Donald M. Cannon scite author profile

The extension of microfluidic devices to include three-dimensional fluidic networks allows complex fluidic and chemical manipulations but requires innovative methods to interface fluidic layers. Externally controllable interconnects, employing nuclear track-etched polycarbonate membranes containing nanometer-diameter capillaries, are described that produce hybrid three-dimensional fluidic architectures. Controllable nanofluidic transfer is achieved by controlling applied bias, polarity, and density of the immobile nanopore surface charge and the impedance of the nanocapillary array relative to the microfluidic channels. Analyte transport between vertically separated microchannels has three stable transfer levels, corresponding to zero, reverse, and forward bias. The transfer can even depend on the properties of the analyte being transferred such as the molecular size, illustrating the flexible character of the analyte transfer. In a specific analysis implementation, nanochannel array gating is applied to capillary electrophoresis separations, allowing selected separated components to be isolated for further manipulation, thereby opening the way for preparative separations at attomole analyte mass levels.

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Hybrid three-dimensional nanofluidic/microfluidic devices using molecular gates

Kuo

Cannon

Shannon

et al. 2003

Sensors and Actuators A: Physical

124

146

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Molecule Specific Imaging of Freeze-Fractured, Frozen-Hydrated Model Membrane Systems Using Mass Spectrometry

et al. 2000

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Imaging time-of-flight secondary ion mass spectrometry is used to chemically resolve the spatial distribution of lipids in submicrometer sections of phospholipid membranes. The results show that it is possible to unravel dynamical events such as chemical fluctuations associated with domain structure in cellular membranes. In this work, a liposome model system has been used to capture the stages of membrane fusion between two merging bilayer systems. Fracturing criteria for preserving chemical distributions are shown to be much more stringent than morphological electron cryomicroscopy studies. Images of membrane heterogeneity, induced via mixing various liposomes followed by fast freezing, demonstrate the necessary sample preparation groundwork to investigate complex, heterogeneous membrane domains. Clear delineation of membrane structure provides direct evidence that specific domains or “rafts” can exist. Moreover, low concentrations of each phospholipid are distributed throughout newly fused liposomes despite the existence of distinct domains. In the liposome model, membrane structure ranges from specific domains to a fluid mosaic of the phospholipids during the fusion event. The availability of mass spectrometric imaging is proposed to facilitate the discovery of functional rafts or substructure in cell membranes before, during, and after events including cell division, exocytosis, endocytosis, intracellular transport, infection of membrane-bound viruses, and receptor clustering. This technology holds the promise to define the biology of cell membranes at the molecular level.

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Dose-Limiting Toxicity After Hypofractionated Dose-Escalated Radiotherapy in Non–Small-Cell Lung Cancer

Cannon

Mehta

Adkison

et al. 2013

JCO

133

101

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A B S T R A C T PurposeLocal failure rates after radiation therapy (RT) for locally advanced non-small-cell lung cancer (NSCLC) remain high. Consequently, RT dose intensification strategies continue to be explored, including hypofractionation, which allows for RT acceleration that could potentially improve outcomes. The maximum-tolerated dose (MTD) with dose-escalated hypofractionation has not been adequately defined. Patients and MethodsSeventy-nine patients with NSCLC were enrolled on a prospective single-institution phase I trial of dose-escalated hypofractionated RT without concurrent chemotherapy. Escalation of dose per fraction was performed according to patients' stratified risk for radiation pneumonitis with total RT doses ranging from 57 to 85.5 Gy in 25 daily fractions over 5 weeks using intensity-modulated radiotherapy. The MTD was defined as the maximum dose with Յ 20% risk of severe toxicity. ResultsNo grade 3 pneumonitis was observed and an MTD for acute toxicity was not identified during patient accrual. However, with a longer follow-up period, grade 4 to 5 toxicity occurred in six patients and was correlated with total dose (P ϭ .004). An MTD was identified at 63.25 Gy in 25 fractions. Late grade 4 to 5 toxicities were attributable to damage to central and perihilar structures and correlated with dose to the proximal bronchial tree. ConclusionAlthough this dose-escalation model limited the rates of clinically significant pneumonitis, dose-limiting toxicity occurred and was dominated by late radiation toxicity involving central and perihilar structures. The identified dose-response for damage to the proximal bronchial tree warrants caution in future dose-intensification protocols, especially when using hypofractionation.

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Nanocapillary Array Interconnects for Gated Analyte Injections and Electrophoretic Separations in Multilayer Microfluidic Architectures

et al. 2003

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An electrokinetic injection technique is described which uses a nuclear track-etched nanocapillary array to inject sample plugs from one layer of a microfluidic device into another vertically separated layer for electrophoretic separations. Gated injection protocols for analyte separations, reported here, establish nanocapillary array interconnects as a route to multilevel microfluidic analytical designs. The hybrid nanofluidic/microfluidic gated injection protocol allows sample preparation and separation to be implemented in separate horizontal planes, thereby achieving multilayer integration. Repeated injections and separations of FITC-labeled arginine and tryptophan, using 200-nm pore-diameter capillary array injectors in place of traditional cross injectors are used to demonstrate gated injection with a bias configuration that uses relay switching of a single high-voltage source. Injection times as rapid as 0.3 s along with separation reproducibilities as low as 1% for FITC-labeled arginine exemplify the capability for fast, serial separations and analyses. Impedance analysis of the micro-/nanofluidic network is used to gain further insight into the mechanism by which this actively controlled nanofluidic-interconnect injection method works. Gated sample introduction via a nanocapillary array interconnect allows the injection and separation protocols to be optimized independently, thus realizing the versatility needed for real-world implementation of rapid, serial microchip analyses.

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Donald M. Cannon

Gateable Nanofluidic Interconnects for Multilayered Microfluidic Separation Systems

Hybrid three-dimensional nanofluidic/microfluidic devices using molecular gates

Molecule Specific Imaging of Freeze-Fractured, Frozen-Hydrated Model Membrane Systems Using Mass Spectrometry

Dose-Limiting Toxicity After Hypofractionated Dose-Escalated Radiotherapy in Non–Small-Cell Lung Cancer

Nanocapillary Array Interconnects for Gated Analyte Injections and Electrophoretic Separations in Multilayer Microfluidic Architectures

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