Vikas Dhawan

Tissue engineering of an implantable bioartificial hemofilter

The first step in the tissue engineering of an implantable bioartificial kidney is the development of an implant that produces ultrafiltrate to replace glomerular function. A fabricated device containing synthetic hollow hemofiltration fibers was placed around the femoral vascular pedicle in rats, which initiated new tissue formation with a mature and durable neocapillary bed. The transudate fluid produced by this newly formed capillary bed accumulated through the hollow fibers into a subcutaneous port to allow evaluation of the fluid. In its first phase, this study evaluated various hollow fibers and tissue induction processes by the measurement of fluid volume, urea nitrogen, and total protein continuously for 6 weeks. New tissues formed within the implants surrounding the fibers, and the vascular density, vessel sizes, and percent cross-sectional vascular area were assessed by means of histomorphometric analysis after 6 weeks. The volume of fluid formation correlated with both vascular density and fiber membrane surface area. The implant fluid-to-serum ratios demonstrated a permselective filtrate. In a second phase, platelet-derived growth factor and vascular endothelial growth factor versus carrier alone were infused directly into the implants for the first 4 weeks in vivo through osmotic pumps and followed up to 9 weeks. Cumulative implant fluid volumes were significantly greater in the growth factor–treated group than in control animals and were associated with greater numbers of small-caliber blood vessels. These results provide the initial proof of concept in developing a tissue-engineered hemofilter prototype on a small scale in a rodent model.

Force Characteristics of In Vivo Tissue-engineered Myocardial Constructs Using Varying Cell Seeding Densities

Experiments have been successfully performed culminating in functional, vascularized, three-dimensional cardiac muscle tissue. Past experience in tissue engineering has led us to the understanding that cell seeding density plays a critical role in the formation and function of both in vitro and in vivo engineered tissues. Therefore, to improve upon the mechanics of this model and to facilitate the formation of myocardial tissue with improved functional performance, we sought to optimize the seeding density of cardiomyocytes in these constructs. Neonatal cardiac myocytes were isolated from 2-day-old Fischer 344 rat hearts. Silicone chambers containing fibrin gel were seeded with varying numbers of cardiac cells (1, 5, 10, and 20 million). Control chambers were prepared using fibrin gel alone. All of the chambers were then implanted around the femoral vessels of isogenic rats. Six constructs per cell seeding density group were implanted. Histological and immunohistochemical evaluation was performed via hematoxylin and eosin, von Gieson, and alpha-sarcomeric actin staining protocols. Linear contractile force measurements were obtained for each construct following 4 weeks of in vivo implantation. After an implantation period of 4 weeks, the newly formed cardiac constructs contained within the chambers were harvested. The femoral vessels within the constructs were found to be patent in all cases. With direct electrical stimulation, the constructs were able to generate an average active force that varied depending on their seeding density. Constructs with seeding densities of 1, 5, 10, and 20 million cells produced an average active force of 208, 241, 151, and 108 microN, respectively. The control constructs did not generate any active force on electrical stimulation. This study demonstrates the in vivo survival, vascularization, organization, and function of transplanted myocardial cells. It is also apparent that cell seeding density plays a direct role in the force generation and mechanical properties of these engineered constructs. Among different groups using varying cell seeding densities, we found that the group with 5 million cells generated maximum active force.