Gustavo Diaz scite author profile

Embedding microfluidic architectures with microneedles enables fluid management capabilities that present new degrees of freedom for transdermal drug delivery. To this end, fabrication schemes that can simultaneously create and integrate complex millimeter/centimeter-long microfluidic structures and micrometer-scale microneedle features are necessary. Accordingly, three-dimensional (3D) printing techniques are suitable candidates because they allow the rapid realization of customizable yet intricate microfluidic and microneedle features. However, previously reported 3D-printing approaches utilized costly instrumentation that lacked the desired versatility to print both features in a single step and the throughput to render components within distinct length-scales. Here, for the first time in literature, we devise a fabrication scheme to create hollow microneedles interfaced with microfluidic structures in a single step. Our method utilizes stereolithography 3D-printing and pushes its boundaries (achieving print resolutions below the full width half maximum laser spot size resolution) to create complex architectures with lower cost and higher print speed and throughput than previously reported methods. To demonstrate a potential application, a microfluidic-enabled microneedle architecture was printed to render hydrodynamic mixing and transdermal drug delivery within a single device. The presented architectures can be adopted in future biomedical devices to facilitate new modes of operations for transdermal drug delivery applications such as combinational therapy for preclinical testing of biologic treatments.

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Three-dimensional microscale hanging drop arrays with geometric control for drug screening and live tissue imaging

Ganguli

Mostafa

Trujillo

et al. 2021

Sci. Adv.

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Existing three-dimensional (3D) culture techniques are limited by trade-offs between throughput, capacity for high-resolution imaging in living state, and geometric control. Here, we introduce a modular microscale hanging drop culture where simple design elements allow high replicates for drug screening, direct on-chip real-time or high-resolution confocal microscopy, and geometric control in 3D. Thousands of spheroids can be formed on our microchip in a single step and without any selective pressure from specific matrices. Microchip cultures from human LN229 glioblastoma and patient-derived mouse xenograft cells retained genomic alterations of originating tumors based on mate pair sequencing. We measured response to drugs over time with real-time microscopy on-chip. Last, by engineering droplets to form predetermined geometric shapes, we were able to manipulate the geometry of cultured cell masses. These outcomes can enable broad applications in advancing personalized medicine for cancer and drug discovery, tissue engineering, and stem cell research.

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Light in the midst of chaos: COVID-19 and female political representation

Piazza

Diaz

2020

World Development

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The promotion of gender equality and the empowerment of women are global policy priorities across countries and development institutions. Research on gender and politics shows that exceptional environments can activate stereotypes of women as honest, trustworthy, and competent lawmakers in public health and, in doing so, can generate increased public support for female political candidates. We argue that the 2019–2020 Coronavirus Pandemic has the potential to produce this outcome, as recent public opinion polls highlight widespread discontent with male-led governments’ responses to the pandemic and elevated concerns surrounding public health. Recent positive media reports of female world leaders’ responses to the pandemic provide further reason to suspect a forthcoming increase in political support for female candidates. We posit that such an outcome may prove essential not only for enhancing development and improving long-standing gender inequities but also for alleviating the pandemic’s disproportionately allocated hardships.

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Gustavo Diaz

A 3D-printed microfluidic-enabled hollow microneedle architecture for transdermal drug delivery

Three-dimensional microscale hanging drop arrays with geometric control for drug screening and live tissue imaging

Light in the midst of chaos: COVID-19 and female political representation

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