Literature DB >> 29208719

Effect of removing Kupffer cells on nanoparticle tumor delivery.

Anthony J Tavares1,2, Wilson Poon1,2, Yi-Nan Zhang1,2, Qin Dai1,2, Rickvinder Besla3, Ding Ding1,2, Ben Ouyang1,2,4, Angela Li3, Juan Chen5, Gang Zheng5,6, Clinton Robbins3,7, Warren C W Chan8,2,9,10,11.   

Abstract

A recent metaanalysis shows that 0.7% of nanoparticles are delivered to solid tumors. This low delivery efficiency has major implications in the translation of cancer nanomedicines, as most of the nanomedicines are sequestered by nontumor cells. To improve the delivery efficiency, there is a need to investigate the quantitative contribution of each organ in blocking the transport of nanoparticles to solid tumors. Here, we hypothesize that the removal of the liver macrophages, cells that have been reported to take up the largest amount of circulating nanoparticles, would lead to a significant increase in the nanoparticle delivery efficiency to solid tumors. We were surprised to discover that the maximum achievable delivery efficiency was only 2%. In our analysis, there was a clear correlation between particle design, chemical composition, macrophage depletion, tumor pathophysiology, and tumor delivery efficiency. In many cases, we observed an 18-150 times greater delivery efficiency, but we were not able to achieve a delivery efficiency higher than 2%. The results suggest the need to look deeper at other organs such as the spleen, lymph nodes, and tumor in mediating the delivery process. Systematically mapping the contribution of each organ quantitatively will allow us to pinpoint the cause of the low tumor delivery efficiency. This, in effect, enables the generation of a rational strategy to improve the delivery efficiency of nanoparticles to solid tumors either through the engineering of multifunctional nanosystems or through manipulation of biological barriers.

Entities:  

Keywords:  cancer; liver; macrophage; nanoparticle; tumor delivery

Mesh:

Substances:

Year:  2017        PMID: 29208719      PMCID: PMC5754793          DOI: 10.1073/pnas.1713390114

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  24 in total

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Journal:  Ther Deliv       Date:  2015-07

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Authors:  Leo Y T Chou; Warren C W Chan
Journal:  Adv Healthc Mater       Date:  2012-08-20       Impact factor: 9.933

3.  Increased serum enzyme levels associated with kupffer cell reduction with no signs of hepatic or skeletal muscle injury.

Authors:  Zaher A Radi; Petra H Koza-Taylor; Rosonald R Bell; Leslie A Obert; Herbert A Runnels; Jean S Beebe; Michael P Lawton; Seth Sadis
Journal:  Am J Pathol       Date:  2011-05-13       Impact factor: 4.307

4.  Mammary fat pad tumor preparation in mice.

Authors:  Rakesh K Jain; Lance L Munn; Dai Fukumura
Journal:  Cold Spring Harb Protoc       Date:  2012-10-01

5.  Relation between localization and function of rat liver Kupffer cells.

Authors:  E C Sleyster; D L Knook
Journal:  Lab Invest       Date:  1982-11       Impact factor: 5.662

6.  Effect of carrageenan on activity of the mononuclear phagocyte system in the mouse.

Authors:  E F Fowler; A W Thomson
Journal:  Br J Exp Pathol       Date:  1978-04

7.  Methyl palmitate: inhibitor of phagocytosis in primary rat Kupffer cells.

Authors:  P Cai; B S Kaphalia; G A S Ansari
Journal:  Toxicology       Date:  2005-06-01       Impact factor: 4.221

8.  Methyl palmitate inhibits lipopolysaccharide-stimulated phagocytic activity of rat peritoneal macrophages.

Authors:  Swapna Sarkar; M Firoze Khan; Bhupendra S Kaphalia; G A S Ansari
Journal:  J Biochem Mol Toxicol       Date:  2006       Impact factor: 3.642

9.  Polyethylene glycol backfilling mitigates the negative impact of the protein corona on nanoparticle cell targeting.

Authors:  Qin Dai; Carl Walkey; Warren C W Chan
Journal:  Angew Chem Int Ed Engl       Date:  2014-04-02       Impact factor: 15.336

10.  Inherently multimodal nanoparticle-driven tracking and real-time delineation of orthotopic prostate tumors and micrometastases.

Authors:  Tracy W Liu; Thomas D Macdonald; Cheng S Jin; Joseph M Gold; Robert G Bristow; Brian C Wilson; Gang Zheng
Journal:  ACS Nano       Date:  2013-04-05       Impact factor: 15.881
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  57 in total

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Authors:  Hamideh Parhiz; Makan Khoshnejad; Jacob W Myerson; Elizabeth Hood; Priyal N Patel; Jacob S Brenner; Vladimir R Muzykantov
Journal:  Adv Drug Deliv Rev       Date:  2018-07-03       Impact factor: 15.470

2.  A "Missile-Detonation" Strategy to Precisely Supply and Efficiently Amplify Cerenkov Radiation Energy for Cancer Theranostics.

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3.  Nanomedicine for Spontaneous Brain Tumors: A Companion Clinical Trial.

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4.  Biomolecular Ultrasound Imaging of Phagolysosomal Function.

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Journal:  ACS Nano       Date:  2020-09-14       Impact factor: 15.881

Review 5.  Induction of anti-cancer T cell immunity by in situ vaccination using systemically administered nanomedicines.

Authors:  Geoffrey M Lynn; Richard Laga; Christopher M Jewell
Journal:  Cancer Lett       Date:  2019-06-08       Impact factor: 8.679

6.  Mild Innate Immune Activation Overrides Efficient Nanoparticle-Mediated RNA Delivery.

Authors:  Melissa P Lokugamage; Zubao Gan; Chiara Zurla; Joel Levin; Fatima Z Islam; Sujay Kalathoor; Manaka Sato; Cory D Sago; Philip J Santangelo; James E Dahlman
Journal:  Adv Mater       Date:  2019-11-19       Impact factor: 30.849

7.  Isolating the sources of heterogeneity in nano-engineered particle-cell interactions.

Authors:  Stuart T Johnston; Matthew Faria; Edmund J Crampin
Journal:  J R Soc Interface       Date:  2020-05-20       Impact factor: 4.118

8.  Salicylic Acid-Based Polymeric Contrast Agents for Molecular Magnetic Resonance Imaging of Prostate Cancer.

Authors:  Sangeeta Ray Banerjee; Xiaolei Song; Xing Yang; Il Minn; Ala Lisok; Yanrong Chen; Albert Bui; Samit Chatterjee; Jian Chen; Peter C M van Zijl; Michael T McMahon; Martin G Pomper
Journal:  Chemistry       Date:  2018-04-26       Impact factor: 5.236

9.  Organ-restricted vascular delivery of nanoparticles for lung cancer therapy.

Authors:  Deniz A Bölükbas; Stefan Datz; Charlotte Meyer-Schwickerath; Carmela Morrone; Ali Doryab; Dorothee Gößl; Malamati Vreka; Lin Yang; Christian Argyo; Sabine H van Rijt; Michael Lindner; Oliver Eickelberg; Tobias Stoeger; Otmar Schmid; Sandra Lindstedt; Georgios T Stathopoulos; Thomas Bein; Darcy E Wagner; Silke Meiners
Journal:  Adv Ther (Weinh)       Date:  2020-05-13

10.  Structure-Dependent Biodistribution of Liposomal Spherical Nucleic Acids.

Authors:  Jennifer R Ferrer; Andrew J Sinegra; David Ivancic; Xin Yi Yeap; Longhui Qiu; Jiao-Jing Wang; Zheng Jenny Zhang; Jason A Wertheim; Chad A Mirkin
Journal:  ACS Nano       Date:  2020-01-17       Impact factor: 15.881
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