Andrea Slezia
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Explore the profile of Andrea Slezia including associated specialties, affiliations and a list of published articles.
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18
Citations
427
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Recent Articles
1.
Ferro M, Proctor C, Gonzalez A, Jayabal S, Zhao E, Gagnon M, et al.
AIP Adv
. 2024 Aug;
14(8):085109.
PMID: 39130131
Scalable electronic brain implants with long-term stability and low biological perturbation are crucial technologies for high-quality brain-machine interfaces that can seamlessly access delicate and hard-to-reach regions of the brain. Here,...
2.
Slezia A, Hegedus P, Rusina E, Lengyel K, Solari N, Kaszas A, et al.
Sci Rep
. 2023 Nov;
13(1):19478.
PMID: 37945922
Studying animal models furthers our understanding of Parkinson's disease (PD) pathophysiology by providing tools to investigate detailed molecular, cellular and circuit functions. Different versions of the neurotoxin-based 6-hydroxydopamine (6-OHDA) model...
3.
Kaszas A, Szalay G, Slezia A, Bojdan A, Vanzetta I, Hangya B, et al.
Sci Rep
. 2021 May;
11(1):9775.
PMID: 33963220
Infrared neural stimulation is a promising tool for stimulating the brain because it can be used to excite with high spatial precision without the need of delivering or inserting any...
4.
Proctor C, Uguz I, Slezia A, Curto V, Inal S, Williamson A, et al.
Adv Biosyst
. 2020 Jul;
3(2):e1800270.
PMID: 32627377
The challenge of treating neurological disorders has motivated the development of implantable devices that can deliver treatment when and where it is needed. This study presents a novel brain implant...
5.
Vicente A, Slezia A, Ghestem A, Bernard C, Quilichini P
Neuroscience
. 2020 Mar;
435:95-111.
PMID: 32222556
The extent of the networks that control the genesis and modulation of hippocampal sharp-wave ripples (SPW-Rs), which are involved in memory consolidation, remains incompletely understood. Here, we performed a detailed...
6.
Slezia A, Proctor C, Kaszas A, Malliaras G, Williamson A
J Vis Exp
. 2019 Jun;
(147).
PMID: 31157762
Epilepsy is a group of neurological disorders which affects millions of people worldwide. Although treatment with medication is helpful in 70% of the cases, serious side effects affect the quality...
7.
Donahue M, Kaszas A, Turi G, Rozsa B, Slezia A, Vanzetta I, et al.
eNeuro
. 2019 Feb;
5(6).
PMID: 30783610
Transparent and flexible materials are attractive for a wide range of emerging bioelectronic applications. These include neural interfacing devices for both recording and stimulation, where low electrochemical electrode impedance is...
8.
Proctor C, Slezia A, Kaszas A, Ghestem A, Agua I, Pappa A, et al.
Sci Adv
. 2018 Sep;
4(8):eaau1291.
PMID: 30167463
The persistence of intractable neurological disorders necessitates novel therapeutic solutions. We demonstrate the utility of direct in situ electrophoretic drug delivery to treat neurological disorders. We present a neural probe...
9.
Pas J, Rutz A, Quilichini P, Slezia A, Ghestem A, Kaszas A, et al.
J Neural Eng
. 2018 Aug;
15(6):065001.
PMID: 30132444
Objective: Neural electrophysiology is often conducted with traditional, rigid depth probes. The mechanical mismatch between these probes and soft brain tissue is unfavorable for tissue interfacing. Making probes compliant can...
10.
Bartho P, Slezia A, Matyas F, Faradzs-Zade L, Ulbert I, Harris K, et al.
Neuron
. 2014 Jun;
82(6):1367-79.
PMID: 24945776
Sleep spindles are major transient oscillations of the mammalian brain. Spindles are generated in the thalamus; however, what determines their duration is presently unclear. Here, we measured somatic activity of...