Your search keyword '"Reit R"' showing total 10 results

1. Uptake of 131I by a papillary meningioma

Author

Preisman, RA, primary, Halpern, SE, additional, Shishido, R, additional, Waltz, T, additional, Callipari, F, additional, and Reit, R, additional

Published

1977

2. Design and demonstration of an intracortical probe technology with tunable modulus.

Author

Simon DM, Charkhkar H, St John C, Rajendran S, Kang T, Reit R, Arreaga-Salas D, McHail DG, Knaack GL, Sloan A, Grasse D, Dumas TC, Rennaker RL, Pancrazio JJ, and Voit WE

Subjects

Animals, Elastic Modulus, Electrodes, Mice, Brain Waves, Frontal Lobe physiology

Abstract

Intracortical probe technology, consisting of arrays of microelectrodes, offers a means of recording the bioelectrical activity from neural tissue. A major limitation of existing intracortical probe technology pertains to limited lifetime of 6 months to a year of recording after implantation. A major contributor to device failure is widely believed to be the interfacial mechanical mismatch of conventional stiff intracortical devices and the surrounding brain tissue. We describe the design, development, and demonstration of a novel functional intracortical probe technology that has a tunable Young's modulus from ∼2 GPa to ∼50 MPa. This technology leverages advances in dynamically softening materials, specifically thiol-ene/acrylate thermoset polymers, which exhibit minimal swelling of < 3% weight upon softening in vitro. We demonstrate that a shape memory polymer-based multichannel intracortical probe can be fabricated, that the mechanical properties are stable for at least 2 months and that the device is capable of single unit recordings for durations up to 77 days in vivo. This novel technology, which is amenable to processes suitable for manufacturing via standard semiconductor fabrication techniques, offers the capability of softening in vivo to reduce the tissue-device modulus mismatch to ultimately improve long term viability of neural recordings. © 2016 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 159-168, 2017., (© 2016 Wiley Periodicals, Inc.)

Published

2017

3. Thiol-epoxy/maleimide ternary networks as softening substrates for flexible electronics.

Author

Reit R, Abitz H, Reddy N, Parker S, Wei A, Aragon N, Ho M, Weittenhiller A, Kang T, Ecker M, and Voit WE

Abstract

Softening microelectrode arrays, or flexible bioelectronic systems which can dynamically change modulus under the application of an external stimulus such as heat or electromagnetic radiation, have been of significant interest in the literature within the previous decade. Through their ability to actively soften in vivo, these devices have shown the capacity to attenuate the neuronal damage associated with insertion of rigid microelectrode arrays into soft tissue. Thiol-click substrates specifically have shown particularly impressive results for fabricating devices requiring small-scale, high-performance electronics for neural recording. However, previous attempts to engineer increasingly lower-modulus substrates for these devices have failed due to the fundamental chemistries' (the thioether linkage) flexibility. This failure has led to substrates without sufficient mechanical rigidity for penetrating soft tissue at physiological temperatures, or sufficient softening capacity to reduce the mechanical mismatch between soft tissue and implantable device. In this work, a ternary thiol-epoxy/maleimide network is investigated as a potential substrate materials space in which the degree of softening can be modulated without sacrificing the mechanical rigidity at physiological temperatures. Using these networks as platforms for the microfabrication of electrode arrays, example implantable intracortical microelectrode arrays are fabricated on both thiol-epoxy and thiol-epoxy/maleimide networks to demonstrate the insertion capacity of microelectrode arrays on the ternary polymer networks.

Published

2016

4. High-Tg Thiol-Click Thermoset Networks via the Thiol-Maleimide Michael Addition.

Author

Parker S, Reit R, Abitz H, Ellson G, Yang K, Lund B, and Voit WE

Subjects

Glass, Molecular Structure, Polymers chemistry, Click Chemistry, Maleimides chemistry, Polymers chemical synthesis, Sulfhydryl Compounds chemistry, Transition Temperature

Abstract

Thiol-click reactions lead to polymeric materials with a wide range of interesting mechanical, electrical, and optical properties. However, this reaction mechanism typically results in bulk materials with a low glass transition temperature (Tg ) due to rotational flexibility around the thioether linkages found in networks such as thiol-ene, thiol-epoxy, and thiol-acrylate systems. This report explores the thiol-maleimide reaction utilized for the first time as a solvent-free reaction system to synthesize high-Tg thermosetting networks. Through thermomechanical characterization via dynamic mechanical analysis, the homogeneity and Tg s of thiol-maleimide networks are compared to similarly structured thiol-ene and thiol-epoxy networks. While preliminary data show more heterogeneous networks for thiol-maleimide systems, bulk materials exhibit Tg s 80 °C higher than other thiol-click systems explored herein. Finally, hollow tubes are synthesized using each thiol-click reaction mechanism and employed in low- and high-temperature environments, demonstrating the ability to withstand a compressive radial 100 N deformation at 100 °C wherein other thiol-click systems fail mechanically., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

5. Hydrolytically Stable Thiol-ene Networks for Flexible Bioelectronics.

Author

Reit R, Zamorano D, Parker S, Simon D, Lund B, Voit W, and Ware TH

Subjects

Elastic Modulus, Electronics instrumentation, Hydrolysis, Kinetics, Microelectrodes, Biocompatible Materials chemistry, Polymers chemistry, Siloxanes chemistry, Sulfhydryl Compounds chemistry

Abstract

Hydrolytically stable, tunable modulus polymer networks are demonstrated to survive harsh alkaline environments and offer promise for use in long-term implantable bioelectronic medicines known as electroceuticals. Today's polymer networks (such as polyimides or polysiloxanes) succeed in providing either stiff or soft substrates for bioelectronics devices; however, the capability to significantly tune the modulus of such materials is lacking. Within the space of materials with easily modified elastic moduli, thiol-ene copolymers are a subset of materials that offer a promising solution to build next generation flexible bioelectronics but have typically been susceptible to hydrolytic degradation chronically. In this inquiry, we demonstrate a materials space capable of tuning the substrate modulus and explore the mechanical behavior of such networks. Furthermore, we fabricate an array of microelectrodes that can withstand accelerated aging environments shown to destroy conventional flexible bioelectronics.

Published

2015

6. Integration of High-Charge-Injection-Capacity Electrodes onto Polymer Softening Neural Interfaces.

Author

Arreaga-Salas DE, Avendaño-Bolívar A, Simon D, Reit R, Garcia-Sandoval A, Rennaker RL, and Voit W

Subjects

Animals, Elastic Modulus, Electrochemistry, Immunohistochemistry, Male, Microelectrodes, Rats, Sprague-Dawley, Xylenes chemistry, Electricity, Neurons physiology, Polymers chemistry

Abstract

Softening neural interfaces are implanted stiff to enable precise insertion, and they soften in physiological conditions to minimize modulus mismatch with tissue. In this work, a high-charge-injection-capacity iridium electrode fabrication process is detailed. For the first time, this process enables integration of iridium electrodes onto softening substrates using photolithography to define all features in the device. Importantly, no electroplated layers are utilized, leading to a highly scalable method for consistent device fabrication. The iridium electrode is metallically bonded to the gold conductor layer, which is covalently bonded to the softening substrate via sulfur-based click chemistry. The resulting shape-memory polymer neural interfaces can deliver more than 2 billion symmetric biphasic pulses (100 μs/phase), with a charge of 200 μC/cm(2) and geometric surface area (GSA) of 300 μm(2). A transfer-by-polymerization method is used in combination with standard semiconductor processing techniques to fabricate functional neural probes onto a thiol-ene-based, thin film substrate. Electrical stability is tested under simulated physiological conditions in an accelerated electrical aging paradigm with periodic measurement of electrochemical impedance spectra (EIS) and charge storage capacity (CSC) at various intervals. Electrochemical characterization and both optical and scanning electron microscopy suggest significant breakdown of the 600 nm-thick parylene-C insulation, although no delamination of the conductors or of the final electrode interface was observed. Minor cracking at the edges of the thin film iridium electrodes was occasionally observed. The resulting devices will provide electrical recording and stimulation of the nervous system to better understand neural wiring and timing, to target treatments for debilitating diseases, and to give neuroscientists spatially selective and specific tools to interact with the body. This approach has uses for cochlear implants, nerve cuff electrodes, penetrating cortical probes, spinal stimulators, blanket electrodes for the gut, stomach, and visceral organs and a host of other custom nerve-interfacing devices.

Published

2015

7. EPR studies on the organization of self-assembled spin-labeled organic monolayers adsorbed on GaAs.

Author

Ruthstein S, Artzi R, Goldfarb D, and Naaman R

Subjects

Electromagnetic Fields, Electron Spin Resonance Spectroscopy methods, Hydroxylamine chemistry, Models, Molecular, Spectroscopy, Fourier Transform Infrared, Spin Labels, Cyclic N-Oxides chemistry

Abstract

Characterizing the structure and dynamic properties of a single monolayer is a challenge due to the minute amount of material that is probed. Here, EPR spectroscopy is used for investigating the spatial and temporal organization of self-assembled monolayers of 5- and 16-doxyl stearic acid (5 DSA and 16 DSA, respectively) adsorbed on a GaAs substrate. The results are complemented with FTIR and ellipsometery measurements, which provide the evidence for the formation of monolayers. Moreover, a comparison with the FTIR spectrum of a monolayer of stearic acid shows that the monolayers of the spin labeled molecules are less packed due to the hindrance introduced by the labeling group. The EPR spectra provide a new insight on the ordering in the layer and more interestingly, it reveals the time dependence of the organization. For 5DSA, with the spin-label group situated close to the substrate, the EPR spectrum immediately after adsorption is poorly resolved and dominated by the spin-exchange interaction between neighboring molecules. As time increases (up to 1 week) the resolution of the 14N hyperfine coupling increases, revealing a better organized monolayer where the molecules are more homogenously spaced. Moreover, the spectrum of the layer, after reaching equilibrium, shows that there is no motional freedom near the GaAs surface. Orientation dependence measurements on the equilibrated sample show the presence of a preferred orientation of the molecules, although with a wide distribution. The spectrum of the 16DSA monolayer, where the nitroxide spin label is situated at the end of the chain, far from the surface, also showed a poorly resolved spectrum at short times, but unlike 5DSA, it did not exhibit any time dependence. Through EPR line-shape simulations and by comparison with FTIR results, the differences between 5DSA and 16DSA were attributed to difference in coverage caused by the bulky spin label near the surface in the case of 5DSA.

Published

2005

8. Uptake of 131I by a papillary meningioma.

Author

Preisman RA, Halpern SE, Shishido R, Waltz T, Callipari F, and Reit R

Subjects

Humans, Male, Meningioma pathology, Middle Aged, Spinal Cord Neoplasms pathology, Thyroid Neoplasms metabolism, Iodine Radioisotopes metabolism, Meningioma metabolism, Spinal Cord Neoplasms metabolism

Published

1977

9. A clinical evaluation of gallium-67 citrate scanning.

Author

Littenberg RL, Alazraki NP, Taketa RM, Reit R, Halpern SE, and Ashburn WL

Subjects

Adenocarcinoma diagnosis, Bone Neoplasms diagnosis, Brain Neoplasms diagnosis, Breast Neoplasms diagnosis, Carcinoma, Bronchogenic diagnosis, Child, Female, Humans, Liver Neoplasms diagnosis, Lung Neoplasms diagnosis, Lymphoma, Large B-Cell, Diffuse diagnosis, Male, Middle Aged, Mononuclear Phagocyte System, Neoplasm Metastasis, Gallium, Neoplasms diagnosis, Radionuclide Imaging

Published

1973

10. Intra-abdominal chicken-bone abscess.

Author

Berk RN and Reit RJ

Subjects

Abscess etiology, Aged, Bone and Bones, Diagnosis, Differential, Female, Humans, Male, Middle Aged, Radiography, Abscess diagnostic imaging, Colon injuries, Foreign Bodies complications, Intestinal Perforation, Liver, Liver Abscess etiology, Stomach Rupture etiology

Published

1971