Axel Schumacher scite author profile

Microinfusions of drugs directly into the central nervous system of awake animals represent a widely used means of unravelling brain functions related to behaviour. However, current approaches generally use tethered liquid infusion systems and a syringe pump to deliver drugs into the brain, which often interfere with behaviour. We address this shortfall with a miniaturised electronically-controlled drug delivery system (20 × 17.5 × 5 mm³) designed to be skull-mounted in rats. The device features a micropump connected to two 8-mm-long silicon microprobes with a cross section of 250 × 250 μm² and integrated fluid microchannels. Using an external electronic control unit, the device allows infusion of 16 metered doses (0.25 μL each, 8 per silicon shaft). Each dosage requires 3.375 Ws of electrical power making the device additionally compatible with state-of-the-art wireless headstages. A dosage precision of 0.25 ± 0.01 μL was determined in vitro before in vivo tests were carried out in awake rats. No passive leakage from the loaded devices into the brain could be detected using methylene blue dye. Finally, the device was used to investigate the effects of the NMDA-receptor antagonist 3-((R)-2-Carboxypiperazin-4-yl)-propyl-1-phosphonic acid, (R)-CPP, administered directly into the prefrontal cortex of rats during performance on a task to assess visual attention and impulsivity. In agreement with previous findings using conventional tethered infusion systems, acute (R)-CPP administration produced a marked increase in impulsivity.

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Robust microprobe systems for simultaneous neural recording and drug delivery

Spieth

Schumacher

Seidl

et al. 2009

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Cross-coupling of the oscillation modes of vibratory gyroscopes

Braxmaier

Gaisser

Link

et al.

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This paper reports for the first time on the results of the advanced gyroscope design of HSG-IMIT with the double decoupling mechanism. In connection with the measurement results, particularly to characterize the effectiveness of the decoupling, the cross-coupling of the driven oscillation and the detection oscillation is investigated, discussed and evaluated in detail by theoretical modeling. A description of the measurement signal and the so-called quadrature signal is deduced and a comparison with the gyroscopes of HSG-IMIT realized according to the single decoupling principle DAVED [I] is accomplished.

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Bioavailability in vivo of naltrexone following transbuccal administration by an electronically-controlled intraoral device: A trial on pigs

Campisi

Giannola

Florena

et al. 2010

Journal of Controlled Release

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Axel Schumacher

Drug delivery from the oral cavity: focus on a novel mechatronic delivery device

An intra-cerebral drug delivery system for freely moving animals

Robust microprobe systems for simultaneous neural recording and drug delivery

Cross-coupling of the oscillation modes of vibratory gyroscopes

Bioavailability in vivo of naltrexone following transbuccal administration by an electronically-controlled intraoral device: A trial on pigs

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