Your search keyword '"Marsano, Anna"' showing total 7 results

1. Fatty acid-based monolayer culture to promote in vitro neonatal rat cardiomyocyte maturation

Author

Isu, Giuseppe, Robles Diaz, Diana, Grussenmeyer, Thomas, Gaudiello, Emanuele, Eckstein, Friedrich, Brink, Marijke, and Marsano, Anna

Published

2020

2. Engineered mesenchymal cell-based patches as controlled VEGF delivery systems to induce extrinsic angiogenesis.

Author

Boccardo, Stefano, Gaudiello, Emanuele, Melly, Ludovic, Cerino, Giulia, Ricci, Davide, Martin, Ivan, Eckstein, Friedrich, Banfi, Andrea, and Marsano, Anna

Subjects

NEOVASCULARIZATION, TISSUE engineering, VASCULAR endothelial growth factors, PROGENITOR cells, STROMAL cells, TISSUE scaffolds

Abstract

Therapeutic over-expression of Vascular Endothelial Growth Factor (VEGF) by transduced progenitors is a promising strategy to efficiently induce angiogenesis in ischemic tissues (e.g. limb muscle and myocardium), but tight control over the micro-environmental distribution of the dose is required to avoid induction of angioma-like tumors. Therapeutic VEGF release was achieved by purified transduced adipose mesenchymal stromal cells (ASC) that homogeneously produce specific VEGF levels, inducing only normal angiogenesis after injection in non-ischemic tissues. However, the therapeutic potential of this approach mostly in the cardiac field is limited by the poor cell survival and the restricted area of effect confined to the cell-injection site. The implantation of cells previously organized in vitro in 3D engineered tissues could overcome these issues. Here we hypothesized that collagen sponge-based construct (patch), generated by ASC expressing controlled VEGF levels, can function as delivery device to induce angiogenesis in surrounding areas (extrinsic vascularization). A 7-mm-thick acellular collagen scaffold (empty), sutured beneath the patch, provided a controlled and reproducible model to clearly investigate the ongoing angiogenesis in subcutaneous mice pockets. VEGF-expressing ASC significantly increased the capillary in-growth inside both the patch itself and the empty scaffold compared to naïve cells, leading to significantly improved survival of implanted cells. These data suggest that this strategy confers control (i) on angiogenesis efficacy and safety by means of ASC expressing therapeutic VEGF levels and (ii) over the treated area through the specific localization in an engineered collagen sponge-based patch. Statement of Significance Development of efficient pro-angiogenic therapies to restore the micro-vascularization in ischemic tissues is still an open issue. Although extensively investigated, the promising approach based on injections of progenitors transduced to over-express Vascular Endothelial Growth Factor (VEGF) has still several limitations: (i) need of a tight control over the microenvironmental VEGF dose to avoid angioma-like tumor growth; (ii) poor implanted cell survival; (iii) effect area restricted mainly to the injection sites. Here, we aimed to overcome these drawbacks by generating a novel cell-based controlled VEGF delivery device. In particular, transduced mesenchymal cells, purified to release a sustained, safe and efficient VEGF dose, were organized in three-dimensional engineered tissues to improve cell survival and provide a uniform vascularization throughout both the mm-thick implanted constructs themselves and the surrounding area. [ABSTRACT FROM AUTHOR]

Published

2016

3. The effect of controlled expression of VEGF by transduced myoblasts in a cardiac patch on vascularization in a mouse model of myocardial infarction

Author

Marsano, Anna, Maidhof, Robert, Luo, Jianwen, Fujikara, Kana, Konofagou, Elisa E., Banfi, Andrea, and Vunjak-Novakovic, Gordana

Subjects

*GENE expression, *VASCULAR endothelial growth factors, *MYOBLASTS, *LABORATORY mice, *MYOCARDIAL infarction, *ELASTOMERS, *TISSUE scaffolds

Abstract

Abstract: Key requirements for cardiac tissue engineering include the maintenance of cell viability and function and the establishment of a perfusable vascular network in millimeters thick and compact cardiac constructs upon implantation. We investigated if these requirements can be met by providing an intrinsic vascularization stimulus (via sustained action of VEGF secreted at a controlled rate by transduced myoblasts) to a cardiac patch engineered under conditions of effective oxygen supply (via medium flow through channeled elastomeric scaffolds seeded with neonatal cardiomyocytes). We demonstrate that this combined approach resulted in increased viability, vascularization and functionality of the cardiac patch. After implantation in a mouse model of myocardial infarction, VEGF-expressing patches displayed significantly improved engraftment, survival and differentiation of cardiomyocytes, leading to greatly enhanced contractility as compared to controls not expressing VEGF. Controlled VEGF expression also mediated the formation of mature vascular networks, both within the engineered patches and in the underlying ischemic myocardium. We propose that this combined cell-biomaterial approach can be a promising strategy to engineer cardiac patches with intrinsic and extrinsic vascularization potential. [Copyright &y& Elsevier]

Published

2013

4. Efficacy and mechanisms of vacuum-assisted closure (VAC) therapy in promoting wound healing: a rodent model.

Author

Jacobs, Sharone', Simhaee, David A., Marsano, Anna, Fomovsky, Gregory M., Niedt, George, and Wu, June K.

Subjects

WOUND healing, LABORATORY rodents, ANIMAL models in research, GRANULATION tissue, POSTOPERATIVE care, TREATMENT effectiveness, SURGICAL excision

Abstract

Summary: Background: The vacuum-assisted closure device (VAC) has revolutionised wound care, although molecular mechanisms are not well understood. We hypothesise that the VAC device induces production of pro-angiogenic factors and promotes formation of granulation tissue and healing. Methods: A novel rodent model of VAC wound healing was established. Excisional wounds were created on rat dorsa. Wounds were dressed with Tegaderm (control group), VAC Granulofoam® and Tegaderm (special control group), or VAC Granulofoam®, T.R.A.C. PAD® with 125mmHg continuous negative pressure (VAC group). Wound closure rates were calculated as a percentage of initial wound sizes. Rats were sacrificed on postoperative days 3, 5 and 7; harvested tissues were processed for histology [haematoxylin & eosin (H&E), Masson''s trichrome, picrosirius red] and Western blot analysis (CD31, vascular endothelial growth factor, basic fibroblast growth factor). Results: Statistically significant wound closure rates were achieved in the experimental group at all measured time points: day 3, 28.1% (VAC) vs 8.2% (control) and 8.8% (special control) (ANOVA, P <0.0001); day 5, 45.3% (VAC) vs 23.7% (control) and 22.5% (special control) (ANOVA, P =0.0003); day 7, 54.4% (VAC) vs 43.0% (control) and 31.5% (special control) (ANOVA; P <0.0001). Morphological evaluation by Masson''s trichrome stain showed increased collagen organisation and wound maturation in the VAC group. These wounds also showed increased expression of vascular endothelial growth factor and fibroblast growth factor-2 on day 5 by Western blot analysis. Conclusion: A small animal VAC wound model was established. Wounds treated with a VAC device showed accelerated wound closure rates, increased pro-angiogenic growth factor production and improved collagen deposition. Further application of this model may elucidate other mechanisms. [Copyright &y& Elsevier]

Published

2009

5. Use of hydrodynamic forces to engineer cartilaginous tissues resembling the non-uniform structure and function of meniscus

Author

Marsano, Anna, Wendt, David, Raiteri, Roberto, Gottardi, Riccardo, Stolz, Martin, Wirz, Dieter, Daniels, Alma U., Salter, Donald, Jakob, Marcel, Quinn, Thomas M., and Martin, Ivan

Subjects

*HYDRODYNAMICS, *FLUID dynamics, *BIOMECHANICS, *TISSUE mechanics

Abstract

Abstract: The aim of this study was to demonstrate that differences in the local composition of bi-zonal fibrocartilaginous tissues result in different local biomechanical properties in compression and tension. Bovine articular chondrocytes were loaded into hyaluronan-based meshes (HYAFF®-11) and cultured for 4 weeks in mixed flask, a rotary Cell Culture System (RCCS), or statically. Resulting tissues were assessed histologically, immunohistochemically, by scanning electron microscopy and mechanically in different regions. Local mechanical analyses in compression and tension were performed by indentation-type scanning force microscopy and by tensile tests on punched out concentric rings, respectively. Tissues cultured in mixed flask or RCCS displayed an outer region positively stained for versican and type I collagen, and an inner region positively stained for glycosaminoglycans and types I and II collagen. The outer fibrocartilaginous capsule included bundles (up to 2μm diameter) of collagen fibers and was stiffer in tension (up to 3.6-fold higher elastic modulus), whereas the inner region was stiffer in compression (up to 3.8-fold higher elastic modulus). Instead, molecule distribution and mechanical properties were similar in the outer and inner regions of statically grown tissues. In conclusion, exposure of articular chondrocyte-based constructs to hydrodynamic flow generated tissues with locally different composition and mechanical properties, resembling some aspects of the complex structure and function of the outer and inner zones of native meniscus. [Copyright &y& Elsevier]

Published

2006

6. Modeling methodology for defining a priori the hydrodynamics of a dynamic suspension bioreactor. Application to human induced pluripotent stem cell culture.

Author

Isu, Giuseppe, Morbiducci, Umberto, De Nisco, Giuseppe, Kropp, Christina, Marsano, Anna, Deriu, Marco A., Zweigerdt, Robert, Audenino, Alberto, and Massai, Diana

Subjects

*INDUCED pluripotent stem cells, *STEM cell culture, *PLURIPOTENT stem cells, *HYDRODYNAMICS

Abstract

Three-dimensional dynamic suspension is becoming an effective cell culture method for a wide range of bioprocesses, with an increasing number of bioreactors proposed for this purpose. The complex hydrodynamics establishing within these devices affects bioprocess outcomes and efficiency, and usually expensive in vitro trial-and-error experiments are needed to properly set the working parameters. Here we propose a methodology to define a priori the hydrodynamic working parameters of a dynamic suspension bioreactor, selected as a test case because of the complex hydrodynamics characterizing its operating condition. A combination of computational and analytical approaches was applied to generate operational guideline graphs for defining a priori specific working parameters. In detail, 43 simulations were performed under pulsed flow regime to characterize advective transport within the device depending on different operative conditions, i.e., culture medium flow rate and its duty cycle, cultured particle diameter, and initial particle suspension volume. The operational guideline graphs were then used to set specific hydrodynamic working parameters for an in vitro proof-of-principle test, where human induced pluripotent stem cell (hiPSC) aggregates were cultured for 24 h within the bioreactor. The in vitro findings showed that, under the selected pulsed flow regime, sedimentation was avoided, hiPSC aggregate circularity and viability were preserved, and culture heterogeneity was reduced, thus confirming the appropriateness of the a priori method. This methodology has the potential to be adaptable to other dynamic suspension devices to support experimental studies by providing in silico -based a priori knowledge, useful to limit costs and to optimize culture bioprocesses. [ABSTRACT FROM AUTHOR]

Published

2019

7. Control of angiogenesis and host response by modulating the cell adhesion properties of an Elastin-Like Recombinamer-based hydrogel.

Author

Staubli, Sebastian Manuel, Cerino, Giulia, Gonzalez De Torre, Israel, Alonso, Matilde, Oertli, Daniel, Eckstein, Friedrich, Glatz, Katharina, Rodríguez Cabello, José Carlos, and Marsano, Anna

Subjects

*NEOVASCULARIZATION, *CELL adhesion, *ELASTIN, *HYDROGELS, *POLYMERS

Abstract

The control of the in vivo vascularization of engineered tissue substitutes is essential in order to obtain either a rapid induction or a complete inhibition of the process (e.g. in muscles and hyaline-cartilage, respectively). Among the several polymers available, Elastin-Like Recombinamers (ELR)-based hydrogel stands out as a promising material for tissue engineering thanks to its viscoelastic properties, non-toxicity, and non-immunogenicity. In this study, we hypothesized that varying the cell adhesion properties of ELR-hydrogels could modulate the high angiogenic potential of adipose tissue-derived stromal vascular fraction (SVF) cells, predominantly composed of endothelial/mural and mesenchymal cells. Human SVF cells, embedded in RGD-REDV-bioactivated or unmodified ELR-hydrogels, were implanted in rat subcutaneous pockets either immediately or upon 5-day-culture in perfusion-bioreactors. Perfusion-based culture enhanced the endothelial cell cord-like-organization and the release of pro-angiogenic factors in functionalized constructs. While in vivo vascularization and host cell infiltration within the bioactivated gels were highly enhanced, the two processes were strongly inhibited in non-functionalized SVF-based hydrogels up to 28 days. ELR-based hydrogels showed a great potential to determine the successful integration of engineered substitutes thanks to their capacity to finely control the angiogenic/inflammation process at the recipient site, even in presence of SVF cells. [ABSTRACT FROM AUTHOR]

Published

2017