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2. Potential for Chemistry in Multidisciplinary, Interdisciplinary, and Transdisciplinary Teaching Activities in Higher Education

Author

Hardy, John G., Sdepanian, Stephanie, Stowell, Alison F., Aljohani, Amal D., Allen, Michael J., Anwar, Ayaz, Barton, Dik, Baum, John V., Bird, David, Blaney, Adam, Brewster, Liz, Cheneler, David, Efremova, Olga, Entwistle, Michael, Esfahani, Reza N., Firlak, Melike, Foito, Alex, Forciniti, Leandro, Geissler, Sydney A., Guo, Feng, Hathout, Rania M., Jiang, Richard, Kevin, Punarja, Leese, David, Low, Wan Li, Mayes, Sarah, Mozafari, Masoud, Murphy, Samuel T., Nguyen, Hieu, Ntola, Chifundo N. M., Okafo, George, Partington, Adam, Prescott, Thomas A. K., Price, Stephen P., Soliman, Sherif, Sutar, Papri, Townsend, David, Trotter, Patrick, and Wright, Karen L.

Abstract

For some professionally, vocationally, or technically oriented careers, curricula delivered in higher education establishments may focus on teaching material related to a single discipline. By contrast, multidisciplinary, interdisciplinary, and transdisciplinary teaching(MITT) results in improved affective and cognitive learning and critical thinking, offering learners/students the opportunity to obtain a broad general knowledge base. Chemistry is a discipline that sits at the interface of science, technology, engineering, mathematics, and medicine(STEMM) subjects (and those aligned with or informed by STEMM subjects). This article discusses the significant potential of inclusion of chemistry in MITT activities in higher education and the real-world importance in personal, organizational, national, and global contexts. It outlines the development and implementation challenges attributed to legacy higher education infrastructures (that call for creative visionary leadership with strong and supportive management and administrative functions), and curriculum design that ensures inclusivity and collaboration and is pitched and balanced appropriately. It concludes with future possibilities, notably highlighting that chemistry, as a discipline, underpins industries that have multibillion dollar turnovers and employ millions of people across the world.

Published
2021
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5. Potential for Chemistry in Multidisciplinary, Interdisciplinary, and Transdisciplinary Teaching Activities in Higher Education

Author

Hardy, John, Sdepanian, Stephanie, Stowell, Alison, Aljohani, Amal, Allen, Michael, Anwar, Ayaz, Barton, Dik, Baum, John, Bird, David, Blaney, Adam, Brewster, Liz, Cheneler, David, Efremova, Olga, Entwistle, Michael, Esfahani, Reza, Firlak, Melike, Foito, Alex, Forciniti, Leandro, Geissler, Sydney, Guo, Feng, Hathout, Rania, Jiang, Richard, Kevin, Punarja, Leese, David, Low, Wan Li, Mayes, Sarah, Mozafari, Masoud, Murphy, Samuel, Nguyen, Hieu, Ntola, Chifundo, Okafo, George, Partington, Adam, Prescott, Thomas, Price, Stephen, Soliman, Sherif, Sutar, Papri, Townsend, David, Trotter, Patrick, Wright, Karen, Hardy, John, Sdepanian, Stephanie, Stowell, Alison, Aljohani, Amal, Allen, Michael, Anwar, Ayaz, Barton, Dik, Baum, John, Bird, David, Blaney, Adam, Brewster, Liz, Cheneler, David, Efremova, Olga, Entwistle, Michael, Esfahani, Reza, Firlak, Melike, Foito, Alex, Forciniti, Leandro, Geissler, Sydney, Guo, Feng, Hathout, Rania, Jiang, Richard, Kevin, Punarja, Leese, David, Low, Wan Li, Mayes, Sarah, Mozafari, Masoud, Murphy, Samuel, Nguyen, Hieu, Ntola, Chifundo, Okafo, George, Partington, Adam, Prescott, Thomas, Price, Stephen, Soliman, Sherif, Sutar, Papri, Townsend, David, Trotter, Patrick, and Wright, Karen

Abstract

For some professionally, vocationally, or technically oriented careers, curricula delivered in higher education establishments may focus on teaching material related to a single discipline. By contrast, multidisciplinary, interdisciplinary, and transdisciplinary teaching (MITT) results in improved affective and cognitive learning and critical thinking, offering learners/students the opportunity to obtain a broad general knowledge base. Chemistry is a discipline that sits at the interface of science, technology, engineering, mathematics, and medicine (STEMM) subjects (and those aligned with or informed by STEMM subjects). This article discusses the significant potential of inclusion of chemistry in MITT activities in higher education and the real-world importance in personal, organizational, national, and global contexts. It outlines the development and implementation challenges attributed to legacy higher education infrastructures (that call for creative visionary leadership with strong and supportive management and administrative functions), and curriculum design that ensures inclusivity and collaboration and is pitched and balanced appropriately. It concludes with future possibilities, notably highlighting that chemistry, as a discipline, underpins industries that have multibillion dollar turnovers and employ millions of people across the world.

Published
2021

7. Neurons differentiate magnitude and location of mechanical stimuli

Author

Gaub, Benjamin M., primary, Kasuba, Krishna Chaitanya, additional, Mace, Emilie, additional, Strittmatter, Tobias, additional, Laskowski, Pawel R., additional, Geissler, Sydney A., additional, Hierlemann, Andreas, additional, Fussenegger, Martin, additional, Roska, Botond, additional, and Müller, Daniel J., additional

Published
2019
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9. A Multi-Functional Microelectrode Array Featuring 59760 Electrodes, 2048 Electrophysiology Channels, Stimulation, Impedance Measurement and Neurotransmitter Detection Channels

Author

Dragas, Jelena, Viswam, Vijay, Shadmani, Amir, Chen, Yihui, Bounik, Raziyeh, Stettler, Alexander, Radivojevic, Milos, Geissler, Sydney, Obien, Marie, Müller, Jan, and Hierlemann, Andreas

Subjects
Article
Abstract

Biological cells are characterized by highly complex phenomena and processes that are, to a great extent, interdependent. To gain detailed insights, devices designed to study cellular phenomena need to enable tracking and manipulation of multiple cell parameters in parallel; they have to provide high signal quality and high spatiotemporal resolution. To this end, we have developed a CMOS-based microelectrode array system that integrates six measurement and stimulation functions, the largest number to date. Moreover, the system features the largest active electrode array area to date (4.48×2.43 mm2) to accommodate 59,760 electrodes, while its power consumption, noise characteristics, and spatial resolution (13.5 μm electrode pitch) are comparable to the best state-of-the-art devices. The system includes: 2,048 action-potential (AP, bandwidth: 300 Hz to 10 kHz) recording units, 32 local-field-potential (LFP, bandwidth: 1 Hz to 300 Hz) recording units, 32 current recording units, 32 impedance measurement units, and 28 neurotransmitter detection units, in addition to the 16 dual-mode voltage-only or current/voltage-controlled stimulation units. The electrode array architecture is based on a switch matrix, which allows for connecting any measurement/stimulation unit to any electrode in the array and for performing different measurement/stimulation functions in parallel.

Published
2017

13. Electrical stimulation of human mesenchymal stem cells on biomineralized conducting polymers enhances their differentiation towards osteogenic outcomes

Author

Hardy, John G., Sukhavasi, Rushi C., Aguilar, David, Villancio-Wolter, Maria K., Mouser, David J., Geissler, Sydney A., Nguy, Lindsey, Chow, Jacqueline K., Kaplan, David L., Schmidt, Christine E., Hardy, John G., Sukhavasi, Rushi C., Aguilar, David, Villancio-Wolter, Maria K., Mouser, David J., Geissler, Sydney A., Nguy, Lindsey, Chow, Jacqueline K., Kaplan, David L., and Schmidt, Christine E.

Abstract

Tissue scaffolds allowing the behaviour of the cells that reside on them to be controlled are of particular interest for tissue engineering. Herein we describe biomineralized conducting polymer-based bone tissue scaffolds that facilitate the electrical stimulation of human mesenchymal stem cells, resulting in enhancement of their differentiation towards osteogenic outcomes.

Published
2015

14. Conducting polymer-based multilayer films for instructive biomaterial coatings

Author

Hardy, John George, Li, Hetian, Chow, Jacqueline K., Geissler, Sydney, McElroy, Austin, Nguy, Lindsey, Hernandez, Derek S., Schmidt, Christine E, Hardy, John George, Li, Hetian, Chow, Jacqueline K., Geissler, Sydney, McElroy, Austin, Nguy, Lindsey, Hernandez, Derek S., and Schmidt, Christine E

Abstract

Aim: To demonstrate the design, fabrication and testing of conformable conducting biomaterials that encourage cell alignment. Materials & methods: Thin conducting composite biomaterials based on multilayer films of poly (3,4-ethylenedioxythiophene) derivatives, chitosan and gelatin were prepared in a layer-by-layer fashion. Fibroblasts were observed with fluorescence microscopy and their alignment (relative to the dipping direction and direction of electrical current passed through the films) was determined using ImageJ. Results: Fibroblasts adhered to and proliferated on the films. Fibroblasts aligned with the dipping direction used during film preparation and this was enhanced by a DC current. Conclusion: We report the preparation of conducting polymer-based films that enhance the alignment of fibroblasts on their surface which is an important feature of a variety of tissues. Lay abstract: Cells inhabit environments known as the extracellular matrix (ECM) which consists of a mixture of different biomolecules, and the precise composition and topographical properties are different in different tissues (e.g., bone, brain, muscle, skin). Cells interact intimately with the ECM, not only constructing the biomolecules, but assist its organization in 3D space, and its degradation (which is important for tissue remodeling); reciprocally, cells respond to the ECM (e.g., by modifying their size, shape, etc). Cellular alignment is observed in organs and tissues such as bones, muscles and skin, and this alignment is important for the healthy functioning of the organ/tissue. Here, we present a novel method of aligning cells on biomaterials, simply by applying an electrical current through the biomaterial.

Published
2015

15. Electrical stimulation of human mesenchymal stem cells on conductive nanofibers enhances their differentiation toward osteogenic outcomes

Author

Hardy, John, Villancio-Wolter, Maria, Sukhavasi, Rushi, Mouser, David, Aguilar, David, Geissler, Sydney, Kaplan, David, Schmidt, Christine, Hardy, John, Villancio-Wolter, Maria, Sukhavasi, Rushi, Mouser, David, Aguilar, David, Geissler, Sydney, Kaplan, David, and Schmidt, Christine

Abstract

Tissue scaffolds allowing the behaviour of the cells that reside within them to be controlled are of particular interest for tissue engineering. Herein we describe the preparation of conductive fiber-based bone tissue scaffolds (nonwoven mats of electrospun polycaprolactone with an interpenetrating network of polypyrrole and polystyrenesulfonate) that enable the electrical stimulation of human mesenchymal stem cells to enhance their differentiation towards osteogenic outcomes.

Published
2015

16. Instructive conductive 3D silk foam-based bone tissue scaffolds enable electrical stimulation of stem cells for enhanced osteogenic differentiation

Author

Hardy, John G., Geissler, Sydney A., Aguilar Jr., David, Villancio-Wolter, Maria K., Mouser, David J., Sukhavasi, Rushi C., Cornelison, R. Chase, Tien, Lee W., Preda, R. Carmen, Hayden, Rebecca S., Chow, Jacqueline K., Nguy, Lindsey, Kaplan, David L., Schmidt, Christine E., Hardy, John G., Geissler, Sydney A., Aguilar Jr., David, Villancio-Wolter, Maria K., Mouser, David J., Sukhavasi, Rushi C., Cornelison, R. Chase, Tien, Lee W., Preda, R. Carmen, Hayden, Rebecca S., Chow, Jacqueline K., Nguy, Lindsey, Kaplan, David L., and Schmidt, Christine E.

Abstract

Stimuli-responsive materials enabling the behaviour of the cells that reside within them to be controlled are vital for the development of instructive tissue scaffolds for tissue engineering. Herein we describe the preparation of conductive silk foam-based bone tissue scaffolds that enable the electrical stimulation of human mesenchymal stem cells to enhance their differentiation towards osteogenic outcomes.

Published
2015

17. Peptide-directed assembly of functional supramolecular polymers for biomedical applications: electroactive molecular tongue-twisters (oligoalanine-oligoaniline-oligoalanine) for electrochemically enhanced drug delivery

Author

Hardy, John G., Amend, Megan N., Geissler, Sydney, Lynch, Vincent M., Schmidt, Christine E., Hardy, John G., Amend, Megan N., Geissler, Sydney, Lynch, Vincent M., and Schmidt, Christine E.

Abstract

We report the preparation and characterization of films of electroactive supramolecular polymers based on non-electroactive oligoalanines and electroactive oligoanilines. Fibroblasts adhered to and proliferated on the films, and the delivery of the clinically relevant anti-inflammatory drug dexamethasone phosphate could be enhanced upon the application of an electrical stimulus.

Published
2015

19. Macromol. Rapid Commun. 21/2015

Author

Hardy, John G., primary, Villancio-Wolter, Maria K., additional, Sukhavasi, Rushi C., additional, Mouser, David J., additional, Aguilar, David, additional, Geissler, Sydney A., additional, Kaplan, David L., additional, and Schmidt, Christine E., additional

Published
2015
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21. Instructive Conductive 3D Silk Foam‐Based Bone Tissue Scaffolds Enable Electrical Stimulation of Stem Cells for Enhanced Osteogenic Differentiation

Author

Hardy, John G., primary, Geissler, Sydney A., additional, Aguilar, David, additional, Villancio‐Wolter, Maria K., additional, Mouser, David J., additional, Sukhavasi, Rushi C., additional, Cornelison, R. Chase, additional, Tien, Lee W., additional, Preda, R. Carmen, additional, Hayden, Rebecca S., additional, Chow, Jacqueline K., additional, Nguy, Lindsey, additional, Kaplan, David L., additional, and Schmidt, Christine E., additional

Published
2015
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22. Electrical stimulation of human mesenchymal stem cells on biomineralized conducting polymers enhances their differentiation towards osteogenic outcomes

Author

Hardy, John G., primary, Sukhavasi, Rushi C., additional, Aguilar, David, additional, Villancio-Wolter, Maria K., additional, Mouser, David J., additional, Geissler, Sydney A., additional, Nguy, Lindsey, additional, Chow, Jacqueline K., additional, Kaplan, David L., additional, and Schmidt, Christine E., additional

Published
2015
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24. Biodegradable electroactive polymers for electrochemically-triggered drug delivery

Author

Hardy, John G., Mouser, David J., Arroyo-Currás, Netzahualcóyotl, Geissler, Sydney, Chow, Jacqueline K., Nguy, Lindsey, Kim, Jong M., Schmidt, Christine E., Hardy, John G., Mouser, David J., Arroyo-Currás, Netzahualcóyotl, Geissler, Sydney, Chow, Jacqueline K., Nguy, Lindsey, Kim, Jong M., and Schmidt, Christine E.

Abstract

We report biodegradable electroactive polymer (EAP)-based materials and their application as drug delivery devices. Copolymers composed of oligoaniline-based electroactive blocks linked to either polyethylene glycol or polycaprolactone blocks via ester bonds were synthesized in three steps from commercially available starting materials and isolated without the need for column chromatography. The physicochemical and electrochemical properties of the polymers were characterized with a variety of techniques. The ability of the polymers to deliver the anti-inflammatory drug dexamethasone phosphate on the application of electrochemical stimuli was studied spectroscopically. Films of the polymers were shown to be degradable and cell adhesive in vitro. Such EAP-based materials have prospects for integration in implantable fully biodegradable/bioerodible EAP-based drug delivery devices that are capable of controlling the chronopharmacology of drugs for future clinical application.

Published
2014

30. Electrical stimulation of human mesenchymal stem cells on biomineralized conducting polymers enhances their differentiation towards osteogenic outcomes.

Author

Villancio-Wolter, Maria K., Geissler, Sydney A., Schmidt, Christine E., Hardy, John G., Sukhavasi, Rushi C., Aguilar, David, Mouser, David J., Nguy, Lindsey, Chow, Jacqueline K., and Kaplan, David L.

Abstract

Tissue scaffolds allowing the behaviour of the cells that reside on them to be controlled are of particular interest for tissue engineering. Herein we describe biomineralized conducting polymer-based bone tissue scaffolds that facilitate the electrical stimulation of human mesenchymal stem cells, resulting in enhancement of their differentiation towards osteogenic outcomes. [ABSTRACT FROM AUTHOR]

Published
2015
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31. Natural biomaterials for enhanced oligodendrocyte differentiation and spinal cord injury repair

Author

Geissler, Sydney Amelia

Subjects
Biomaterial, Hydrogel, Spinal cord injury, Progenitor cell, Functional recovery
Abstract

Spinal cord injury is a devastating source of suffering in the spectrum of human pathophysiology; advancement for clinical therapy in this area has been stagnant in comparison to modern medical development. Current treatments are palliative, and functional recovery is minimal. During the first two weeks after injury, dense glial scar forms that is impenetrable by regenerating axons. Intervention is imperative to minimize scar formation and provide a supportive environment for axonal regeneration. Oligodendrocytes are critical to maintain the health of growing axons during development and after injury. Obtaining these cells through differentiation of neural progenitor cells (NPCs) is a viable option, but current clinical trials involving stem cells are plagued by poor cell survival and undirected differentiation. Research indicates that local extracellular matrix (ECM) is vital to progenitor differentiation and tissue regeneration. During development, spinal cord ECM is comprised of high concentrations of laminin and hyaluronic acid (HA), which provide essential cues to direct NPC migration and differentiation. The purpose of this research is to create a biomaterial optimized to direct NPC differentiation to oligodendrocytes. Natural biomaterials were optimized from distinct combinations of collagen I, HA, and laminin I to model the native ECM signals found during oligodendrocyte maturation. Four material combinations (collagen, collagen-HA-laminin, collagen-HA, and collagen-laminin) were fabricated into injectable hydrogels to mimic the range of compressive and shear mechanical properties present in neonatal central nervous system (CNS) tissue. Differentiation was assessed by culturing rodent fetal NPCs in these materials without specific soluble factors to direct cellular behavior. The three-component hydrogel performed optimally and achieved a 66% oligodendrocyte differentiation rate compared to approximately 15% in the collagen alone hydrogel. An in vivo study was then conducted using a rat contusion model of spinal cord injury with intervention using the injectable, three-component hydrogel seeded with rat NPCs. Functional recovery was assessed using six behavioral tests. Significant recovery was observed using two behavioral tests six weeks post-treatment. Lesion size was measured and correlated well with behavioral outcomes. The data obtained in this research indicate that a multi-component hydrogel mimicking native, developmental CNS tissue may address problems associated with current clinical practice.

Published
2014

32. Rodent Models and Behavioral Outcomes of Cervical Spinal Cord Injury.

Author

Geissler SA, Schmidt CE, and Schallert T

Abstract

Rodent spinal cord injury (SCI) models have been developed to examine functional and physiological deficits after spinal cord injury with the hope that these models will elucidate information about human SCI. Models are needed to examine possible treatments and to understand histopathology after SCI; however, they should be considered carefully and chosen based on the goals of the study being performed. Contusion, compression, transection, and other models exist and have the potential to reveal important information about SCI that may be related to human SCI and the outcomes of treatment and timing of intervention.

Published
2013
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