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4. Improved cellular uptake of perfluorocarbon nanoparticles for in vivo murine cardiac 19F MRS/MRI and temporal tracking of progenitor cells

Author

Constantinides, C, McNeill, E, Carnicer, R, Al Haj Zen, A, Sainz-Urruela, R, Shaw, Andrew, Patel, J, Swider, E, Alonaizan, R, Potamiti, L, Hadjisavvas, A, Padilla-Parra, S, Kyriacou, K, Srinivas, M, Carr, C.A, Constantinides, C, McNeill, E, Carnicer, R, Al Haj Zen, A, Sainz-Urruela, R, Shaw, Andrew, Patel, J, Swider, E, Alonaizan, R, Potamiti, L, Hadjisavvas, A, Padilla-Parra, S, Kyriacou, K, Srinivas, M, and Carr, C.A

Abstract

Herein, we maximize the labeling efficiency of cardiac progenitor cells (CPCs) using perfluorocarbon nanoparticles (PFCE-NP) and 19F MRI detectability, determine the temporal dynamics of single-cell label uptake, quantify the temporal viability/fluorescence persistence of labeled CPCs in vitro, and implement in vivo, murine cardiac CPC MRI/tracking that could be translatable to humans. FuGENEHD-mediated CPC PFCE-NP uptake is confirmed with flow cytometry/confocal microscopy. Epifluorescence imaging assessed temporal viability/fluorescence (up to 7 days [D]). Nonlocalized murine 19F MRS and cardiac MRI studied label localization in terminal/longitudinal tracking studies at 9.4 T (D1-D8). A 4-8 fold 19F concentration increase is evidenced in CPCs for FuGENE vs. directly labeled cells. Cardiac 19F signals post-CPC injections diminished in vivo to ~31% of their values on D1 by D7/D8. Histology confirmed CPC retention, dispersion, and macrophage-induced infiltration. Intra-cardiac injections of PFCE-NP-labeled CPCs with FuGENE can be visualized/tracked in vivo for the first time with 19F MRI.

Published
2019

5. Fast, quantitative, murine cardiac ¹⁹F MRI/MRS of PFCE-labeled progenitor stem cells and macrophages at 9.4T

Author

Constantinides, C, Maguire, M, McNeill, E, Carnicer, R, Swider, E, Srinivas, M, Carr, CA, and Schneider, JE

Abstract

Purpose: To a) achieve cardiac ¹⁹F-Magnetic Resonance Imaging (MRI) of perfluoro-crown-ether (PFCE) labeled cardiac progenitor stem cells (CPCs) and bone-derived bone marrow macrophages, b) determine label concentration and cellular load limits, and c) achieve spectroscopic and image-based quantification.\ud \ud \ud \ud Methods: Theoretical simulations and experimental comparisons of spoiled-gradient echo (SPGR), rapid acquisition with relaxation enhancement (RARE), and steady state at free precession (SSFP) pulse sequences, and phantom validations, were conducted using ¹⁹F MRI/Magnetic Resonance Spectroscopy (MRS) at 9.4 T. Successful cell labeling was confirmed using flow cytometry and confocal microscopy. For CPC and macrophage concentration quantification, in vitro and post-mortem cardiac validations were pursued with the use of the transfection agent FuGENE. Feasibility of fast imaging is demonstrated in murine cardiac acquisitions in vivo, and in post-mortem murine skeletal and cardiac applications.\ud \ud \ud \ud Results: SPGR/SSFP proved favorable imaging sequences yielding good signal-to-noise ratio values. Confocal microscopy confirmed heterogeneity of cellular label uptake in CPCs. ¹⁹F MRI indicated lack of additional benefits upon label concentrations above 7.5–10 mg/ml/million cells. The minimum detectable CPC load was ~500k (~10k/voxel) in two-dimensional (2D) acquisitions (3–5 min) using the butterfly coil. Additionally, absolute ¹⁹F based concentration and intensity estimates (trifluoroacetic-acid solutions, macrophages, and labeled CPCs in vitro and post-CPC injections in the post-mortem state) scaled linearly with fluorine concentrations. Fast, quantitative cardiac ¹⁹F-MRI was demonstrated with SPGR/SSFP and MRS acquisitions spanning 3–5 min, using a butterfly coil.\ud \ud \ud \ud Conclusion: The developed methodologies achieved in vivo cardiac ¹⁹F of exogenously injected labeled CPCs for the first time, accelerating imaging to a total acquisition of a few minutes, providing evidence for their potential for possible translational work.

Published
2018

6. In Vivo Tracking and 1H/19F Magnetic Resonance Imaging of Biodegradable Polyhydroxyalkanoate / Polycaprolactone Blend Scaffolds Seeded with Labeled Cardiac Stem Cells

Author

Constantinides, C., Basnett, P., Lukasiewicz, B., Carnicer, R., Swider, E., Majid, Q.A., Srinivas, M., Carr, C.A., and Roy, I.

Subjects
19F magnetic resonance spectroscopy/imaging, cardiac progenitor stem cells, cardiac regeneration, polycaprolactone, polyhydroxyalkanoates, polymer blends, polymer scaffolds
Abstract

Medium-chain length Polyhydroxyalkanoates (MCL-PHAs) have demonstrated exceptional properties for cardiac tissue engineering (CTE) applications. Despite prior work on MCL-PHA/Polycaprolactone (PCL) blends, optimal scaffold production and use as an alternative delivery route for controlled release of seeded cardiac progenitor cells (CPCs) in CTE applications in vivo has been lacking, We present herein applicability of MCL-PHA/PCL (95/5 wt%) blends fabricated as thin films with an improved performance compared to the neat MCL-PHA aiming to a) benefit from the material properties of natural and synthetic polymers, b) achieve controlled delivery and increase retention of delivered cells to the murine myocardium, c) extend the temporal window over which the release of labeled CPCs occurs compared to traditional direct injection techniques, and d) use 19F MRI/MRS to noninvasively detect, and longitudinally monitor the seeded scaffolds. Polymer characterization confirmed the chemical structure and composition of the synthesized scaffolds, while thermal, wettability, and mechanical properties were also investigated and compared in neat and porous counterparts. In vitro cytocompatibility studies were performed using perfluorocrown-ether (PFCE)-nanoparticle-labeled murine cardiac progenitor cells (CPC), and studied using confocal microscopy and 19F MRS/MRI. Seeded scaffolds were implanted and studied in the post-mortem murine heart in situ, and in two additional C57BL/6 mice in vivo (using single-layered and double-layered scaffolds) and imaged immediately after and at 7 days post-implantation. Superior MCL-PHA/PCL scaffold performance has been demonstrated compared to MCL-PHA through experimental comparisons of a) morphological data using scanning electron microscopy and b) contact angle measurements attesting to improved CPC adhesion, c) in vitro confocal microscopy showing increased SC proliferative capacity, d) mechanical testing that elicited good overall responses. In vitro MRI results justify the increased seeding density, increased in vitro MRI signal, and improved MRI visibility in vivo, in the double-layered compared to the single-layered scaffolds. Histological evaluations (bright-field, cytoplasmic (Atto647) and nuclear (DAPI) stains) performed in conjunction with confocal microscopy imaging attest to CPC binding within the scaffold, subsequent release and migration to the neighboring myocardium, and to increased retention in the murine myocardium in the case of the double-layered scaffold. Thus MCL-PHA/PCL blends possess tremendous potential for controlled delivery of CPCs and to maximize possible regeneration in myocardial infarction.

Published
2018

8. Temporal accumulation and localization of isoflurane in the C57BL/6 mouse and assessment of its potential contamination in 19F MRI with perfluoro-crown ether- labeled cardiac progenitor cells at 9.4 T

Author

Constantinides, C, Maguire, M, Stork, L, Swider, E, Srinivas, M, Carr, CA, and Schneider, J

Abstract

Purpose: To assess the uptake, accumulation, temporal stability, and spatial localization of isoflurane (ISO) in the C57BL/6 mouse, and to identify its potential interference with the detection of labeled cardiac progenitor cells using 19F MRI/MRS. Materials and Methods: Objectives are demonstrated using a) in vitro ISO tests, b) in vivo temporal accumulation/spatial localization C57BL/6 studies (n=3), and c) through injections of perfluoro-crown-ether (PFCE)-labeled cardiac progenitor cells into femoral muscle areas of the murine hindlimb post-mortem (n=1) using 1H/19F MRI/MRS at 9.4 T. Data were acquired using double-gated spoiled gradient echo images and pulse-acquire spectra. For the in vivo study, the temporal stability of ISO resonances was quantified using coefficient of variability [CV] (5 min) estimates. Results: Two ISO resonances were observed in vivo that correspond to the -CF3 and -OCHF2 moieties. CV values ranged between 3.2–6.4% (CF3) and 6.4–11.2% (CHOF2). Reductions of the ISO dose (2.0 to 1.7%) at 80 min post-induction had insignificant effects on ISO signals (p=0.23, p=0.71). PFCE labeled cells exhibited a resonance at -16.25 ppm in vitro that did not overlap with the ISO resonances, a finding that is confirmed with MRS post-mortem using injected labeled cells. Based on 19F MRI, similar in vivo/post-mortem ISO compartmentalization was also confirmed in peripheral and thoracic skeletal muscles. Conclusion: Significant ISO accumulation was observed by 19F MRS in vivo with temporally stable signals over 90 min post-induction. ISO effects on PFCE labels are anticipated to be minimal but may be more prominent for perfluoropolyether or perfluorooctyl bromide labels.

Published
2016
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11. Total System Hazards Analysis for the Western Area Demilitarization Facility

Author

IIT RESEARCH INST CHICAGO IL, Pape,R., Mniszewski,K., Swider,E., IIT RESEARCH INST CHICAGO IL, Pape,R., Mniszewski,K., and Swider,E.

Abstract

The results of a hazards analysis of the Western Area Demilitarization facility (WADF) at Hawthorne, Nevada are summarized. This paper contains an overview of the WADF systems, the hazards analysis methodology that was applied, a general discussion of the fault tree analysis results, and a compilation of the conclusions and recommendations for each area of the facility. (Author), This article is from 'Minutes of the Explosives Safety Seminar (21st) Held at Houston, Texas on 28-30 August 1984. Volume 2,' AD-A152 150, p1529-1551.

Published
1984

12. Air Gun Test Facility

Author

IIT RESEARCH INST CHICAGO IL, Napadensky,H., Swider,E., Waterman,T., Pape,R., IIT RESEARCH INST CHICAGO IL, Napadensky,H., Swider,E., Waterman,T., and Pape,R.

Abstract

This paper describes a facility that is potentially useful in providing data for models to predict the effects of nuclear explosions on cities. IIT Research Institute has a large air gun facility capable of launching heavy items of a wide variety of geometries to velocities ranging from about 80 fps to 1100 fps. The facility and its capabilities are described, and city model problem areas capable of investigation using the air gun are presented. (Author), This article is from the Proceedings of the Asilomar Conference on Fire and Blast Effects of Nuclear Weapons (17th), 30 May-3 Jun 83, Asilomar Conference Center, Pacific Grove, CA., AD-A132 780, p144-149.

Published
1980

13. Conceptual Combat Footwear Study

Author

IIT RESEARCH INST CHICAGO IL, MacDonald, J L, Swider, E, IIT RESEARCH INST CHICAGO IL, MacDonald, J L, and Swider, E

Abstract

A series of footwear uppers and outsole concepts are presented to provide expedient donning and doffing and aid in improving traction effectiveness for the foot soldier. Manufacturing processes and material use relative to the concepts are studied and prototype models constructed which indicate compatibility with production requirements and utilization. Three concepts were then selected and final design versions conceived and constructed. These models incorporate one version of a quick closure upper with three different versions of traction aided molded outsoles.

Published
1974

16. Continuous-Flow Production of Perfluorocarbon-Loaded Polymeric Nanoparticles: From the Bench to Clinic.

Author

Hoogendijk E, Swider E, Staal AHJ, White PB, van Riessen NK, Glaßer G, Lieberwirth I, Musyanovych A, Serra CA, Srinivas M, and Koshkina O

Subjects
Cells, Cultured, Humans, Magnetic Resonance Imaging, Microfluidic Analytical Techniques, Molecular Structure, Particle Size, Surface Properties, Theranostic Nanomedicine, Fluorocarbons chemistry, Nanoparticles chemistry, Polylactic Acid-Polyglycolic Acid Copolymer chemistry
Abstract

Perfluorocarbon-loaded nanoparticles are powerful theranostic agents, which are used in the therapy of cancer and stroke and as imaging agents for ultrasound and 19 F magnetic resonance imaging (MRI). Scaling up the production of perfluorocarbon-loaded nanoparticles is essential for clinical translation. However, it represents a major challenge as perfluorocarbons are hydrophobic and lipophobic. We developed a method for continuous-flow production of perfluorocarbon-loaded poly(lactic- co -glycolic acid) (PLGA) nanoparticles using a modular microfluidic system, with sufficient yields for clinical use. We combined two slit interdigital micromixers with a sonication flow cell to achieve efficient mixing of three phases: liquid perfluorocarbon, PLGA in organic solvent, and aqueous surfactant solution. The production rate was at least 30 times higher than with the conventional formulation. The characteristics of nanoparticles can be adjusted by changing the flow rates and type of solvent, resulting in a high PFC loading of 20-60 wt % and radii below 200 nm. The nanoparticles are nontoxic, suitable for 19 F MRI and ultrasound imaging, and can dissolve oxygen. In vivo 19 F MRI with perfluoro-15-crown-5 ether-loaded nanoparticles showed similar biodistribution as nanoparticles made with the conventional method and a fast clearance from the organs. Overall, we developed a continuous, modular method for scaled-up production of perfluorocarbon-loaded nanoparticles that can be potentially adapted for the production of other multiphase systems. Thus, it will facilitate the clinical translation of theranostic agents in the future.

Published
2020
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17. Nanoparticles for "two color" 19 F magnetic resonance imaging: Towards combined imaging of biodistribution and degradation.

Author

Koshkina O, White PB, Staal AHJ, Schweins R, Swider E, Tirotta I, Tinnemans P, Fokkink R, Veltien A, van Riessen NK, van Eck ERH, Heerschap A, Metrangolo P, Baldelli Bombelli F, and Srinivas M

Subjects
Cell Survival, Cells, Cultured, Fluorocarbons chemistry, Humans, Leukocytes, Mononuclear chemistry, Leukocytes, Mononuclear cytology, Molecular Structure, Nanoparticles chemistry, Particle Size, Surface Properties, Color, Fluorine-19 Magnetic Resonance Imaging, Fluorocarbons metabolism, Leukocytes, Mononuclear metabolism, Nanoparticles metabolism
Abstract

The use of polymeric nanoparticles (NPs) as therapeutics has been steadily increasing over past decades. In vivo imaging of NPs is necessary to advance the therapeutic performance. 19 F Magnetic Resonance Imaging ( 19 F MRI) offers multiple advantages for in vivo imaging. However, design of a probe for both biodistribution and degradation has not been realized yet. We developed polymeric NPs loaded with two fluorocarbons as promising imaging tools to monitor NP biodistribution and degradation by 19 F MRI. These 200 nm NPs consist of poly(lactic-co-glycolic acid) (PLGA) loaded with perfluoro-15-crown-5 ether (PFCE) and PERFECTA. PERFECTA/PFCE-PLGA NPs have a fractal sphere structure, in which both fluorocarbons are distributed in the polymeric matrix of the fractal building blocks, which differs from PFCE-PLGA NPs and is unique for fluorocarbon-loaded colloids. This structure leads to changes of magnetic resonance properties of both fluorocarbons after hydrolysis of NPs. PERFECTA/PFCE-PLGA NPs are colloidally stable in serum and biocompatible. Both fluorocarbons show a single resonance in 19 F MRI that can be imaged separately using different excitation pulses. In the future, these findings may be used for biodistribution and degradation studies of NPs by 19 F MRI in vivo using "two color" labeling leading to improvement of drug delivery agents., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2020
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19. Improved cellular uptake of perfluorocarbon nanoparticles for in vivo murine cardiac 19 F MRS/MRI and temporal tracking of progenitor cells.

Author

Constantinides C, McNeill E, Carnicer R, Al Haj Zen A, Sainz-Urruela R, Shaw A, Patel J, Swider E, Alonaizan R, Potamiti L, Hadjisavvas A, Padilla-Parra S, Kyriacou K, Srinivas M, and Carr CA

Subjects
Animals, Cell Survival, Female, Fluorescence, Mice, Inbred C57BL, Signal-To-Noise Ratio, Time Factors, Cell Tracking, Endocytosis, Fluorine chemistry, Fluorocarbons metabolism, Magnetic Resonance Imaging, Myocardium cytology, Nanoparticles chemistry, Stem Cells metabolism
Abstract

Herein, we maximize the labeling efficiency of cardiac progenitor cells (CPCs) using perfluorocarbon nanoparticles (PFCE-NP) and 19 F MRI detectability, determine the temporal dynamics of single-cell label uptake, quantify the temporal viability/fluorescence persistence of labeled CPCs in vitro, and implement in vivo, murine cardiac CPC MRI/tracking that could be translatable to humans. FuGENE HD -mediated CPC PFCE-NP uptake is confirmed with flow cytometry/confocal microscopy. Epifluorescence imaging assessed temporal viability/fluorescence (up to 7 days [D]). Nonlocalized murine 19 F MRS and cardiac MRI studied label localization in terminal/longitudinal tracking studies at 9.4 T (D1-D8). A 4-8 fold 19 F concentration increase is evidenced in CPCs for FuGENE vs. directly labeled cells. Cardiac 19 F signals post-CPC injections diminished in vivo to ~31% of their values on D1 by D7/D8. Histology confirmed CPC retention, dispersion, and macrophage-induced infiltration. Intra-cardiac injections of PFCE-NP-labeled CPCs with FuGENE can be visualized/tracked in vivo for the first time with 19 F MRI., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2019
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20. Multicore Liquid Perfluorocarbon-Loaded Multimodal Nanoparticles for Stable Ultrasound and 19 F MRI Applied to In Vivo Cell Tracking.

Author

Koshkina O, Lajoinie G, Bombelli FB, Swider E, Cruz LJ, White PB, Schweins R, Dolen Y, van Dinther EAW, van Riessen NK, Rogers SE, Fokkink R, Voets IK, van Eck ERH, Heerschap A, Versluis M, de Korte CL, Figdor CG, de Vries IJM, and Srinivas M

Abstract

Ultrasound is the most commonly used clinical imaging modality. However, in applications requiring cell-labeling, the large size and short active lifetime of ultrasound contrast agents limit their longitudinal use. Here, 100 nm radius, clinically applicable, polymeric nanoparticles containing a liquid perfluorocarbon, which enhance ultrasound contrast during repeated ultrasound imaging over the course of at least 48 h, are described. The perfluorocarbon enables monitoring the nanoparticles with quantitative 19 F magnetic resonance imaging, making these particles effective multimodal imaging agents. Unlike typical core-shell perfluorocarbon-based ultrasound contrast agents, these nanoparticles have an atypical fractal internal structure. The nonvaporizing highly hydrophobic perfluorocarbon forms multiple cores within the polymeric matrix and is, surprisingly, hydrated with water, as determined from small-angle neutron scattering and nuclear magnetic resonance spectroscopy. Finally, the nanoparticles are used to image therapeutic dendritic cells with ultrasound in vivo, as well as with 19 F MRI and fluorescence imaging, demonstrating their potential for long-term in vivo multimodal imaging., Competing Interests: Conflict of Interest The authors declare no conflict of interest.

Published
2019
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21. Förster Resonance Energy Transfer-Based Stability Assessment of PLGA Nanoparticles in Vitro and in Vivo.

Author

Swider E, Maharjan S, Houkes K, van Riessen NK, Figdor C, Srinivas M, and Tagit O

Abstract

The knowledge of in vitro and in vivo stability of polymeric nanoparticles is vital for the development of clinical formulations for drug delivery and cell labeling applications. Förster resonance energy transfer (FRET)-based fluorescence labeling approaches are promising tools to study nanoparticle stability under different physiological conditions. Here, we present the FRET-based stability assessment of poly(lactic- co -glycolic acid) (PLGA) nanoparticles encapsulating BODIPY-FL12 and Nile Red as the donor and acceptor, respectively. The stability of PLGA nanoparticles is studied via monitoring the variations of fluorescence emission characteristics along with colloidal characterization. Accordingly, PLGA nanoparticles are colloidally stable for more than 2 weeks when incubated in aqueous buffers in situ, whereas in vitro particle degradation starts in between 24 and 48 h, reaching a complete loss of FRET at 72 h as shown with fluorescence microscopy imaging and flow cytometry analysis. PLGA nanoparticles systemically administered to mice predominantly accumulate in the liver, in which FRET no longer takes place at time points as early as 24 h postadministration as determined by ex vivo organ imaging and flow cytometry analysis. The results of this study expand our knowledge on drug release and degradation behavior of PLGA nanoparticles under different physiological conditions, which will prove useful for the rational design of PLGA-based formulations for various applications that can be translated into clinical practice., Competing Interests: The authors declare no competing financial interest.

Published
2019
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22. In Vivo Tracking and 1 H/ 19 F Magnetic Resonance Imaging of Biodegradable Polyhydroxyalkanoate/Polycaprolactone Blend Scaffolds Seeded with Labeled Cardiac Stem Cells.

Author

Constantinides C, Basnett P, Lukasiewicz B, Carnicer R, Swider E, Majid QA, Srinivas M, Carr CA, and Roy I

Subjects
Animals, Heart, Magnetic Resonance Imaging, Mice, Mice, Inbred C57BL, Polyesters, Stem Cells, Tissue Engineering, Tissue Scaffolds, Polyhydroxyalkanoates chemistry
Abstract

Medium-chain length polyhydroxyalkanoates (MCL-PHAs) have demonstrated exceptional properties for cardiac tissue engineering (CTE) applications. Despite prior work on MCL-PHA/polycaprolactone (PCL) blends, optimal scaffold production and use as an alternative delivery route for controlled release of seeded cardiac progenitor cells (CPCs) in CTE applications in vivo has been lacking. We present herein applicability of MCL-PHA/PCL (95/5 wt %) blends fabricated as thin films with an improved performance compared to the neat MCL-PHA. Polymer characterization confirmed the chemical structure and composition of the synthesized scaffolds, while thermal, wettability, and mechanical properties were also investigated and compared in neat and porous counterparts. In vitro cytocompatibility studies were performed using perfluorocrown-ether-nanoparticle-labeled murine CPCs and studied using confocal microscopy and 19 F magnetic resonance spectroscopy and magnetic resonance imaging (MRI). Seeded scaffolds were implanted and studied in the postmortem murine heart in situ and in two additional C57BL/6 mice in vivo (using single-layered and double-layered scaffolds) and imaged immediately after and at 7 days postimplantation. Superior MCL-PHA/PCL scaffold performance has been demonstrated compared to MCL-PHA through experimental comparisons of (a) morphological data using scanning electron microscopy and (b) contact angle measurements attesting to improved CPC adhesion, (c) in vitro confocal microscopy showing increased SC proliferative capacity, and (d) mechanical testing that elicited good overall responses. In vitro MRI results justify the increased seeding density, increased in vitro MRI signal, and improved MRI visibility in vivo, in the double-layered compared to the single-layered scaffolds. Histological evaluations [bright-field, cytoplasmic (Atto647) and nuclear (4',6-diamidino-2-phenylindole) stains] performed in conjunction with confocal microscopy imaging attest to CPC binding within the scaffold, subsequent release and migration to the neighboring myocardium, and increased retention in the murine myocardium in the case of the double-layered scaffold. Thus, MCL-PHA/PCL blends possess tremendous potential for controlled delivery of CPCs and for maximizing possible regeneration in myocardial infarction.

Published
2018
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23. Clinically-Applicable Perfluorocarbon-Loaded Nanoparticles For In vivo Photoacoustic, 19 F Magnetic Resonance And Fluorescent Imaging.

Author

Swider E, Daoudi K, Staal AHJ, Koshkina O, van Riessen NK, van Dinther E, de Vries IJM, de Korte CL, and Srinivas M

Abstract

Photoacoustic imaging (PAI) is an emerging biomedical imaging technique that is now coming to the clinic. It has a penetration depth of a few centimeters and generates useful endogenous contrast, particularly from melanin and oxy-/deoxyhemoglobin. Indocyanine green (ICG) is a Food and Drug Administration-approved contrast agents for human applications, which can be also used in PAI. It is a small molecule dye with limited applications due to its fast clearance, rapid protein binding, and bleaching effect. Methods: Here, we entrap ICG in a poly(lactic- co -glycolic acid) nanoparticles together with a perfluorocarbon (PFC) using single emulsion method. These nanoparticles and nanoparticle-loaded dendritic cells were imaged with PA, 19 F MR, and fluorescence imaging in vitro and in vivo . Results: We formulated particles with an average diameter of 200 nm. The encapsulation of ICG within nanoparticles decreased its photobleaching and increased the retention of the signal within cells, making it available for applications such as cell imaging. As little as 0.1x10 6 cells could be detected in vivo with PAI using automated spectral unmixing. Furthermore, we observed the accumulation of ICG signal in the lymph node after subcutaneous injection of nanoparticles. Conclusion: We show that we can label primary human dendritic cells with the nanoparticles and image them in vitro and in vivo , in a multimodal manner. This work demonstrates the potential of combining PAI and 19 F MRI for cell imaging and lymph node detection using nanoparticles that are currently produced at GMP-grade for clinical use., Competing Interests: Competing Interests: The authors have declared that no competing interest exists.

Published
2018
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24. Customizing poly(lactic-co-glycolic acid) particles for biomedical applications.

Author

Swider E, Koshkina O, Tel J, Cruz LJ, de Vries IJM, and Srinivas M

Subjects
Animals, Humans, Microfluidics instrumentation, Microfluidics methods, Biocompatible Materials chemistry, Materials Testing, Polylactic Acid-Polyglycolic Acid Copolymer chemistry
Abstract

Nano- and microparticles have increasingly widespread applications in nanomedicine, ranging from drug delivery to imaging. Poly(lactic-co-glycolic acid) (PLGA) particles are the most widely-applied type of particles due to their biocompatibility and biodegradability. Here, we discuss the preparation of PLGA particles, and various modifications to tailor particles for applications in biological systems. We highlight new preparation approaches, including microfluidics and PRINT method, and modifications of PLGA particles resulting in novel or responsive properties, such as Janus or upconversion particles. Finally, we describe how the preparation methods can- and should-be adapted to tailor the properties of particles for the desired biomedical application. Our aim is to enable researchers who work with PLGA particles to better appreciate the effects of the selected preparation procedure on the final properties of the particles and its biological implications., Statement of Significance: Nanoparticles are increasingly important in the field of biomedicine. Particles made of polymers are in the spotlight, due to their biodegradability, biocompatibility, versatility. In this review, we aim to discuss the range of formulation techniques, manipulations, and applications of poly(lactic-co-glycolic acid) (PLGA) particles, to enable a researcher to effectively select or design the optimal particles for their application. We describe the various techniques of PLGA particle synthesis and their impact on possible applications. We focus on recent developments in the field of PLGA particles, and new synthesis techniques that have emerged over the past years. Overall, we show how the chemistry of PLGA particles can be adapted to solve pressing biological needs., (Copyright © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published
2018
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25. Design of triphasic poly(lactic- co -glycolic acid) nanoparticles containing a perfluorocarbon phase for biomedical applications.

Author

Swider E, Staal AHJ, Koen van Riessen N, Jacobs L, White PB, Fokkink R, Janssen GJ, van Dinther E, Figdor CG, de Vries IJM, Koshkina O, and Srinivas M

Abstract

Poly(lactic- co -glycolic acid) (PLGA) particles are very widely used, particularly for drug delivery, including commercial clinical formulations. Adding perfluorocarbon (PFC) enables in vivo imaging and quantification of the PLGA particles through 19 F NMR, MRS or MRI. PFCs are both hydrophobic and lipophobic at the same time. This property makes their encapsulation in particles challenging, as it requires the addition of a third immiscible phase during the emulsification process. Here we explore how different parameters affect the miniemulsion formation of particles loaded with perfluoro-15-crown-5-ether (PFCE). By changing the concentration of surfactant and type of solvent, we were able to control the radius of synthesized particles, between 85-200 nm. We assessed stability and release from the particles at different pH values, showing that hydrophobic agents are released from the particles by diffusion rather than degradation. With cell experiments, we show that primary human dendritic cells take up the particles without any apparent effect, including on cell migration. In summary, the control of synthesis conditions leads to particles with sufficient PFCE encapsulation, which are suitable for drug loading and cell labeling, and do not affect cell viability or functionality. Finally, these nanoparticles can be produced at GMP-grade for clinical use., Competing Interests: There are no conflicts of interest to declare., (This journal is © The Royal Society of Chemistry.)

Published
2018
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26. Fast, quantitative, murine cardiac 19F MRI/MRS of PFCE-labeled progenitor stem cells and macrophages at 9.4T.

Author

Constantinides C, Maguire M, McNeill E, Carnicer R, Swider E, Srinivas M, Carr CA, and Schneider JE

Subjects
Animals, Mice, Microscopy, Confocal, Phantoms, Imaging, Fluorine-19 Magnetic Resonance Imaging methods, Heart diagnostic imaging, Macrophages cytology, Stem Cells cytology
Abstract

Purpose: To a) achieve cardiac 19F-Magnetic Resonance Imaging (MRI) of perfluoro-crown-ether (PFCE) labeled cardiac progenitor stem cells (CPCs) and bone-derived bone marrow macrophages, b) determine label concentration and cellular load limits, and c) achieve spectroscopic and image-based quantification., Methods: Theoretical simulations and experimental comparisons of spoiled-gradient echo (SPGR), rapid acquisition with relaxation enhancement (RARE), and steady state at free precession (SSFP) pulse sequences, and phantom validations, were conducted using 19F MRI/Magnetic Resonance Spectroscopy (MRS) at 9.4 T. Successful cell labeling was confirmed using flow cytometry and confocal microscopy. For CPC and macrophage concentration quantification, in vitro and post-mortem cardiac validations were pursued with the use of the transfection agent FuGENE. Feasibility of fast imaging is demonstrated in murine cardiac acquisitions in vivo, and in post-mortem murine skeletal and cardiac applications., Results: SPGR/SSFP proved favorable imaging sequences yielding good signal-to-noise ratio values. Confocal microscopy confirmed heterogeneity of cellular label uptake in CPCs. 19F MRI indicated lack of additional benefits upon label concentrations above 7.5-10 mg/ml/million cells. The minimum detectable CPC load was ~500k (~10k/voxel) in two-dimensional (2D) acquisitions (3-5 min) using the butterfly coil. Additionally, absolute 19F based concentration and intensity estimates (trifluoroacetic-acid solutions, macrophages, and labeled CPCs in vitro and post-CPC injections in the post-mortem state) scaled linearly with fluorine concentrations. Fast, quantitative cardiac 19F-MRI was demonstrated with SPGR/SSFP and MRS acquisitions spanning 3-5 min, using a butterfly coil., Conclusion: The developed methodologies achieved in vivo cardiac 19F of exogenously injected labeled CPCs for the first time, accelerating imaging to a total acquisition of a few minutes, providing evidence for their potential for possible translational work.

Published
2018
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