Your search keyword '"F. Montini"' showing total 2 results

1. High pressure assessment of bilayered electrospun vascular grafts by means of an Electroforce Biodynamic System®.

Author

Armentano RL, Valdez Jasso D, Cymberknop LJ, Montini Ballarin F, Velez D, Caracciolo PC, and Abraham G

Subjects

Animals, Collagen, Elastic Modulus, Elasticity, Equipment Design, Femoral Artery transplantation, Lactic Acid chemistry, Male, Materials Testing instrumentation, Polyesters chemistry, Polymers chemistry, Polyurethanes chemistry, Pressure, Sheep, Domestic, Tissue Engineering methods, Vascular Grafting methods, Bioprosthesis, Blood Vessel Prosthesis, Materials Testing methods, Vascular Grafting instrumentation

Abstract

Introduction: Tissue engineering offers the possibility of developing a biological substitute material in vitro with the inherent properties required in vivo. However, the inadequate performance in vascular replacement of small diameter vascular grafts (VG) reduces considerably the current alternatives in this field. In this study, a bilayered tubular VG was produced, where its mechanical response was tested at high pressure ranges and compared to a native femoral artery., Materials and Method: The VG was obtained using sequential electrospinning technique, by means of two blends of Poly(L-lactic acid) and segmented poly(ester urethane). Mechanical testing was performed in a biodynamic system and the pressure-strain relationship was used to determine the elastic modulus., Results: Elastic modulus assessed value of femoral artery at a high pressure range (33.02×106 dyn/cm(2)) was founded to be 36% the magnitude of VG modulus (91.47×106 dyn/cm(2)) at the same interval., Conclusion: A new circulating mock in combination with scan laser micrometry have been employed for the mechanical evaluation of bioresorbable bilayered VGs. At same pressure levels, graft elasticity showed a purely "collagenic" behavior with respect to a femoral artery response.

Published

2015

2. Similarities of arterial collagen pressure-diameter relationship in ovine femoral arteries and PLLA vascular grafts.

Author

Armentano RL, Cymberknop LJ, Suarez Bagnasco D, Montini Ballarin F, Balay G, Negreira CA, and Abraham GA

Subjects

Animals, Arteries pathology, Biomechanical Phenomena, Bioprosthesis, Blood Vessel Prosthesis, Elastic Modulus, Elasticity, Elastin chemistry, Male, Polyesters, Pressure, Sheep, Sheep, Domestic, Vascular Grafting, Arteries metabolism, Collagen chemistry, Femoral Artery pathology, Lactic Acid chemistry, Polymers chemistry

Abstract

Introduction: In-vivo implanted vascular grafts fail due to the mechanical mismatch between the native vessel and the implant. The biomechanical characterization of native vessels provides valuable information towards the development of synthetic grafts., Materials and Methods: Five samples of electrospun nanofibrous poly(L-lactic acid)(PLLA) tubular structures were subjected to physiological pulsating pressure using an experimental setup. Four ovine femoral arteries were also tested in the experimental setup under the same conditions. Instantaneous diameter and pressure signals were obtained using gold standard techniques, in order to estimate the dynamic pressure-strain elastic modulus (E(Pε)) of both native vessels and grafts., Results: Synthetic grafts showed a significant increase of E(Pε) (10.57±0.97 to 17.63±2.61 10(6) dyn/cm(2)) when pressure was increased from a range of 50-90 mmHg (elastin-response range) to a range of 100-130 mmHg (collagen-response range). Furthermore, femoral arteries also exhibited a significant increase of EPε (1.66±0.30 to 15.76±4.78 10(6) dyn/cm(2)) with the same pressure variation, showing that both native vessels and synthetic grafts have a similar behavior in the collagen-acting range., Conclusion: The mechanical behavior of PLLA vascular grafts was characterized In vitro. However, the procedure can be easily extrapolated to In vivo experiences in conscious and chronically instrumented animals.

Published

2014