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Articles 1 - 4 of 4
Full-Text Articles in Physics
Cell-Induced Confinement Effects In Soft Tissue Mechanics, Dawei Song, Jordan L. Shivers, Fred C. Mackintosh, Alison E. Patteson, Paul A. Janmey
Cell-Induced Confinement Effects In Soft Tissue Mechanics, Dawei Song, Jordan L. Shivers, Fred C. Mackintosh, Alison E. Patteson, Paul A. Janmey
Physics - All Scholarship
The mechanical properties of tissues play a critical role in their normal and pathophysiological functions such as tissue development, aging, injury, and disease. Understanding tissue mechanics is important not only for designing realistic biomimetic materials for tissue engineering and drug testing but also for developing novel diagnostic techniques and medical interventions. Tissues are heterogeneous materials consisting of cells confined within extracellular matrices (ECMs), both of which derive their structural integrity, at least in part, from networks of biopolymers. However, the rheology of purified reconstituted biopolymer networks fails to explain many key aspects of tissue mechanics. Notably, purified networks typically soften …
Raman Spectroscopy Of Oxygen Evolution Catalysts And Psii Manganese Model Compounds, Sergei Shmakov, Daniel A. Hartzler, Alireza Karbakhsh Ravari, Yulia Pushkar
Raman Spectroscopy Of Oxygen Evolution Catalysts And Psii Manganese Model Compounds, Sergei Shmakov, Daniel A. Hartzler, Alireza Karbakhsh Ravari, Yulia Pushkar
The Summer Undergraduate Research Fellowship (SURF) Symposium
Photosynthesis is the basis of life on earth, and oxygen evolution catalysts are key components of this complicated, yet not fully understood process. Photosystem II, a large membrane bound pigment-protein complex, is the key system that facilitates oxygenic photosynthesis via the oxygen evolving complex (a natural oxygen evolving catalyst). It is a key component in oxygen producing catalysts, which can be used in fields such as energy production and biomimetic catalysts. The oxygen evolution cycle, or Kok cycle going within it is still not studied completely. In this project, we were studying the vibrational (and structural) state of a Manganese …
Hiv Fusion Peptide Penetrates, Disorders, And Softens T-Cell Membrane Mimics., Stephanie Tristram-Nagle, Rob Chan, Edgar Kooijman, Pradeep Uppamoochikkal, Wei Qiang, David Weliky, Pradeep Uppamoochikkal
Hiv Fusion Peptide Penetrates, Disorders, And Softens T-Cell Membrane Mimics., Stephanie Tristram-Nagle, Rob Chan, Edgar Kooijman, Pradeep Uppamoochikkal, Wei Qiang, David Weliky, Pradeep Uppamoochikkal
Prof. Stephanie Tristram-Nagle Ph.D.
This work investigates the interaction of N-terminal gp41 fusion peptide (FP) of human immunodeficiency virus type 1 (HIV-1) with model membranes in order to elucidate how FP leads to fusion of HIV and T-cell membranes. FP constructs were (i) wild-type FP23 (23 N-terminal amino acids of gp41), (ii) water-soluble monomeric FP that adds six lysines on the C-terminus of FP23 (FPwsm), and (iii) the C-terminus covalently linked trimeric version (FPtri) of FPwsm. Model membranes were (i) LM3 (a T-cell mimic), (ii) 1,2-dioleoyl-sn-glycero-3-phosphocholine, (iii) 1,2-dioleoyl-sn-glycero-3-phosphocholine/30 mol% cholesterol, (iv) 1,2-dierucoyl-sn-glycero-3-phosphocholine, and (v) 1,2-dierucoyl-sn-glycero-3-phosphocholine/30 mol% cholesterol. Diffuse synchrotron low-angle x-ray scattering from fully …
Proton-Fountain Electric-Field-Assisted Nanolithography (Pen): Fabrication Of Polymer Nanostructures That Respond To Chemical And Electrical Stimuli. An Overview In The Context Of The Top-Down And Bottom-Up Approaches To Nanotechnology, Andres H. La Rosa, Mingdi Yan, Rodolfo Fernandez, Elia Zegarra
Proton-Fountain Electric-Field-Assisted Nanolithography (Pen): Fabrication Of Polymer Nanostructures That Respond To Chemical And Electrical Stimuli. An Overview In The Context Of The Top-Down And Bottom-Up Approaches To Nanotechnology, Andres H. La Rosa, Mingdi Yan, Rodolfo Fernandez, Elia Zegarra
Physics Faculty Publications and Presentations
The development of chemically functionalized materials, such that their physical properties can vary in response to external mechanical, chemical, or optical stimuli, offers potential applications in a wide range of fields, namely microfluidics, electronic memory devices, sensors and actuators. In particular, patterned structures built with stimuli-responsive polymer materials are attractive due to their inherent lower cost production and for building soft scaffolds that mimic closer natural bio-environments. In addition, harnessing the construction of patterns with nanoscale dimensions would not only a) allow building lab-on-a-chip devices that require minimal chemical reactants volumes, but also b) find applications in the area of …