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150 results on '"Marcos-Contreras, Oscar A."'

1. Nanocarriers' repartitioning of drugs between blood subcompartments as a mechanism of improving pharmacokinetics, safety, and efficacy

Author

Zaleski, Michael H., Omo-Lamai, Serena, Nong, Jia, Chase, Liam S., Myerson, Jacob W., Glassman, Patrick M., Lee, Florence, Reyes-Esteves, Sahily, Wang, Zhicheng, Patel, Manthan N., Peshkova, Alina D., Komatsu, Hiroaki, Axelsen, Paul H., Muzykantov, Vladimir R., Marcos-Contreras, Oscar A., and Brenner, Jacob S.

Published
2024
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3. Targeting lipid nanoparticles to the blood-brain barrier to ameliorate acute ischemic stroke

Author

Nong, Jia, Glassman, Patrick M., Shuvaev, Vladimir V., Reyes-Esteves, Sahily, Descamps, Helene C., Kiseleva, Raisa Y., Papp, Tyler E., Alameh, Mohamad-Gabriel, Tam, Ying K., Mui, Barbara L., Omo-Lamai, Serena, Zamora, Marco E., Shuvaeva, Tea, Arguiri, Evguenia, Gong, Xijing, Brysgel, Taylor V., Tan, Ai Wen, Woolfork, Ashley G., Weljie, Aalim, Thaiss, Christoph A., Myerson, Jacob W., Weissman, Drew, Kasner, Scott E., Parhiz, Hamideh, Muzykantov, Vladimir R., Brenner, Jacob S., and Marcos-Contreras, Oscar A.

Published
2024
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6. Added to pre-existing inflammation, mRNA-lipid nanoparticles induce inflammation exacerbation (IE)

Author

Parhiz, Hamideh, Brenner, Jacob S., Patel, Priyal N., Papp, Tyler E., Shahnawaz, Hamna, Li, Qin, Shi, Ruiqi, Zamora, Marco E., Yadegari, Amir, Marcos-Contreras, Oscar A., Natesan, Ambika, Pardi, Norbert, Shuvaev, Vladimir V., Kiseleva, Raisa, Myerson, Jacob W., Uhler, Thomas, Riley, Rachel S., Han, Xuexiang, Mitchell, Michael J., Lam, Kieu, Heyes, James, Weissman, Drew, and Muzykantov, Vladimir R.

Published
2022
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7. Supramolecular arrangement of protein in nanoparticle structures predicts nanoparticle tropism for neutrophils in acute lung inflammation

Author

Myerson, Jacob W., Patel, Priyal N., Rubey, Kathryn M., Zamora, Marco E., Zaleski, Michael H., Habibi, Nahal, Walsh, Landis R., Lee, Yi-Wei, Luther, David C., Ferguson, Laura T., Marcos-Contreras, Oscar A., Glassman, Patrick M., Mazaleuskaya, Liudmila L., Johnston, Ian, Hood, Elizabeth D., Shuvaeva, Tea, Wu, Jichuan, Zhang, Hong-Ying, Gregory, Jason V., Kiseleva, Raisa Y., Nong, Jia, Grosser, Tilo, Greineder, Colin F., Mitragotri, Samir, Worthen, George S., Rotello, Vincent M., Lahann, Joerg, Muzykantov, Vladimir R., and Brenner, Jacob S.

Published
2022
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8. Targeting of nanoparticles to the cerebral vasculature after traumatic brain injury

Author

Omo-Lamai, Serena, primary, Nong, Jia, additional, Savalia, Krupa, additional, Kelley, Brian J., additional, Wu, Jichuan, additional, Esteves-Reyes, Sahily, additional, Chase, Liam S., additional, Muzykantov, Vladimir R., additional, Marcos-Contreras, Oscar A., additional, Dollé, Jean-Pierre, additional, Smith, Douglas H., additional, and Brenner, Jacob S., additional

Published
2024
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9. Marginated neutrophils in the lungs effectively compete for nanoparticles targeted to the endothelium, serving as a part of the reticuloendothelial system

Author

Zamora, Marco E, primary, Essien, Eno-Obong, additional, Bhamidipati, Kartik, additional, Murthy, Aditi, additional, Liu, Jing, additional, Kim, Hyunjun, additional, Patel, Manthan N, additional, Nong, Jia, additional, Wang, Zhicheng, additional, Espy, Carolann, additional, Chaudhry, Fatima, additional, Ferguson, Laura T, additional, Tiwari, Sachchidananda, additional, Hood, Elizabeth, additional, Marcos-Contreras, Oscar A, additional, Omo-Lamai, Serena, additional, Shuvaeva, Tea, additional, Arguiri, Evguenia, additional, Wu, Jichuan, additional, Rauova, Lubica, additional, Poncz, Mortimer, additional, Basil, Maria C, additional, Cantu, Edward, additional, Planer, Joseph D, additional, Spiller, Kara, additional, Zepp, Jarod, additional, Muzykantov, Vladimir, additional, Myerson, Jacob W, additional, and Brenner, Jacob S, additional

Published
2024
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11. Selective targeting of nanomedicine to inflamed cerebral vasculature to enhance the blood–brain barrier

Author

Marcos-Contreras, Oscar A., Greineder, Colin F., Kiseleva, Raisa Yu, Parhiz, Hamideh, Walsh, Landis R., Zuluaga-Ramirez, Viviana, Myerson, Jacob W., Hood, Elizabeth D., Villa, Carlos H., Tombacz, Istvan, Pardi, Norbert, Seliga, Alecia, Mui, Barbara L., Tam, Ying K., Glassman, Patrick M., Shuvaev, Vladimir V., Nong, Jia, Brenner, Jacob S., Khoshnejad, Makan, Madden, Tom, Weissmann, Drew, Persidsky, Yuri, and Muzykantov, Vladimir R.

Published
2020

13. Marginated Neutrophils in the Lungs Effectively Compete for Nanoparticles Targeted to the Endothelium, Serving as a Part of the Reticuloendothelial System.

Author

Zamora, Marco E., Essien, Eno-Obong, Bhamidipati, Kartik, Murthy, Aditi, Liu, Jing, Kim, Hyunjun, Patel, Manthan N., Nong, Jia, Wang, Zhicheng, Espy, Carolann, Chaudhry, Fatima N., Ferguson, Laura T., Tiwari, Sachchidanand, Hood, Elizabeth D., Marcos-Contreras, Oscar A., Omo-Lamai, Serena, Shuvaeva, Tea, Arguiri, Evguenia, Wu, Jichuan, and Rauova, Lubica

Published
2024
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21. Targeting lipid nanoparticles to the blood brain barrier to ameliorate acute ischemic stroke

Author

Nong, Jia, Glassman, Patrick M., Reyes-Esteves, Sahily, Descamps, Helene C., Shuvaev, Vladimir V., Kiseleva, Raisa Y., Papp, Tyler E., Alameh, Mohamad-Gabriel, Tam, Ying K., Mui, Barbara L., Omo-Lamai, Serena, Zamora, Marco E., Shuvaeva, Tea, Arguiri, Evguenia, Thaiss, Christoph A, Myerson, Jacob W., Weissman, Drew, Kasner, Scott E., Parhiz, Hamideh, Muzykantov, Vladimir R., Brenner, Jacob S., and Marcos-Contreras, Oscar A.

Subjects
Article
Abstract

After more than 100 failed drug trials for acute ischemic stroke (AIS), one of the most commonly cited reasons for the failure has been that drugs achieve very low concentrations in the at-risk penumbra. To address this problem, here we employ nanotechnology to significantly enhance drug concentration in the penumbra’s blood-brain barrier (BBB), whose increased permeability in AIS has long been hypothesized to kill neurons by exposing them to toxic plasma proteins. To devise drug-loaded nanocarriers targeted to the BBB, we conjugated them with antibodies that bind to various cell adhesion molecules on the BBB endothelium. In the transient middle cerebral artery occlusion (tMCAO) mouse model, nanocarriers targeted with VCAM antibodies achieved the highest level of brain delivery, nearly 2 orders of magnitude higher than untargeted ones. VCAM-targeted lipid nanoparticles loaded with either a small molecule drug (dexamethasone) or mRNA (encoding IL-10) reduced cerebral infarct volume by 35% or 73%, respectively, and both significantly lowered mortality rates. In contrast, the drugs delivered without the nanocarriers had no effect on AIS outcomes. Thus, VCAM-targeted lipid nanoparticles represent a new platform for strongly concentrating drugs within the compromised BBB of penumbra, thereby ameliorating AIS. GRAPHICAL ABSTRACT: Acute ischemic stroke induces upregulation of VCAM. We specifically targeted upregulated VCAM in the injured region of the brain with drug- or mRNA-loaded targeted nanocarriers. Nanocarriers targeted with VCAM antibodies achieved the highest brain delivery, nearly orders of magnitude higher than untargeted ones. VCAM-targeted nanocarriers loaded with dexamethasone and mRNA encoding IL-10 reduced infarct volume by 35% and 73%, respectively, and improved survival rates.

Published
2023

23. Targeted In Vivo Loading of Red Blood Cells Markedly Prolongs Nanocarrier Circulation

Author

Glassman, Patrick M., primary, Villa, Carlos H., additional, Marcos-Contreras, Oscar A., additional, Hood, Elizabeth D., additional, Walsh, Landis R., additional, Greineder, Colin F., additional, Myerson, Jacob W., additional, Shuvaeva, Tea, additional, Puentes, Laura, additional, Brenner, Jacob S., additional, Siegel, Don L., additional, and Muzykantov, Vladimir R., additional

Published
2022
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25. Pulmonary Marginated Neutrophils: A Novel Target for Vascular Targeted Nanoparticles

Author

Essien, Eno-Obong, Zamora, Marco, Murthy, Aditi, Hood, Elizabeth, Ferguson, Laura, Marcos-Contreras, Oscar, and Brenner, Jacob S.

Abstract

Pulmonary disease is one of the leading causes of mortality in the world, and continues to remain in need of effective therapies. To address this need, nanomedicine is a promising strategy that achieves organ specific delivery of RNA and small molecular drugs. Antibody conjugated nanoparticles targeting vascular endothelial moieties such as ICAM, PLVAP and PECAM can concentrate drugs in the lungs up to 300 fold more than standard drug delivery. However, for decades, this organ specificity had been assumed to be solely due to endothelial cell specific uptake in the pulmonary vasculature. Thus, in our study, we sought to determine the cell type specificity of vascular targeted liposomes. We achieved this by conjugating antibodies targeting ICAM, PECAM and PLVAP, and delivered them intravenously in both healthy mice and mice with acute lung injury. Surprisingly, we found that in addition to endothelial cell uptake, there was avid uptake by marginated neutrophils in both healthy and diseased mice. Across the vascular targeting moieties, PLVAP had the most endothelial specific uptake though there was still some uptake by marginated neutrophils. To further understand the mechanisms of uptake, we showed that marginated neutrophil liposome uptake is not mediated by surface presentation of ICAM and PECAM as previously thought. Furthermore, we demonstrated that the mechanism of uptake is similar amongst other forms of vascular targeted conjugated nanoparticles. Finally, we showed that these mechanisms of liposomal uptake can be recapitulated in human lungs. In conclusion, from our data, cell specific targeting remains elusive and will require further engineering to improve specificity. However, neutrophil nanoparticle uptake does present a unique opportunity for innovative drug delivery strategies to ameliorate lung disease.

Published
2022
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27. Dual Affinity to RBCs and Target Cells (DART) Enhances Both Organ- and Cell Type-Targeting of Intravascular Nanocarriers

Author

Ferguson, Laura T., primary, Hood, Elizabeth D., additional, Shuvaeva, Tea, additional, Shuvaev, Vladimir V., additional, Basil, Maria C., additional, Wang, Zhicheng, additional, Nong, Jia, additional, Ma, Xiaonan, additional, Wu, Jichuan, additional, Myerson, Jacob W., additional, Marcos-Contreras, Oscar A., additional, Katzen, Jeremy, additional, Carl, Justine M., additional, Morrisey, Edward E., additional, Cantu, Edward, additional, Villa, Carlos H., additional, Mitragotri, Samir, additional, Muzykantov, Vladimir R., additional, and Brenner, Jacob S., additional

Published
2022
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28. Targeted nanocarriers coopting pulmonary leukocytes for drug delivery to the injured brain

Author

Glassman, Patrick M., primary, Nong, Jia, additional, Myerson, Jacob W., additional, Zuluaga-Ramirez, Viviana, additional, Rodriguez-Garcia, Alba, additional, Mukalel, Alvin, additional, Omo-Lamai, Serena, additional, Walsh, Landis R., additional, Kiseleva, Raisa Y., additional, Villa, Carlos H., additional, Greineder, Colin F., additional, Kasner, Scott E., additional, Weissman, Drew, additional, Mitchell, Michael J., additional, Muro, Silvia, additional, Persidsky, Yuri, additional, Brenner, Jacob S., additional, Muzykantov, Vladimir R., additional, and Marcos-Contreras, Oscar A., additional

Published
2022
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29. Combating Complement's Deleterious Effects on Nanomedicine by Conjugating Complement Regulatory Proteins to Nanoparticles (Adv. Mater. 8/2022)

Author

Wang, Zhicheng, primary, Hood, Elizabeth D., additional, Nong, Jia, additional, Ding, Jing, additional, Marcos‐Contreras, Oscar A., additional, Glassman, Patrick M., additional, Rubey, Kathryn M., additional, Zaleski, Michael, additional, Espy, Carolann L., additional, Gullipali, Damodara, additional, Miwa, Takashi, additional, Muzykantov, Vladimir R., additional, Song, Wen‐Chao, additional, Myerson, Jacob W., additional, and Brenner, Jacob S., additional

Published
2022
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30. Supramolecular arrangement of protein in nanoparticle structures predicts nanoparticle tropism for neutrophils in acute lung inflammation

Author

Myerson, Jacob W., primary, Patel, Priyal N., additional, Rubey, Kathryn M., additional, Zamora, Marco E., additional, Zaleski, Michael H., additional, Habibi, Nahal, additional, Walsh, Landis R., additional, Lee, Yi-Wei, additional, Luther, David C., additional, Ferguson, Laura T., additional, Marcos-Contreras, Oscar A., additional, Glassman, Patrick M., additional, Mazaleuskaya, Liudmila L., additional, Johnston, Ian, additional, Hood, Elizabeth D., additional, Shuvaeva, Tea, additional, Wu, Jichuan, additional, Zhang, Hong-Ying, additional, Gregory, Jason V., additional, Kiseleva, Raisa Y., additional, Nong, Jia, additional, Grosser, Tilo, additional, Greineder, Colin F., additional, Mitragotri, Samir, additional, Worthen, George S., additional, Rotello, Vincent M., additional, Lahann, Joerg, additional, Muzykantov, Vladimir R., additional, and Brenner, Jacob S., additional

Published
2021
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34. Abstract P742: Nanoparticles Targeting the Inflammatory Network in Acute Neurovascular Inflammation: Lungs to Brain Axis

Author

Marcos-Contreras, Oscar Armando, primary, Glassman, Patrick M, additional, Nong, Jia, additional, Walsh, Landis, additional, Zuluaga-Ramirez, Viviana, additional, Rodriguez-Garcia, Alba, additional, Kiseleva, Raisa Yu, additional, Greineder, Colin, additional, Hood, Elizabeth, additional, Villa, Carlos H, additional, Myerson, Jacob W, additional, Brenner, Jacob, additional, Persidsky, Yuri, additional, and Muzykantov, Vladimir R, additional

Published
2021
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36. Supramolecular Organization Predicts Protein Nanoparticle Delivery to Neutrophils for Acute Lung Inflammation Diagnosis and Treatment

Author

Myerson, Jacob W., primary, Patel, Priyal N., additional, Habibi, Nahal, additional, Walsh, Landis R., additional, Lee, Yi-Wei, additional, Luther, David C., additional, Ferguson, Laura T., additional, Zaleski, Michael H., additional, Zamora, Marco E., additional, Marcos-Contreras, Oscar A., additional, Glassman, Patrick M., additional, Johnston, Ian, additional, Hood, Elizabeth D., additional, Shuvaeva, Tea, additional, Gregory, Jason V., additional, Kiseleva, Raisa Y., additional, Nong, Jia, additional, Rubey, Kathryn M., additional, Greineder, Colin F., additional, Mitragotri, Samir, additional, Worthen, George S., additional, Rotello, Vincent M., additional, Lahann, Joerg, additional, Muzykantov, Vladimir R., additional, and Brenner, Jacob S., additional

Published
2020
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39. Monoclonal antibody 2C5 specifically targets neutrophil extracellular traps

Author

Mendes, Livia P., primary, Rostamizadeh, Kobra, additional, Gollomp, Kandace, additional, Myerson, Jacob W., additional, Marcos-Contreras, Oscar A., additional, Zamora, Marco, additional, Luther, Ed, additional, Brenner, Jacob S., additional, Filipczak, Nina, additional, Li, Xiang, additional, and Torchilin, Vladimir P., additional

Published
2020
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40. Cross-linker-Modulated Nanogel Flexibility Correlates with Tunable Targeting to a Sterically Impeded Endothelial Marker

Author

Myerson, Jacob Wheatley, primary, McPherson, Olivia, additional, DeFrates, Kelsey G., additional, Towslee, Jenna H., additional, Marcos-Contreras, Oscar A., additional, Shuvaev, Vladimir V., additional, Braender, Bruce, additional, Composto, Russell J., additional, Muzykantov, Vladimir R., additional, and Eckmann, David M., additional

Published
2019
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41. Red blood cell-hitchhiking boosts delivery of nanocarriers to chosen organs by orders of magnitude

Author

Brenner, Jacob S., primary, Pan, Daniel C., additional, Myerson, Jacob W., additional, Marcos-Contreras, Oscar A., additional, Villa, Carlos H., additional, Patel, Priyal, additional, Hekierski, Hugh, additional, Chatterjee, Shampa, additional, Tao, Jian-Qin, additional, Parhiz, Hamideh, additional, Bhamidipati, Kartik, additional, Uhler, Thomas G., additional, Hood, Elizabeth D., additional, Kiseleva, Raisa Yu., additional, Shuvaev, Vladimir S., additional, Shuvaeva, Tea, additional, Khoshnejad, Makan, additional, Johnston, Ian, additional, Gregory, Jason V., additional, Lahann, Joerg, additional, Wang, Tao, additional, Cantu, Edward, additional, Armstead, William M., additional, Mitragotri, Samir, additional, and Muzykantov, Vladimir, additional

Published
2018
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42. Flexible Nanoparticles Reach Sterically Obscured Endothelial Targets Inaccessible to Rigid Nanoparticles

Author

Myerson, Jacob W., primary, Braender, Bruce, additional, Mcpherson, Olivia, additional, Glassman, Patrick M., additional, Kiseleva, Raisa Y., additional, Shuvaev, Vladimir V., additional, Marcos‐Contreras, Oscar, additional, Grady, Martha E., additional, Lee, Hyun‐Su, additional, Greineder, Colin F., additional, Stan, Radu V., additional, Composto, Russell J., additional, Eckmann, David M., additional, and Muzykantov, Vladimir R., additional

Published
2018
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46. Targeted Nanocarriers Co-Opting Pulmonary Intravascular Leukocytes for Drug Delivery to the Injured Brain

Author

Nong, Jia, Glassman, Patrick M., Myerson, Jacob W., Zuluaga-Ramirez, Viviana, Rodriguez-Garcia, Alba, Mukalel, Alvin, Omo-Lamai, Serena, Walsh, Landis R., Zamora, Marco E., Gong, Xijing, Wang, Zhicheng, Bhamidipati, Kartik, Kiseleva, Raisa Y., Villa, Carlos H., Greineder, Colin Fred, Kasner, Scott E., Weissman, Drew, Mitchell, Michael J., Muro, Silvia, Persidsky, Yuri, Brenner, Jacob Samuel, Muzykantov, Vladimir R., and Marcos-Contreras, Oscar A.

Abstract

Ex vivo-loaded white blood cells (WBC) can transfer cargo to pathological foci in the central nervous system (CNS). Here we tested affinity ligand driven in vivoloading of WBC in order to bypass the need for ex vivoWBC manipulation. We used a mouse model of acute brain inflammation caused by local injection of tumor necrosis factor alpha (TNF-α). We intravenously injected nanoparticles targeted to intercellular adhesion molecule 1 (anti-ICAM/NP). We found that (A) at 2 h, >20% of anti-ICAM/NP were localized to the lungs; (B) of the anti-ICAM/NP in the lungs >90% were associated with leukocytes; (C) at 6 and 22 h, anti-ICAM/NP pulmonary uptake decreased; (D) anti-ICAM/NP uptake in brain increased up to 5-fold in this time interval, concomitantly with migration of WBCs into the injured brain. Intravital microscopy confirmed transport of anti-ICAM/NP beyond the blood–brain barrier and flow cytometry demonstrated complete association of NP with WBC in the brain (98%). Dexamethasone-loaded anti-ICAM/liposomes abrogated brain edema in this model and promoted anti-inflammatory M2 polarization of macrophages in the brain. In vivotargeted loading of WBC in the intravascular pool may provide advantages of coopting WBC predisposed to natural rapid mobilization from the lungs to the brain, connected directly via conduit vessels.

Published
2023
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48. Abstract 12153: Targeting Nanoparticles to Migrating Leukocytes in the Inflamed Brain

Author

Marcos-Contreras, Oscar Armando, Greineder, Colin, Zuluaga-Ramirez, Viviana, Glassman, Patrick M, Walsh, Landis, Kiseleva, Raisa Y, Hood, Elizabeth D, Villa, Carlos, Myerson, Jacob W, Brenner, Jacob S, Persidsky, Yuri, and Muzykantov, Vladimir R

Abstract

Infiltration of leukocytes into the inflamed brain has been well characterized by multiple groups. It has been demonstrated that ex vivo loading of leukocytes (neutrophils, monocytes and macrophages) allows nanoparticle (NP)-mediated delivery to inflamed tissues, including the brain. Our preliminary results suggest that leukocytes can be targeted directly in vivo using ICAM targeted NP. Therefore, we hypothesize: i) that direct in vivo targeting of leukocytes, followed by carrier leukocyte migration to the brain will allow NP delivery to the brain and, ii) that targeted NP against leukocytes would be a therapeutically relevant target in neurovascular inflammation and stroke. In fact, the injection of intercellular adhesion molecule (ICAM)-targeted NP 2 hours after injection of tumor necrosis factor (TNF) into the brain parenchyma showed some uptake of the carrier in the brain vasculature (probably associated with leukocytes). Interestingly, imaging the same mice over the next 24 hours showed an increase of ICAM targeted NP in the brain (panel A) even reaching the brain parenchyma) with the time. As we know, ICAM targeted NP are highly accumulated in the lungs, have a very poor circulation time and are rapidly internalized. In the same line of thought, taking the same time points after TNF injury for the injection of the radiolabeled ICAM targeted NP (panel B), we observed an increase in brain uptake with time. Further analysis, by flow cytometry of brain homogenates, revealed that non-coated NP or untargeted IgG coated NP had a residual uptake into the brain (panel C). However, ICAM targeted NP were positive in ~6% of total events and nearly 100% of these events were in leukocytes. Despite the high number of infiltrated leukocytes, approximately a 15% of them contained ICAM targeted NC (panel C). All together, the data suggest that ICAM targeted NP can be uptaken by leukocytes and migrate to the inflamed brain.

Published
2019
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49. Biomechanical and Functional Features of the Carrier Erythrocytes Prolonging Circulation Time of Biotherapeutic Targeted to Glycophorin A.

Author

Peshkova AD, Brysgel TV, Mody P, Nong J, Wang Z, Myerson JW, Litvinov RI, Weisel JW, Brenner JS, Glassman PM, Marcos-Contreras OA, and Muzykantov VR

Subjects
Animals, Mice, Humans, Factor IX pharmacokinetics, Factor IX metabolism, Biomechanical Phenomena, Glycophorins metabolism, Erythrocytes metabolism
Abstract

Red blood cells (RBCs) serve as natural transporters and can be modified to enhance the pharmacokinetics and pharmacodynamics of a protein cargo. Affinity targeting of Factor IX (FIX) to the RBC membrane is a promising approach to improve the (pro)enzyme's pharmacokinetics. For RBC targeting, purified human FIX was conjugated to the anti-mouse glycophorin A monoclonal antibody Ter119. The goal of this study was to characterize the activity of the FIX-Ter119 conjugate and efficacy of its loading on RBCs, as well as to investigate the biodistribution, pharmacokinetics, and various biological properties of the loaded RBCs. Mouse RBCs were incubated with the Ter119-FIX conjugate, where adding 10,000 molecules per RBC resulted in 37% binding (4K/RBC), and 50,000 molecules per RBC resulted in 34% binding (17K/RBC). The pharmacokinetics (PK) profile showed that more than 90% of the Ter119-FIX conjugate was associated with RBCs and circulated stably bound to the RBCs for 24 h, increasing the area under the PK curve 7.6 times vs free FIX. Ter119-FIX loaded RBCs have specific procoagulant FIXa activity, including promotion of thrombin generation and acceleration of clotting in FIX-deficient plasma. Morphological characterization shows that Ter119-FIX-loaded RBCs undergo a shape change, with an increased fraction of echinocytes and spheroidal RBCs. Ektacytometry and electron microscopy assessment of RBC compressibility reveal a dose-dependent reduction in the deformability of RBCs loaded with Ter119-FIX. In conclusion, RBCs loaded with Ter119-FIX have the potential to serve as prohemostatic agents, but their reduced deformability warrants further engineering of Ter119-FIX to improve the safety profile.

Published
2025
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50. Multi-stage-mixing to control the supramolecular structure of lipid nanoparticles, thereby creating a core-then-shell arrangement that improves performance by orders of magnitude.

Author

Nong J, Gong X, Dang QM, Tiwari S, Patel M, Wu J, Hanna A, Park WJ, Atochina-Vasserman EN, Huang HT, Marcos-Contreras OA, Morris-Blanco KC, Miner JJ, Weissman D, Muzykantov VR, Gupta K, Issadore D, Myerson JW, Wang Z, and Brenner JS

Abstract

As they became the dominant gene therapy platform, lipid nanoparticles (LNPs) experienced nearly all their innovation in varying the structure of individual molecules in LNPs. This ignored control of the spatial arrangement of molecules, which is suboptimal because supramolecular structure determines function in biology. To control LNPs' supramolecular structure, we introduce multi-stage-mixing (MSM) to successively add different molecules to LNPs. We first utilize MSM to create a core-then-shell (CTS) synthesis. CTS-LNPs display a clear core-shell structure, vastly lower frequency of LNPs containing no detectable mRNA, and improved mRNA-LNP expression. With DNA-loaded LNPs, which for decades lagged behind mRNA-LNPs due to low expression, CTS improved DNA-LNPs' protein expression by 2-3 orders of magnitude, bringing it within range of mRNA-LNPs. These results show that supramolecular arrangement is critical to LNP performance and can be controlled by mixing methodology. Further, MSM/CTS have finally made DNA-LNPs into a practical platform for long-term gene expression.

Published
2025
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