Showing papers presented at "Biomedical Engineering International Conference in 2009"

Composite PLDLLA/TCP Scaffolds for Bone Engineering: Mechanical and In Vitro Evaluations

Abstract: Bone tissue engineering scaffolds have two challenging functional tasks to play; to be bioactive by encouraging cell proliferation and differentiation, and to provide suitable mechanical stability upon implantation. Composites of biopolymers and bioceramics unite the advantages of both materials resulting in better processibility, enhanced mechanical properties through matrix reinforcement and osteoinductivity. Novel composite blends of poly(L-lactide-co-D,L-lactide)/tricalcium phosphate (PLDLLA/TCP) were fabricated into scaffolds by an extrusion deposition technique customised from standard rapid prototyping technology. PLDLLA/TCP composite material blends of various compositions were prepared and analysed for their mechanical properties. PLDLLA/TCP (10%) was optimised and fabricated into scaffolds. Compressive mechanical properties for the composite scaffolds were performed. In vitro studies were conducted using porcine bone-marrow stromal cells (BMSCs). Cell-scaffold constructs were induced using osteogenic induction factors for up to 8 weeks. Cell proliferation, viability and differentiation capabilities were assayed using phase contrast light microscopy, scanning electron microscopy, PicoGreen DNA quantification, AlamarBlue metabolic assay; FDA/PI fluorescent assay and western blot analysis for osteopontin. Microscopy observations showed BMSCs possessed high proliferative capabilities and demonstrated bridging across the pores of the scaffolds. FDA/PI staining as well as AlamarBlue assay showed high viability of BMSCs cultured on the composite scaffolds Cell numbers, based on DNA quantitation, was observed to increase continuously up to the 8th week of study. Western blot analysis showed increased osteopontin synthesis on the scaffolds compared to tissue culture plastic. Based on our results the PLDLLA/TCP scaffolds exhibit good potential and biocompatibility for bone tissue engineering applications.

Knowledge Bases for Arterial Hypertension Strategy Selection: Development and Estimation

Abstract: Introduction. The information technologies give the possibility to formalize and structurize knowledge in the knowledge base (KB). Thus, knowledge is available for computer processing [1]. The two KB developed comprise the same knowledge amount: „New European Hypertension Guidelines, 2003”. Goal. To build two KB and computer systems for decision making on strategy concerning arterial hypertension (AH) patients and to compare them. Methods. Authors used rules and frames to formalize knowledge. Decision making are divided into three levels: 1. The lowest level: based on symptoms, the patients blood pressure (BP) class, risk factors (RF), number of target organ damage (TOD) and the AH-related clinical conditions (RCC) are detected. 2. The medium level: total risk is calculated. 3. The highest level: optimal AH strategy for the patient is determined. Figure 1 illustrates the decision making tree on the medium level for patient with blood pressure class A.