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NHRI reports on 2009 Biomedical Research Symposium

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¥»¦¸·|ij¬°´Á¤G¤Ñ¡A¤W¤È®É¬q¦U³W¹º¤@³õPlenary Lecture¡C­º¤éÁܽЬü°ê¤Ç¯÷³ù¤j¾Ç°©¬ì°©Àf¦Ù¦×¬ã¨s¤¤¤ß/¥Íª«¤uµ{¨t±Ð±Â­J¬y·½°|¤h¥H¡uBioengineering and Its Importance in Keeping our Joints Healthy^µù2¡v¬°ÃDµoªíºt»¡¡F¦¸¤é¤W¤È«hÁܽХ»°|¤À¤l»P°ò¦]Âå¾Ç¬ã¨s²Õ¤ý³°®ü²Õ¥D¥ô¥H¡uMolecular Signaling Regulating Oncogenic Properties of Cancer Cells^µù3¡v¬°ÃDµoªíºt»¡¡C

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Bioengineering and Its Importance in Keeping Our Joints Healthy

Ligaments and tendons are parallel-fibered soft connective tissues that are well designed to resist tensile loads. They have unique nonlinear tensile properties. At low loads, their relatively low stiffness serves to stabilize and guide the diarthrodial joints to move smoothly. At higher loads, their stiffness increases, and thus, can help to limit excessive motion between the bones in order to protect other soft tissues in and around these joints from being damaged. Thus, ligaments and tendons play a very important role in keeping our joints healthy.

Unfortunately, injuries to ligaments and tendons occur frequently during work- and sports-related activities, and the incidence has increased over the last few decades. It is estimated that tendon injuries account for 30% to 50% of all sports-related injuries. Tendinopathies are so ubiquitous that they occur in over 48% of occupationally induced musculoskeletal ailments. The incidence of knee ligament injuries is estimated to be 2 in 1,000 people per year in the general population―translating to over 200,000 and 150,000 anterior cruciate ligament (ACL) and medial collateral ligament (MCL) tears per year, respectively, in the U.S alone. The same could be said about the tendons and ligaments in and around the shoulder.

Patients with tendon and ligament ailments demand quick return to work and sports.However, as investigators, physicians and, medical personnel are well-aware, these tissues heal and repair very slowly. As such,the healing ligaments and tendons lack the biomechanical properties to perform their normal function; thus, significantly elevating the potential of damaging other tissues,the articular cartilage, in particular. As a result, there is a dire need to better understand the normal function of tendons and ligaments, the mechanisms of their injuries, and the healing and remodeling processes in order to find better treatment strategies to accelerate their recovery.

In this lecture, we first present the fundamental work done during the last 40 years on the anatomy and biology of ligaments and tendons, as well as describing specially developed methodologies to accurately determine their biomechanical properties and function. We then highlight biological factors that would cause changes to tissue properties in-vivo. To complete the picture, we include the importance of their time- and history-dependent properties based on Professor Y.C. Fung's quasi-linear viscoelastic theory.

It can be easily visualized that the field of biomechanics has made great strides in better understanding the function of ligaments and tendons as well as in finding new and improved treatment of their injuries. As a result, many patients have benefited. Examples on how to better treat a complete tear of the MCL of the knee, as well as how to improve ACL reconstruction procedures by means of robotics technology are presented in detail. With the advent of functional tissue engineering, the use of growth factor and cytokines as well as cells for ligament and tendon healing are interesting and timely topics to be discussed. In addition, the use of biological scaffolds (e.g. extracellular matrix (ECM) bioscaffolds, such as porcine small intestinal submucosa) have shown translational potential and examples of how they may be applied to improve the healing and regeneration of the MCL and the patellar tendon (PT) are presented. Finally, novel ECM hydrogels that can retain important bioactive agents have been fabricated and injected and used together with ECM bioscaffolds to act synergistically as a biological augmentation to successfully heal the ACL; thus, providing a novel approach for treatment of the most serious problem in orthopaedic sports medicine.

In our research center, in-vitro cyclic stretching and cell seeding of ECM bioscaffolds have been utilized to produce better aligned neo-collagen. Novel processing techniques, including electrospinning, can be used to synthesize bioscaffolds with highly aligned fiber morphology―an optimal structure to promote enhanced ligament and tendon healing. For the future, we have identified exciting areas in molecular and cellular bioengineering that would further enhance our knowledge on the mechanism of healing of these tissues, and therefore, bringing tissue regeneration within the realm of possibility.

It is also time to move our focus towards in-vivo studies to better understand the injury mechanisms of ligaments and tendons. As it is possible to use biplanar fluoroscopy to collect in-vivo kinematics data to within 0.1 mm & 0.1¢X accuracy, we can reproduce these data on cadaveric knees utilizing the robotic/UFS testing system to learn about the in-situ forces in these tissues. Moreover, in-vivo kinematics can be integrated into computational models to calculate the in-situ forces in the same tissues. Once the computational models are validated, they can be used to predict the function of ligaments and tendons under more complex external loading conditions, to better understand their injury mechanisms and to properly evaluate new and improved treatment procedures on a scientific basis.

Thus, it is easy to see that ligament and tendon research has reached an exciting period of time. On the other hand, we must recognize that there is still a long way to go. Translating molecular and cellular responses to in-vivo conditions and clinical applications will take hard work and ingenuity as the biology is extremely complex. We suggest that it will require an interdisciplinary and multidisciplinary research team to work together to accomplish these goals. We are optimistic that many biologists, biochemists, clinicians, bioengineers and other scientific disciplines (i.e. mathematicians, statisticians, immunologists, and so on) recognize the need to work together in a seamless manner to find new ways to regenerate injured ligaments and tendons to their normal state so that patients will be able to resume their normal daily as well as sports activities while keeping their joints healthy.

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Molecular Signaling Regulating Oncogenic Properties of Cancer Cells

The purpose of this study is to explore the genes and signaling pathways important for regulating various oncogneic properties of cancer cells with emphasis on their survival and invasive abilities. For this purpose, we selected from low invasive human breast cancer lines MCF-7 and MDA-MB453 to derive their respective highly invasive lines. Those pairs of lines were subjected to cDNA and miRNA array analysis, as well as comparison of various signaling pathways known to be relevant for oncogenic properties of tumor cells. Among the genes shown to be differentially expressed or activated, we observed increased expression of Twist and AKT2, as well as activation of STAT3 in the invasive but not in the parental lines. Co-expression of these molecules was further examined for signaling and functional linkage. Our results indicated that STAT3 bound to Twist promoter and activated its transcription, Twist in turn bound to AKT2 promoter to activate AKT2 transcription. The STAT3-Twist-AKT2 signaling axis plays an important role in regulating breast cancer cell anchorage independent growth, migration/invasion and resistance to paclitaxel. Co-expression of Twist and AKT2 as well as increased P-STAT3 and Twist was found in most of the late stage breast cancer specimens. Furthermore, a number of miRNAs were found to be differentially expressed in the parental and invasive cells. Their functional significance and potential target genes relevant to maintenance of the oncogenic properties are being investigated.

In conclusion, we have identified STAT3-Twist-AKT2 signaling pathway to be important in regulating invasion and survival of breast cancer cells, and these molecules could serve as the prognosis markers and potential drug targets for cancer treatment.
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