Biomedical Engineering and Bioengineering Commons^™

Diagnostic Sequence Detection Against A Complex Background Using A Dna Molecular Computation Framework, Adan Leon Myers Y Gutierrez

Nanoscience and Microsystems ETDs

Diagnostic assays are designed to detect a unique analyte profile in a disease of interest. Nucleic acids contain an information-dense sequence, and thus are ideal candidates for unique analytes. The gold-standard of nucleic-acid-based detection is PCR which has high sensitivity, but involves time, expertise, and cost. DNA molecular logic technology holds much promise as an alternative molecular detection method due to the potential to save cost and expertise, while also achieving a high sensitivity. However, nucleic acid detection in biomedical applications carries with it the difficulty of choice of appropriate sequence and potential biological sample background.

This work describes the …

Incorporation Of Egfr And Ron Receptors Into Nanodiscs, Cristina Flores-Cadengo

Biomedical Engineering ETDs

Understanding the structure-function relationship of membrane receptors is essential to comprehend the crosstalk between key signaling pathways. Aberrant trans-activation between receptors can lead to tumorigenesis. Two of these receptors known to be involved in cancer development are receptor tyrosine kinases (RTKs), RON (Recepteur d'Origine Nantais) and EGFR (Epidermal Growth Factor Receptor). There has been evidence of heterodimerization and crosstalk between these two receptors based on co-immunoprecipitation, however the structural requirements behind these interactions remain unknown. Structural studies could provide insights into these RTKs’ modes of dimerization and structure-function relationship. However, structural studies of full-length membrane proteins are often difficult due …

The Effect Of Defects And Surface Modification On Biomolecular Assembly And Transport, Haneen Martinez

Nanoscience and Microsystems ETDs

Nanoscale transport using the kinesin-microtubule (MT) biomolecular system has been successfully used in a wide range of nanotechnological applications including self-assembly, nanofluidic transport, and biosensing. Most of these applications use the ‘gliding motility geometry’, in which surface-adhered kinesin motors attach and propel MT filaments across the surface, a process driven by ATP hydrolysis. It has been demonstrated that active assembly facilitated by these biomolecular motors results in complex, non-equilibrium nanostructures currently unattainable through conventional self-assembly methods. In particular, MTs functionalized with biotin assemble into rings and spools upon introduction of streptavidin and/or streptavidin-coated nanoparticles. Upon closer examination of these structures …