Balancing Passive and Active Targeting to Different Tumor Compartments Using Riboflavin-Functionalized Polymeric Nanocarriers

Riboflavin transporters (RFTs) and the riboflavin carrier protein (RCP) are highly upregulated in many tumor cells, tumor stem cells, and tumor neovasculature, which makes them attractive targets for nanomedicines. Addressing cells in different tumor compartments requires drug carriers, which are no...

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Veröffentlicht in:	Nano letters 2017-08, Vol.17 (8), p.4665-4674
Hauptverfasser:	Tsvetkova, Yoanna, Beztsinna, Nataliia, Baues, Maike, Klein, Dionne, Rix, Anne, Golombek, Susanne K, Al Rawashdeh, Wa’el, Gremse, Felix, Barz, Matthias, Koynov, Kaloian, Banala, Srinivas, Lederle, Wiltrud, Lammers, Twan, Kiessling, Fabian
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Sprache:	eng
Schlagworte:	Animals Cell Line, Tumor Cell Proliferation - drug effects Cell Survival - drug effects Drug Carriers - chemistry Heterografts Humans Male Membrane Transport Proteins - metabolism Mice Particle Size Polyethylene Glycols - chemistry Polymers - chemistry Prostatic Neoplasms - drug therapy Riboflavin - chemistry Surface Properties Tissue Distribution
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creator	Tsvetkova, Yoanna Beztsinna, Nataliia Baues, Maike Klein, Dionne Rix, Anne Golombek, Susanne K Al Rawashdeh, Wa’el Gremse, Felix Barz, Matthias Koynov, Kaloian Banala, Srinivas Lederle, Wiltrud Lammers, Twan Kiessling, Fabian
description	Riboflavin transporters (RFTs) and the riboflavin carrier protein (RCP) are highly upregulated in many tumor cells, tumor stem cells, and tumor neovasculature, which makes them attractive targets for nanomedicines. Addressing cells in different tumor compartments requires drug carriers, which are not only able to accumulate via the EPR effect but also to extravasate, target specific cell populations, and get internalized by cells. Reasoning that antibodies are among the most efficient targeting systems developed by nature, we consider their size (∼10–15 nm) to be ideal for balancing passive and active tumor targeting. Therefore, small, short-circulating (10 kDa, ∼7 nm, t 1/2 ∼ 1 h) and larger, longer-circulating (40 kDa, ∼13 nm, t 1/2 ∼ 13 h) riboflavin-targeted branched PEG polymers were synthesized, and their biodistribution and target site accumulation were evaluated in mice bearing angiogenic squamous cell carcinoma (A431) and desmoplastic prostate cancer (PC3) xenografts. The tumor accumulation of the 10 kDa PEG was characterized by rapid intercompartmental exchange and significantly improved upon active targeting with riboflavin (RF). The 40 kDa PEG accumulated in tumors four times more efficiently than the small polymer, but its accumulation did not profit from active RF-targeting. However, RF-targeting enhanced the cellular internalization in both tumor models and for both polymer sizes. Interestingly, the nanocarriers’ cell-uptake in tumors was not directly correlated with the extent of accumulation. For example, in both tumor models the small RF-PEG accumulated much less strongly than the large passively targeted PEG but showed significantly higher intracellular amounts 24 h after iv administration. Additionally, the size of the polymer determined its preferential uptake by different tumor cell compartments: the 10 kDa RF-PEGs most efficiently targeted cancer cells, whereas the highest uptake of the 40 kDa RF-PEGs was observed in tumor-associated macrophages. These findings imply that drug carriers with sizes in the range of therapeutic antibodies show balanced properties with respect to passive accumulation, tissue penetration, and active targeting. Besides highlighting the potential of RF-mediated (cancer) cell targeting, we show that strong tumor accumulation does not automatically mean high cellular uptake and that the nanocarriers’ size plays a critical role in cell- and compartment-specific drug targeting.
doi_str_mv	10.1021/acs.nanolett.7b01171
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Addressing cells in different tumor compartments requires drug carriers, which are not only able to accumulate via the EPR effect but also to extravasate, target specific cell populations, and get internalized by cells. Reasoning that antibodies are among the most efficient targeting systems developed by nature, we consider their size (∼10–15 nm) to be ideal for balancing passive and active tumor targeting. Therefore, small, short-circulating (10 kDa, ∼7 nm, t 1/2 ∼ 1 h) and larger, longer-circulating (40 kDa, ∼13 nm, t 1/2 ∼ 13 h) riboflavin-targeted branched PEG polymers were synthesized, and their biodistribution and target site accumulation were evaluated in mice bearing angiogenic squamous cell carcinoma (A431) and desmoplastic prostate cancer (PC3) xenografts. The tumor accumulation of the 10 kDa PEG was characterized by rapid intercompartmental exchange and significantly improved upon active targeting with riboflavin (RF). The 40 kDa PEG accumulated in tumors four times more efficiently than the small polymer, but its accumulation did not profit from active RF-targeting. However, RF-targeting enhanced the cellular internalization in both tumor models and for both polymer sizes. Interestingly, the nanocarriers’ cell-uptake in tumors was not directly correlated with the extent of accumulation. For example, in both tumor models the small RF-PEG accumulated much less strongly than the large passively targeted PEG but showed significantly higher intracellular amounts 24 h after iv administration. Additionally, the size of the polymer determined its preferential uptake by different tumor cell compartments: the 10 kDa RF-PEGs most efficiently targeted cancer cells, whereas the highest uptake of the 40 kDa RF-PEGs was observed in tumor-associated macrophages. 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Addressing cells in different tumor compartments requires drug carriers, which are not only able to accumulate via the EPR effect but also to extravasate, target specific cell populations, and get internalized by cells. Reasoning that antibodies are among the most efficient targeting systems developed by nature, we consider their size (∼10–15 nm) to be ideal for balancing passive and active tumor targeting. Therefore, small, short-circulating (10 kDa, ∼7 nm, t 1/2 ∼ 1 h) and larger, longer-circulating (40 kDa, ∼13 nm, t 1/2 ∼ 13 h) riboflavin-targeted branched PEG polymers were synthesized, and their biodistribution and target site accumulation were evaluated in mice bearing angiogenic squamous cell carcinoma (A431) and desmoplastic prostate cancer (PC3) xenografts. The tumor accumulation of the 10 kDa PEG was characterized by rapid intercompartmental exchange and significantly improved upon active targeting with riboflavin (RF). The 40 kDa PEG accumulated in tumors four times more efficiently than the small polymer, but its accumulation did not profit from active RF-targeting. However, RF-targeting enhanced the cellular internalization in both tumor models and for both polymer sizes. Interestingly, the nanocarriers’ cell-uptake in tumors was not directly correlated with the extent of accumulation. For example, in both tumor models the small RF-PEG accumulated much less strongly than the large passively targeted PEG but showed significantly higher intracellular amounts 24 h after iv administration. Additionally, the size of the polymer determined its preferential uptake by different tumor cell compartments: the 10 kDa RF-PEGs most efficiently targeted cancer cells, whereas the highest uptake of the 40 kDa RF-PEGs was observed in tumor-associated macrophages. These findings imply that drug carriers with sizes in the range of therapeutic antibodies show balanced properties with respect to passive accumulation, tissue penetration, and active targeting. Besides highlighting the potential of RF-mediated (cancer) cell targeting, we show that strong tumor accumulation does not automatically mean high cellular uptake and that the nanocarriers’ size plays a critical role in cell- and compartment-specific drug targeting.</description><subject>Animals</subject><subject>Cell Line, Tumor</subject><subject>Cell Proliferation - drug effects</subject><subject>Cell Survival - drug effects</subject><subject>Drug Carriers - chemistry</subject><subject>Heterografts</subject><subject>Humans</subject><subject>Male</subject><subject>Membrane Transport Proteins - metabolism</subject><subject>Mice</subject><subject>Particle Size</subject><subject>Polyethylene Glycols - chemistry</subject><subject>Polymers - chemistry</subject><subject>Prostatic Neoplasms - drug therapy</subject><subject>Riboflavin - chemistry</subject><subject>Surface Properties</subject><subject>Tissue Distribution</subject><issn>1530-6984</issn><issn>1530-6992</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNp9kM1OJCEUhclkzOiobzCZsJxNtReK-ltqO44mRo1p1xUaLgZTBS1QJk7iu0ulW5euOOGec-B-hPxisGDA2YlUceGk8wOmtGjWwFjDvpEDVpVQ1F3Hv3_qVuyTnzE-AUBXVvCD7PO2YRXnzQF5O5ODdMq6R3onY7QvSKXT9FSlWa5keMQ0D5On59YYDOgSXU2jD3Tpx40Macw3kT7E2XVv194M8sW64mJyucM7Odj_qOmdH15HDFbRm_xnJUOwGOIR2TNyiHi8Ow_Jw8Xf1fKyuL79d7U8vS5k2YlUaJTAKwStW4ZgVFlpxsW6rDVT0gAHbBVmxaASray5MUJ0WEMndFNiVZeH5M-2dxP884Qx9aONCoe8Ovop9qzjogYh6iZbxdaqgo8xoOk3wY4yvPYM-hl8n8H3H-D7Hfgc-717YVqPqD9DH6SzAbaGOf7kp5DJxK873wGkD5YL</recordid><startdate>20170809</startdate><enddate>20170809</enddate><creator>Tsvetkova, Yoanna</creator><creator>Beztsinna, Nataliia</creator><creator>Baues, Maike</creator><creator>Klein, Dionne</creator><creator>Rix, Anne</creator><creator>Golombek, Susanne K</creator><creator>Al Rawashdeh, Wa’el</creator><creator>Gremse, Felix</creator><creator>Barz, Matthias</creator><creator>Koynov, Kaloian</creator><creator>Banala, Srinivas</creator><creator>Lederle, Wiltrud</creator><creator>Lammers, Twan</creator><creator>Kiessling, Fabian</creator><general>American Chemical Society</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><orcidid>https://orcid.org/0000-0002-1090-6805</orcidid><orcidid>https://orcid.org/0000-0002-7341-0399</orcidid></search><sort><creationdate>20170809</creationdate><title>Balancing Passive and Active Targeting to Different Tumor Compartments Using Riboflavin-Functionalized Polymeric Nanocarriers</title><author>Tsvetkova, Yoanna ; Beztsinna, Nataliia ; Baues, Maike ; Klein, Dionne ; Rix, Anne ; Golombek, Susanne K ; Al Rawashdeh, Wa’el ; Gremse, Felix ; Barz, Matthias ; Koynov, Kaloian ; Banala, Srinivas ; Lederle, Wiltrud ; Lammers, Twan ; Kiessling, Fabian</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a394t-dea025e0dd81e0fc35d124b36d1caf020e8cecaf10548a62ff449e6094d73e563</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2017</creationdate><topic>Animals</topic><topic>Cell Line, Tumor</topic><topic>Cell Proliferation - drug effects</topic><topic>Cell Survival - drug effects</topic><topic>Drug Carriers - chemistry</topic><topic>Heterografts</topic><topic>Humans</topic><topic>Male</topic><topic>Membrane Transport Proteins - metabolism</topic><topic>Mice</topic><topic>Particle Size</topic><topic>Polyethylene Glycols - chemistry</topic><topic>Polymers - chemistry</topic><topic>Prostatic Neoplasms - drug therapy</topic><topic>Riboflavin - chemistry</topic><topic>Surface Properties</topic><topic>Tissue Distribution</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Tsvetkova, Yoanna</creatorcontrib><creatorcontrib>Beztsinna, Nataliia</creatorcontrib><creatorcontrib>Baues, Maike</creatorcontrib><creatorcontrib>Klein, Dionne</creatorcontrib><creatorcontrib>Rix, Anne</creatorcontrib><creatorcontrib>Golombek, Susanne K</creatorcontrib><creatorcontrib>Al Rawashdeh, Wa’el</creatorcontrib><creatorcontrib>Gremse, Felix</creatorcontrib><creatorcontrib>Barz, Matthias</creatorcontrib><creatorcontrib>Koynov, Kaloian</creatorcontrib><creatorcontrib>Banala, Srinivas</creatorcontrib><creatorcontrib>Lederle, Wiltrud</creatorcontrib><creatorcontrib>Lammers, Twan</creatorcontrib><creatorcontrib>Kiessling, Fabian</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>Nano letters</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Tsvetkova, Yoanna</au><au>Beztsinna, Nataliia</au><au>Baues, Maike</au><au>Klein, Dionne</au><au>Rix, Anne</au><au>Golombek, Susanne K</au><au>Al Rawashdeh, Wa’el</au><au>Gremse, Felix</au><au>Barz, Matthias</au><au>Koynov, Kaloian</au><au>Banala, Srinivas</au><au>Lederle, Wiltrud</au><au>Lammers, Twan</au><au>Kiessling, Fabian</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Balancing Passive and Active Targeting to Different Tumor Compartments Using Riboflavin-Functionalized Polymeric Nanocarriers</atitle><jtitle>Nano letters</jtitle><addtitle>Nano Lett</addtitle><date>2017-08-09</date><risdate>2017</risdate><volume>17</volume><issue>8</issue><spage>4665</spage><epage>4674</epage><pages>4665-4674</pages><issn>1530-6984</issn><eissn>1530-6992</eissn><abstract>Riboflavin transporters (RFTs) and the riboflavin carrier protein (RCP) are highly upregulated in many tumor cells, tumor stem cells, and tumor neovasculature, which makes them attractive targets for nanomedicines. Addressing cells in different tumor compartments requires drug carriers, which are not only able to accumulate via the EPR effect but also to extravasate, target specific cell populations, and get internalized by cells. Reasoning that antibodies are among the most efficient targeting systems developed by nature, we consider their size (∼10–15 nm) to be ideal for balancing passive and active tumor targeting. Therefore, small, short-circulating (10 kDa, ∼7 nm, t 1/2 ∼ 1 h) and larger, longer-circulating (40 kDa, ∼13 nm, t 1/2 ∼ 13 h) riboflavin-targeted branched PEG polymers were synthesized, and their biodistribution and target site accumulation were evaluated in mice bearing angiogenic squamous cell carcinoma (A431) and desmoplastic prostate cancer (PC3) xenografts. The tumor accumulation of the 10 kDa PEG was characterized by rapid intercompartmental exchange and significantly improved upon active targeting with riboflavin (RF). The 40 kDa PEG accumulated in tumors four times more efficiently than the small polymer, but its accumulation did not profit from active RF-targeting. However, RF-targeting enhanced the cellular internalization in both tumor models and for both polymer sizes. Interestingly, the nanocarriers’ cell-uptake in tumors was not directly correlated with the extent of accumulation. For example, in both tumor models the small RF-PEG accumulated much less strongly than the large passively targeted PEG but showed significantly higher intracellular amounts 24 h after iv administration. Additionally, the size of the polymer determined its preferential uptake by different tumor cell compartments: the 10 kDa RF-PEGs most efficiently targeted cancer cells, whereas the highest uptake of the 40 kDa RF-PEGs was observed in tumor-associated macrophages. These findings imply that drug carriers with sizes in the range of therapeutic antibodies show balanced properties with respect to passive accumulation, tissue penetration, and active targeting. Besides highlighting the potential of RF-mediated (cancer) cell targeting, we show that strong tumor accumulation does not automatically mean high cellular uptake and that the nanocarriers’ size plays a critical role in cell- and compartment-specific drug targeting.</abstract><cop>United States</cop><pub>American Chemical Society</pub><pmid>28715227</pmid><doi>10.1021/acs.nanolett.7b01171</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0002-1090-6805</orcidid><orcidid>https://orcid.org/0000-0002-7341-0399</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Animals Cell Line, Tumor Cell Proliferation - drug effects Cell Survival - drug effects Drug Carriers - chemistry Heterografts Humans Male Membrane Transport Proteins - metabolism Mice Particle Size Polyethylene Glycols - chemistry Polymers - chemistry Prostatic Neoplasms - drug therapy Riboflavin - chemistry Surface Properties Tissue Distribution
title	Balancing Passive and Active Targeting to Different Tumor Compartments Using Riboflavin-Functionalized Polymeric Nanocarriers
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