Silvia Farè scite author profile

This study assesses in vivo the surface roughness necessary to reduce plaque colonization on titanium after 24 hours. Three groups of 16 titanium disks were assigned to 3 different polishing groups (A, B, and C). The roughness was evaluated with a laser profilometer and the morphology with a scanning electron microscope (SEM). Eight volunteers were enrolled and two Stents were applied in the mandibular posterior region of each. Each Stent supported 3 disks, one per group. The volunteers suspended oral hygiene for 24 hours, after which the Stents were removed; one was processed for evaluation of the adherent biomass and the other for SEM study. On each specimen a global area of 100 × 125 μm was examined with SEM. The area was composed of five 20 × 25 μm randomly selected fields. For each field the density of bacteria and the morphotypes were recorded. The data quoted for the global area are cumulative of those observed in the 20 × 25 μm fields. Group A had a significantly smoother surface than groups B and C. The adherent microbial biomass determination and SEM evaluation revealed that group A contained less bacteria than the roughest group. The bacterial population was composed of cocci in group A, and of cocci and short and long rods in groups B and C. We conclude that a titanium surface with Ra ≤ 0.088 μm and Rz < 1.027 μm strongly inhibits accumulation and maturation of plaque at the 24‐hour time period and that such smoothness can be achieved in transgingival and healing implant components. J Periodontol 1997;68:556–562.

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Vascular Tissue Engineering: Recent Advances in Small Diameter Blood Vessel Regeneration

Catto

Farè

Freddi³

et al. 2014

ISRN Vascular Medicine

129

130

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Cardiovascular diseases are the leading cause of mortality around the globe. The development of a functional and appropriate substitute for small diameter blood vessel replacement is still a challenge to overcome the main drawbacks of autografts and the inadequate performances of synthetic prostheses made of polyethylene terephthalate (PET, Dacron) and expanded polytetrafluoroethylene (ePTFE, Goretex). Therefore, vascular tissue engineering has become a promising approach for small diameter blood vessel regeneration as demonstrated by the increasing interest dedicated to this field. This review is focused on the most relevant and recent studies concerning vascular tissue engineering for small diameter blood vessel applications. Specifically, the present work reviews research on the development of tissue-engineered vascular grafts made of decellularized matrices and natural and/or biodegradable synthetic polymers and their realization without scaffold.

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Compliant electrospun silk fibroin tubes for small vessel bypass grafting

et al. 2010

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Towards 4D printed scaffolds for tissue engineering: exploiting 3D shape memory polymers to deliver time-controlled stimulus on cultured cells

et al. 2017

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Tissue engineering needs innovative solutions to better fit the requirements of a minimally invasive approach, providing at the same time instructive cues to cells. The use of shape memory polyurethane has been investigated by producing 4D scaffolds via additive manufacturing technology. Scaffolds with two different pore network configurations (0/90° and 0/45°) were characterized by dynamic-mechanical analysis. The thermo-mechanical analysis showed a T at about 32 °C (T = T ), indicating no influence of the fabrication process on the transition temperature. In addition, shape recovery tests showed a good recovery of the permanent shape for both scaffold configurations. When cells were seeded onto the scaffolds in the temporary shape and the permanent shape was recovered, cells were significantly more elongated after shape recovery. Thus, the mechanical stimulus imparted by shape recovery is able to influence the shape of cells and nuclei. The obtained results indicate that a single mechanical stimulus is sufficient to initiate changes in the morphology of adherent cells.

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Silvia Farè

The Effect of Surface Roughness on Early In Vivo Plaque Colonization on Titanium

Vascular Tissue Engineering: Recent Advances in Small Diameter Blood Vessel Regeneration

Compliant electrospun silk fibroin tubes for small vessel bypass grafting

Towards 4D printed scaffolds for tissue engineering: exploiting 3D shape memory polymers to deliver time-controlled stimulus on cultured cells

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