MICROSCOPIC ANALYSIS OF <sup>11</sup>Li ELASTIC SCATTERING ON PROTONS

Key Points Question Will fecal microbiome transfer (FMT) lead to weight loss among adolescents with obesity? Findings In this randomized clinical trial of 87 adolescents with obesity, FMT alone did not lead to weight loss at 6 weeks. FMT alone was associated with a reduction in android-to-gynoid-fat ratio sustained for at least 26 weeks, particularly in female adolescents; changes in the overall gut microbiome composition; and a resolution of metabolic syndrome by 26 weeks in participants who had this undiagnosed condition at baseline. Meaning FMT alone is not an effective treatment for weight loss but may reduce visceral adiposity and improve health.

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Human Neural Tissues from Neural Stem Cells Using Conductive Biogel and Printed Polymer Microelectrode Arrays for 3D Electrical Stimulation

Tomaskovic-Crook

Zhang

Ahtiainen

et al. 2019

Adv Healthcare Materials

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Electricity is important in the physiology and development of human tissues such as embryonic and fetal development, and tissue regeneration for wound healing. Accordingly, electrical stimulation (ES) is increasingly being applied to influence cell behavior and function for a biomimetic approach to in vitro cell culture and tissue engineering. Here, the application of conductive polymer (CP) poly(3,4‐ethylenedioxythiophene)‐polystyrenesulfonate (PEDOT:PSS) pillars is described, direct‐write printed in an array format, for 3D ES of maturing neural tissues that are derived from human neural stem cells (NSCs). NSCs are initially encapsulated within a conductive polysaccharide‐based biogel interfaced with the CP pillar microelectrode arrays (MEAs), followed by differentiation in situ to neurons and supporting neuroglia during stimulation. Electrochemical properties of the pillar electrodes and the biogel support their electrical performance. Remarkably, stimulated constructs are characterized by widespread tracts of high‐density mature neurons and enhanced maturation of functional neural networks. Formation of tissues using the 3D MEAs substantiates the platform for advanced clinically relevant neural tissue induction, with the system likely amendable to diverse cell types to create other neural and non‐neural tissues. The platform may be useful for both research and translation, including modeling tissue development, function and dysfunction, electroceuticals, drug screening, and regenerative medicine.

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Conducting polymers for neuronal microelectrode array recording and stimulation

Aqrawe

Montgomery

Travaš-Sejdić

et al. 2018

Sensors and Actuators B: Chemical

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Electrochemically controlled drug delivery based on intrinsically conducting polymers

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Effects of Fecal Microbiome Transfer in Adolescents With Obesity

Human Neural Tissues from Neural Stem Cells Using Conductive Biogel and Printed Polymer Microelectrode Arrays for 3D Electrical Stimulation

Conducting polymers for neuronal microelectrode array recording and stimulation

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