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Full-Text Articles in Biomedical Engineering and Bioengineering
Development Of Peritoneal Microbubble Oxygenation As An Extrapulmonary Treatment For Hypoxia, Nathan Legband
Development Of Peritoneal Microbubble Oxygenation As An Extrapulmonary Treatment For Hypoxia, Nathan Legband
Department of Mechanical and Materials Engineering: Dissertations, Theses, and Student Research
Patients affected by a respiratory disease or injury experience a substantially impaired respiratory system and as a consequence are unable to obtain a sufficient amount of oxygen. Hypoxia can quickly result in developing permanent tissue damage or death. Currently, the medical methods of treating hypoxia are mechanical ventilation or extracorporeal membrane oxygenation. However, these treatments are ineffective in certain cases and possess significant additional risks including barotrauma, infection, hemorrhage, and thrombosis.
The extrapulmonary method of peritoneal oxygenation has been investigated by other research groups as a potential alternative to providing supplemental oxygen in hypoxic animals. In peritoneal oxygenation, the peritoneum, …
Design And Validation Of An In Vivo Long-Term Attachment Capsule Robot, Wanchuan Xie
Design And Validation Of An In Vivo Long-Term Attachment Capsule Robot, Wanchuan Xie
Department of Mechanical and Materials Engineering: Dissertations, Theses, and Student Research
The invention of capsule endoscopy (CE) made the non-invasive monitoring of the entire small bowel possible and became the primary means for diagnosing small bowel pathology. In the last decade, capsule robots have been transformed from diagnostic devices into a widely studied biomedical platform with the potential for active locomotion, drug delivery and therapeutic capabilities. To perform accurate on-site drug release and therapy, it is necessary for a capsule robot to be able to attach to the intestinal tissue and maintain its position long-term. Design challenges derive from the task of long-term mucosal adhesion which requires firm, quick-response attachment without …
A Novel Biochamberfor Modeling Of Atherosclerotic Arteries: In-Vitro Capabilities And Applications, Iman Salafian, Angelos Karagiannis, Benjamin S. Terry, Yiannis S. Chatzizisis
A Novel Biochamberfor Modeling Of Atherosclerotic Arteries: In-Vitro Capabilities And Applications, Iman Salafian, Angelos Karagiannis, Benjamin S. Terry, Yiannis S. Chatzizisis
Department of Mechanical and Materials Engineering: Dissertations, Theses, and Student Research
Atherosclerosis is a chronic disease that involves the lipid accumulation and inflammation of the arterial wall [1,2]. Despite great efforts,its pathophysiology has not been fully elucidated. Existent drugs can reduce its progression but there are no available drugs to prevent its complications [3,4]. Atherosclerosis remains the leading global cause of death[5].
The purpose of this work is to design and build a customized biochamber which can be used for the following studies:
•Study the pathophysiology of atherosclerosis in vitro & ex vivo
•Investigate the mechanisms of atherosclerotic plaque disruption
•Examine the direct effect of different anti-atherosclerotic drugs on lesions
•Use …
Repair And Regeneration Of Chondral Defects: An In Vitro Study Demonstrating Feasibility And Mechanism Under Low Intensity Ultrasound, Neety Sahu, Anuradha Subramanian
Repair And Regeneration Of Chondral Defects: An In Vitro Study Demonstrating Feasibility And Mechanism Under Low Intensity Ultrasound, Neety Sahu, Anuradha Subramanian
Department of Chemical and Biomolecular Engineering: Theses and Student Research
Holistic repair of damaged cartilage remains an unsolved biomedical problem. Current methods that employ microfracture (MF) or autologous chondrocyte implantation (ACT) or tissue engineered strategies yield inferior repaired cartilage (Fig. 1). Lack of chondroinductive factors at the site of injury, in vivo, has been identified as a factor that limits repair. Clinically amenable strategies that can improve repair are desired. A novel clinically translatable repair strategy based on low-intensity-ultrasound (US) is proposed (Fig.2). Differently from all approaches that use US, our approach employs US at the cell resonant frequency where bioeffects are maximized. We have shown that US impacts the …