TY - JOUR
T1 - Leveraging nanochannels for universal, zero-order drug delivery in vivo
AU - Ferrati, Silvia
AU - Fine, Daniel
AU - You, Junping
AU - De Rosa, Enrica
AU - Hudson, Lee
AU - Zabre, Erika
AU - Hosali, Sharath
AU - Zhang, Li
AU - Hickman, Catherine
AU - Sunder Bansal, Shyam
AU - Cordero-Reyes, Andrea M.
AU - Geninatti, Thomas
AU - Sih, Juliana
AU - Goodall, Randy
AU - Palapattu, Ganesh
AU - Kloc, Malgorzata
AU - Ghobrial, Rafik M.
AU - Ferrari, Mauro
AU - Grattoni, Alessandro
N1 - Funding Information:
This technical report is dedicated to the memory of Catherine Hickman. The authors would like to acknowledge the contributions of: Dr. Xian Li, Dr. Alma Zecevic, Eugenia Nicolov, Christian Celia, and Fatema Dalal for support in the manuscript preparation and in vitro and in vivo testing; Kunal Raghuwansi for the gas testing of the nanofluidic membranes; Neelam Tejpal for the preparation of histological samples and Keith Youker for pathological analysis; Tommaso Novellino for performing ELISA measurements and analysis of the INFα-2b blood samples. The authors would also like to thank The Methodist Hospital Research Institute Proteomics Core Facility (Houston, TX) for the LC/MS analysis, the Texas Children's Hospital Small Animal Imaging Facility (Houston, TX) for bone density analysis, the Pathology Department of The Methodist Hospital (Houston, TX), the Texas A&M Institute for Preclinical Studies and the Cardiovascular Pathology Lab at Texas A&M University (College Station, TX) for histological analysis, and the Microelectronics Research Center at the University of Texas at Austin for facilitating membrane fabrication and characterization. This work was supported with funds from NASA ( NNJ06HEA and NNX08AW91G ), NanoMedical Systems (NMS) , the Department of Defense ( DODW81XWH-09-1-0212 ), Emily Herrmann Foundation , and the Cancer, Prevention, and Research Institute of Texas (CPRIT) for the Innovative Thinking Scholarship. The authors D. Fine, R. Goodall, L. Hudson, S. Hosali, M. Ferrari, and A. Grattoni disclose a financial interest in NanoMedical Systems, Inc. All other authors declare no competing financial interest.
PY - 2013
Y1 - 2013
N2 - Drug delivery is essential to achieve effective therapy. Herein we report on the only implantable nanochannel membrane with geometrically defined channels as small as 2.5 nm that achieves constant drug delivery in vivo. Nanochannels passively control the release of molecules by physico-electrostatic confinement, thereby leading to constant drug diffusion. We utilize a novel design algorithm to select the optimal nanochannel size for each therapeutic agent. Using nanochannels as small as 3.6 and 20 nm, we achieve sustained and constant plasma levels of leuprolide, interferon α-2b, letrozole, Y-27632, octreotide, and human growth hormone, all delivered at clinically-relevant doses. The device was demonstrated in dogs, rats, and mice and was capable of sustaining target doses for up to 70 days. To provide evidence of therapeutic efficacy, we successfully combined nanochannel delivery with a RhoA pathway inhibitor to prevent chronic rejection of cardiac allografts in a rat model. Our results provide evidence that the nanochannel platform has the potential to dramatically improve long-term therapies for chronic conditions.
AB - Drug delivery is essential to achieve effective therapy. Herein we report on the only implantable nanochannel membrane with geometrically defined channels as small as 2.5 nm that achieves constant drug delivery in vivo. Nanochannels passively control the release of molecules by physico-electrostatic confinement, thereby leading to constant drug diffusion. We utilize a novel design algorithm to select the optimal nanochannel size for each therapeutic agent. Using nanochannels as small as 3.6 and 20 nm, we achieve sustained and constant plasma levels of leuprolide, interferon α-2b, letrozole, Y-27632, octreotide, and human growth hormone, all delivered at clinically-relevant doses. The device was demonstrated in dogs, rats, and mice and was capable of sustaining target doses for up to 70 days. To provide evidence of therapeutic efficacy, we successfully combined nanochannel delivery with a RhoA pathway inhibitor to prevent chronic rejection of cardiac allografts in a rat model. Our results provide evidence that the nanochannel platform has the potential to dramatically improve long-term therapies for chronic conditions.
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U2 - 10.1016/j.jconrel.2013.09.028
DO - 10.1016/j.jconrel.2013.09.028
M3 - Article
C2 - 24095805
AN - SCOPUS:84887164660
SN - 0168-3659
VL - 172
SP - 1011
EP - 1019
JO - Journal of Controlled Release
JF - Journal of Controlled Release
IS - 3
ER -