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Items: 1 to 20 of 92

1.

Local drug delivery with a self-contained, programmable, microfluidic system.

Fiering J, Mescher MJ, Leary Swan EE, Holmboe ME, Murphy BA, Chen Z, Peppi M, Sewell WF, McKenna MJ, Kujawa SG, Borenstein JT.

Biomed Microdevices. 2009 Jun;11(3):571-8. doi: 10.1007/s10544-008-9265-5.

2.

Microfabricated infuse-withdraw micropump component for an integrated inner-ear drug-delivery platform.

Tandon V, Kang WS, Spencer AJ, Kim ES, Pararas EE, McKenna MJ, Kujawa SG, Mescher MJ, Fiering J, Sewell WF, Borenstein JT.

Biomed Microdevices. 2015 Apr;17(2):37. doi: 10.1007/s10544-014-9923-8.

PMID:
25686902
3.

A microfluidic reciprocating intracochlear drug delivery system with reservoir and active dose control.

Kim ES, Gustenhoven E, Mescher MJ, Pararas EE, Smith KA, Spencer AJ, Tandon V, Borenstein JT, Fiering J.

Lab Chip. 2014 Feb 21;14(4):710-21. doi: 10.1039/c3lc51105g.

4.

Characterization of implantable microfabricated fluid delivery devices.

Rathnasingham R, Kipke DR, Bledsoe SC Jr, McLaren JD.

IEEE Trans Biomed Eng. 2004 Jan;51(1):138-45.

PMID:
14723503
5.

Microfabricated reciprocating micropump for intracochlear drug delivery with integrated drug/fluid storage and electronically controlled dosing.

Tandon V, Kang WS, Robbins TA, Spencer AJ, Kim ES, McKenna MJ, Kujawa SG, Fiering J, Pararas EE, Mescher MJ, Sewell WF, Borenstein JT.

Lab Chip. 2016 Mar 7;16(5):829-46. doi: 10.1039/c5lc01396h.

6.

Development of a microfluidics-based intracochlear drug delivery device.

Sewell WF, Borenstein JT, Chen Z, Fiering J, Handzel O, Holmboe M, Kim ES, Kujawa SG, McKenna MJ, Mescher MM, Murphy B, Swan EE, Peppi M, Tao S.

Audiol Neurootol. 2009;14(6):411-22. doi: 10.1159/000241898. Epub 2009 Nov 16.

7.

Kinetics of reciprocating drug delivery to the inner ear.

Pararas EE, Chen Z, Fiering J, Mescher MJ, Kim ES, McKenna MJ, Kujawa SG, Borenstein JT, Sewell WF.

J Control Release. 2011 Jun 10;152(2):270-7. doi: 10.1016/j.jconrel.2011.02.021. Epub 2011 Mar 6.

8.

Inner ear drug delivery via a reciprocating perfusion system in the guinea pig.

Chen Z, Kujawa SG, McKenna MJ, Fiering JO, Mescher MJ, Borenstein JT, Swan EE, Sewell WF.

J Control Release. 2005 Dec 10;110(1):1-19. Epub 2005 Nov 7.

9.

Antisense oligonucleotides to the GluR2 AMPA receptor subunit modify excitatory synaptic transmission in vivo.

d'Aldin C, Caicedo A, Ruel J, Renard N, Pujol R, Puel JL.

Brain Res Mol Brain Res. 1998 Mar 30;55(1):151-64.

PMID:
9645970
10.

Ensemble spontaneous activity in the guinea-pig cochlear nerve.

Searchfield GD, Muñoz DJ, Thorne PR.

Hear Res. 2004 Jun;192(1-2):23-35.

PMID:
15157960
11.

A method for intracochlear drug delivery in the mouse.

Chen Z, Mikulec AA, McKenna MJ, Sewell WF, Kujawa SG.

J Neurosci Methods. 2006 Jan 15;150(1):67-73. Epub 2005 Jul 25.

PMID:
16043228
12.
13.

New approaches for inner ear therapy with glutamate antagonists.

Oestreicher E, Arnold W, Ehrenberger K, Felix D.

Acta Otolaryngol. 1999 Mar;119(2):174-8.

PMID:
10320071
14.

Microfluidics: an opportunity for trend-setting drug delivery.

Goettsche T, Ernst H, Messner S, Sandmaier H.

Med Device Technol. 2004 Mar;15(2):12-5.

PMID:
15154332
15.

Activity-dependent maturation of excitatory synaptic connections in solitary neuron cultures of mouse neocortex.

Takada N, Yanagawa Y, Komatsu Y.

Eur J Neurosci. 2005 Jan;21(2):422-30.

PMID:
15673441
16.

Glutamate transporters in the guinea-pig cochlea: partial mRNA sequences, cellular expression and functional implications.

Rebillard G, Ruel J, Nouvian R, Saleh H, Pujol R, Dehnes Y, Raymond J, Puel JL, Devau G.

Eur J Neurosci. 2003 Jan;17(1):83-92.

PMID:
12534971
17.

Transient gain adjustment in the inferior colliculus is serotonin- and calcium-dependent.

Miko IJ, Sanes DH.

Hear Res. 2009 May;251(1-2):39-50. doi: 10.1016/j.heares.2009.02.003. Epub 2009 Feb 20.

18.

Protection of auditory function against noise trauma with local caroverine administration in guinea pigs.

Chen Z, Ulfendahl M, Ruan R, Tan L, Duan M.

Hear Res. 2004 Nov;197(1-2):131-6.

PMID:
15504611
19.

Chronic excitotoxicity in the guinea pig cochlea induces temporary functional deficits without disrupting otoacoustic emissions.

Le Prell CG, Yagi M, Kawamoto K, Beyer LA, Atkin G, Raphael Y, Dolan DF, Bledsoe SC Jr, Moody DB.

J Acoust Soc Am. 2004 Aug;116(2):1044-56.

PMID:
15376671
20.

Localization and function of NK(3) subtype tachykinin receptors of layer V pyramidal neurons of the guinea-pig medial prefrontal cortex.

Simmons MA, Sobotka-Briner CD, Medd AM.

Neuroscience. 2008 Oct 28;156(4):987-94. doi: 10.1016/j.neuroscience.2008.08.037. Epub 2008 Aug 23.

PMID:
18801417

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