibility and a slight inflammatory reaction without any sign of encapsulation and implant rejection. Morphological analyses showed an homogeneus fibrin coating of the scaffolds, tightly bound and interconnected to the PEtU-PDMS surface. SEM showed the presence of a well organized layer of fibres in a nm scale (mean diameter ~140nm). Cell viability and phenotype were not affected when EPC were seeded on PEtU-PDMS/fibrin scaffolds. The histological observation of explanted scaffolds revealed a slightly inflammatory response and a significant increased numbers of neovessels in tissues surrounding the EPC-seeded scaffold as compared to the scaffold without cells. Conclusions Our data suggest that PEtU-PDMS/fibrin scaffold obtained with a new spray manufacturing technology can support in vitro EPC growth and promote in vivo neovascularisation. Further studies are currently under way in an ischemic hindlimb rat model

Growing bone tissue-engineered niches with graded osteogenicity: an in vitro method for biomimetic construct assembly

The traditional bone tissue-engineering approach exploits mesenchymal stem cells ( MSCs) to be seeded once only on three-dimensional (3D) scaffolds, hence, differentiated for a certain period of time and resulting in a homogeneous osteoblast population at the endpoint. However, after achieving terminal osteodifferentiation, cell viability is usually markedly compromised. On the other hand, naturally occurring osteogenesis results from the coexistence of MSC progenies at distinct differentiative stages in the same microenvironment. This diversification also enables long-term viability of the mature tissue. We report an easy and tunable in vitro method to engineer simple osteogenic cell niches in a biomimetic fashion. The niches were grown via periodic reseeding of undifferentiated MSCs on MSC/scaffold constructs, the latter undergoing osteogenic commitment. Timefractioning of the seeded cell number during differentiation time of the constructs allowed graded osteogenic cell populations to be grown together on the same scaffolds (i.e., not only terminally differentiated osteoblasts). In such cell-dynamic systems, the overall differentiative stage of the constructs could also be tuned by varying the cell density seeded at each inoculation. In this way, we generated two different biomimetic niche models able to host good reservoirs of preosteoblasts and other osteoprogenitors after 21 culture days. At that time, the niche type resulting in 40.8% of immature osteogenic progenies and only 59.2% of mature osteoblasts showed a calcium content comparable to the constructs obtained with the traditional culture method (i.e., 100.03 – 29.30 vs. 78.51 – 28.50 pg/cell, respectively; p = not significant), the latter colonized only by fully differentiated osteoblasts showing exhausted viability. This assembly method for tissue-engineered constructs enabled a set of important parameters, such as viability, colonization, and osteogenic yield of the MSCs to be balanced on 3D scaffolds, thus achieving biomimetic in vitro models with graded osteogenicity, which are more complex and reliable than those currently used by tissue engineers

Endophytic and rhizospheric bacterial communities isolated from the medicinal plants Echinacea purpurea and Echinacea angustifolia

In this work we analyzed the composition and structure of cultivable bacterial communities isolated from the stem/leaf and root compartments of two medicinal plants, Echinacea purpurea (L.) Moench and Echinacea angustifolia (DC.) Hell, grown in the same soil, as well as the bacterial community from their rhizospheric soils. Molecular PCR-based techniques were applied to cultivable bacteria isolated from the three compartments of the two plants. The results showed that the two plants and their respective compartments were characterized by different communities, indicating a low degree of strain sharing and a strong selective pressure within plant tissues. Pseudomonas was the most highly represented genus, together with Actinobacteria and Bacillus spp. The presence of distinct bacterial communities in different plant species and among compartments of the same plant species could account for the differences in the medicinal properties of the two plants. [Int Microbiol 2014; 17(3):165-174]Keywords: Echinacea purpurea &middot; Echinacea angustifolia &middot; rhizosphere &middot; medicinal plants &middot; endophyte

3-D Fibrin Scaffold Improves Stemness of Human Peripheral Blood Endothelial Progenitor Cells

Aims Fibrin is a natural biopolymer appealing for cell-based regenerative therapies, because it can support growth, migration and differentiation of different cell types. Endothelial progenitor cells (EPC) represent a very interesting alternative cell source for mature endothelial cells; the fact that can easily isolated from the peripheral blood, thereby eliminating donor morbidity, makes them ideal in applications in the field of regenerative medicine. We have demonstrated that fibrin can support EPC viability and growth. Aim of this study was to evaluate if fibrin can affect EPC differentiation and stem cell markers expression. Methods Fibrin was prepared mixing commercially available (Kedrion S.p.A. Lucca, Italy) fibrinogen (9 mg/ml) and thrombin (25 U/ml). Clot ultrastructure was investigated by scanning electron microscopy (SEM) and cryogenic SEM (CRYO-SEM) to measure fibre diameter and density. Clot elasticity was evaluated by atomic force microscopy (AFM), measuring the tip-sample force by cantilever displacement. EPC were obtained from peripheral blood and cultured on fibrin at the concentration of 1x106cell/cm2. Fibronectin coating was used as a control. Metabolic activity was assessed after 7 and 14 days by WST1 assay and viability by confocal microscopy (calcein incorporation). The expression of both endothelial (CD31, KDR, vWF, Ve-Cadherin) and stem cell markers (nanog, oct-4) was assessed by flow cytometry, confocal microscopy and Real Time RT-PCR. Results SEM analysis revealed a nanometric fibrous structure, with mean fiber diameter of 165?4 nm and mean density of 95.9?0.2 %. CRYO-SEM suggested a reticulate structure with mesh-size up to 10 ?m. Fibrin clot elasticity was 1.78 MPa, as in literature. WST1 assay showed that fibrin increased EPC metabolic activity as compared to fibronectin (fibrin: 0.606?0.056 a.u. vs. fibronectin: 0.311?0.067). Calcein staining demonstrated that EPC were still viable at 14 days. Flow cytometry showed the expression of endothelial markers (CD31=41.8?8.4%; vWF=32.3?3.0%; KDR=89.3?3.7%; VE-Cadherin=41.2?3.8%), confirmed also by confocal microscopy and Real Time RT-PCR. Interestingly, nanog and oct-4 (embryonic stem cell markers) expression was significantly greater on fibrin (p<0.001) as compared to fibronectin. Conclusions These findings suggest that fibrin it is not only a suitable scaffold for EPC growth and viability but also induces EPC differentiation. The observation that Nanog, known as the most important marker of stemness, is maintained longer than on fibronectin, may offer a surplus value to stem cell-based therapies

Discovery of pyridoquinoxaline-based new P-gp inhibitors as coadjutant against Multi Drug Resistance in cancer

Multi-drug resistance (MDR) is a serious challenge in contemporary clinical practice and is mostly responsible for the failure of cancer medication therapies. Several experimental evidence links MDR to the overexpression of the drug efflux transporter P-gp, therefore, the discovery of novel P-glycoprotein inhibitors is required to treat or prevent MDR and to improve the absorption of chemotherapy drugs via the gastrointestinal system. In this work, we explored a series of novel pyridoquinoxaline-based derivatives designed from parental compounds, previously proved active in enhancing anticancer drugs in MDR nasopharyngeal carcinoma (KB). Among them, derivative 10d showed the most potent and selective inhibition of fluorescent dye efflux, if compared to reference compounds (MK-571, Novobiocin, Verapamil), and the highest MDR reversal activity when co-administered with the chemotherapeutic agents Vincristine and Etoposide, at non-cytotoxic concentrations. Molecular modelling predicted the two compound 10d binding mode in a ratio of 2:1 with the target protein. No cytotoxicity was observed in healthy microglia cells and off-target investigations showed the absence of CaV1.2 channel blockade. In summary, our findings indicated that 10d could potentially be a novel therapeutic coadjutant by inhibiting Pgp transport function in vitro, thereby reversing cancer multidrug resistance

In vitro study on the generation of tympanic membrane substitutes via tissue engineering

The tympanic membrane (TM) is an anatomical structure with unique histological and physiological features playing a fundamental role in sound transmission. In particular, the middle layer of the pars tensa, which represents the widest and thickest surface portion of the TM, consists of connective tissue mainly composed of collagen types II and III fibers, while collagen type I is present at a lesser extent [1]. Several pathologies affect the TM, including otitis media, tympanosclerosis, cholesteatoma and perforation that require reconstructive surgery depending on the lesion extent [2]. To this purpose, the temporalis fascia is currently considered as the gold standard material. However, due to limited graft availability, fully synthetic substitutes are also applied, with poorly satisfactory outcomes. For these reasons new strategies for TM replacement are still needed. In this study, we employed a tissue engineering (TE) approach for the regeneration of TM substitutes selecting some biocompatible and bioresorbable polymeric matrices to be cultured with human bone marrow-derived mesenchymal stem cells (MSCs). We set up a cell differentiation protocol using an appropriate mix of growing factors to obtain the in vitro differentiation of MSCs into TM fibroblasts. Furthermore, because of the role played by mechanical forces in TM motion, these engineered substitutes underwent mechanical stress during the culture. The obtained biohybrid constructs were characterized about cellular viability assays, gene expression quantification as well as histochemical and immunohistochemical analyses. Moreover, native TMs from cadavers were investigated for assessment and optimization of the engineered constructs. Our results showed that MSCs were able to grow and differentiate properly on the selected biomaterials and to synthesize appropriate extracellular matrix molecules. Moreover, the applied mechanical forces seem to promote TM-fibroblastic differentiation, increasing the production of collagen type II, that is a peculiarity of TM structure

Hit-to-Lead Optimization of Mouse Trace Amine Associated Receptor 1 (mTAAR1) Agonists with a Diphenylmethane-Scaffold: Design, Synthesis, and Biological Study

The trace amine-associated receptor 1 (TAAR1) is a G-protein-coupled receptors (GPCR) potently activated by a variety of molecules besides trace amines (TAs), including thyroid hormone-derivatives like 3-iodothyronamine (T1AM), catechol-O-methyltransferase products like 3-methoxytyramine, and amphetamine-related compounds. Accordingly, TAAR1 is considered a promising target for medicinal development. To gain more insights into TAAR1 physiological functions and validation of its therapeutic potential we recently developed a new class of thyronamine-like derivatives. Among them compound SG2 showed high affinity and potent agonist activity at mouse TAAR1. In the present work we describe design, the synthesis and SAR study of a new series of compounds (1-16) obtained by introducing specific structural changes at key points of our lead-compound SG2 skeleton. Five of the newly synthesized compounds displayed mTAAR1 agonist activity higher than both SG2 and T1AM. Selected diphenylmethane analogs, namely 1 and 2, showed potent functional activity in in vitro and in vivo models