Ruben Y. Kannan

Silsesquioxane nanocomposites as tissue implants.

Background: Silicone implants are being used increasingly worldwide, especially in breast augmentation procedures. The most common morbidity observed is capsular contracture, which occurs in 15 percent of cases. To overcome this problem, the authors have developed a novel nanocomposite based on polyhedral oligomeric silsesquioxane-poly(carbonate-urea)urethane (POSS-PCU) for use as tissue implants. Methods: These polymers were implanted in six healthy sheep (n = 6) for 36 months and a siloxane served as the positive control. After explantation, these polymers were extracted, as was the surrounding capsule, if any. Attenuated total reflectance Fourier transform infrared spectroscopy analysis was performed to look for signs of surface degradation on the polymers and histopathologic and electron microscopic examinations were performed to study the interaction between the biomaterial and the host environment in greater detail. Results: After implantation, the authors observed minimal inflammation of the nanocomposite within the sheep model as compared with the siloxane control. Contact angle measurements and fibrinogen enzyme-linked immunosorbent assay tests were then conducted on the POSS-PCU nanocomposite to determine the reason for this behavior. The increased fibrinogen adsorption on POSS-PCU, its amphilicity, and large contact-angle hysteresis indicated that POSS-PCU inhibits inflammation by adsorbing and inactivating fibrinogen on its surface. In complete contrast, the control siloxane in the same setting demonstrated very significant inflammation and degradation, resulting in capsular formation. Naturally, there was no evidence of degradation of the nanocomposite compared with the siloxane control. Conclusions: POSS-PCU nanocomposites have enhanced interfacial biocompatibility and better biological stability as compared with conventional silicone biomaterials, thus making them safer as tissue implants.

The endothelialization of polyhedral oligomeric silsesquioxane nanocomposites - An in vitro study

It has been recognized that seeding vascular bypass grafts with endothelial cells is the ideal method of improving their long-term patency rates. The aim of this study was to assess the in vitro cytocompatibility of a novel silica nanocomposite, polyhedral oligomeric silsesquioxane-poly(carbonate-urea)urethane (POSS-PCU) and hence elicit its feasibility at the vascular interface for potential use in cardiovascular devices such as vascular grafts. Using primary human umbilical vein endothelial cells (HUVEC), cell viability and adhesion were studied using AlamarBlue assays, whereas cell proliferation on the polymer was assessed using the PicoGreen dye assay. Cellular confluence and morphology on the nanocomposite were analyzed using light and electron microscopy, respectively. Our results showed that there was no significant difference between cell viability in standard culture media and POSS-PCU. Endothelial cells were capable of adhering to the polymer within 30 min of contact (Students t-test, p<0.05) with no difference between POSS-PCU and control cell culture plates. POSS-PCU was also capable of sustaining good cell proliferation for up to 14d even from low seeding densities (1.0×103 cells/cm2) and reaching saturation by 21 d. Microscopic analysis showed evidence of optimal endothelial cell adsorption morphology with the absence of impaired motility and morphogenesis. In conclusion, these results support the application of POSS-PCU as a suitable biomaterial scaffold in bio-hybrid vascular prostheses and biomedical devices.

Artificial nerve conduits in peripheral-nerve repair

Injuries to the nervous system are the result of mechanical, thermal, chemical or congenital pathologies and, if function is not restored, they lead to loss of muscle function, pain and impaired sensation. Current treatment modalities essentially coapt the two nerves ends together or place a nerve graft between the cut ends. However, clinical results have never been optimal, and therefore a quest for better options has taken place. In this review article we look at the synthetic and biomimetic options currently being tested as potential nerve grafts.

Review paper: principles and applications of surface analytical techniques at the vascular interface.

Surface properties have been found to be one of the key parameters which cause degradation and of thrombogenicity in all polymers used in biomedical devices, thus signifying the importance and the necessity for quantitative and accurate characterization of the polymer surface itself as used in the construction of the device. The characterization techniques employed generally involve thermal and spectroscopic measurements, in which class the electrochemical investigations and scanning probe microscopies can also be included. Current hypotheses on the correlations that exist between surface parameters and hemocompatibility and degradation of polymers are examined herein, but concentrating on the field of clinically utilized polymeric materials as used within medical devices themselves. Furthermore, this review provides a brief but complete synopsis of these techniques and other emerging ones, which have proven useful in the analysis of the surface properties of polymeric materials as used in the construction of cardiovascular devices. Statements and examples are given as to how specific information can be acquired from these differing methodologies and how it aids in the design and development of new polymers for usage in biomedical device construction.

Is there an alternative to systemic anticoagulation, as related to interventional biomedical devices?

To reduce the toxic effects, related clinical problems and complications such as bleeding disorders associated with systemic anticoagulation, it has been hypothesized that by coating the surfaces of medical devices, such as stents, bypass grafts, extracorporeal circuits, guide wires and catheters, there will be a significant reduction in the requirement for systemic anticoagulation or, ideally, it will no longer be necessary. However, current coating processes, even covalent ones, still result in leaching followed by reduced functionality. Alternative anticoagulants and related antiplatelet agents have been used for improvement in terms of reduced restenosis, intimal hyperphasia and device failure. This review focuses on existing heparinization processes, their application in clinical devices and the updated list of alternatives to heparinization in order to obtain a broad overview, it then highlights, in particular, the future possibilities of using heparin and related moieties to tissue engineer scaffolds.

Ex Vivo Formation of Blood Vessels

Vascular bypass grafts represent a well-grounded technological advance in the new millennium, this being related to the high prevalence of atherosclerosis and the ensuing treatment of myocardial infarction [1]. However, more recently a paradigm shift has occurred casting the subject of vascular tissue engineering in new light. The development of cardiovascular devices both for high- and low-flow scenarios in the form of functional vascular prostheses has made this possible. While the patency rates of highflow vessels [2], such as polyethylene terephthalate (Dacron) and expanded polytetrafluoroethylene (ePTFE) grafts following prolonged clinical use are acceptable, these figures are less satisfactory at lower flow rates [3]. Given the limitations with synthetic materials alone, a biological or biohybrid vascular prosthesis could provide us with the ideal blood vessel substitute.