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4. DYNAMIC MR IMAGING, BIODISTRIBUTION AND PHARMACOKINETICS OF POLYMER SHELLED MICROBUBBLES CONTAINING SPION

Author

Barrefelt, Åsa, Paradossi, Gaio, Asem, Heba, Margheritelli, Silvia, Saghafian, Maryam, Oddo, Letizia, Muhammed, Mamoun, Aspelin, Peter, Hassan, Moustapha, Brismar, Torkel B., Barrefelt, Åsa, Paradossi, Gaio, Asem, Heba, Margheritelli, Silvia, Saghafian, Maryam, Oddo, Letizia, Muhammed, Mamoun, Aspelin, Peter, Hassan, Moustapha, and Brismar, Torkel B.

Abstract

Magnetic Resonance Imaging (MRI) is a noninvasive diagnostic method that provides information on morphological and physiological changes of the internal organs over time. Imaging and measurements can be repeated on the same subject, thereby reducing inter-individual variability effects and hence the number of subjects required. A potential MRI contrast agent consisting of microbubbles embedded with superparamagnetic iron oxide nanoparticles (SPION) in the shell (SPION MBs) was injected intravenously into rats to determine their biodistribution and pharmacokinetics using MR imaging. Agarose phantoms containing SPION MBs were scanned using 3 T MRI to construct a standard curve. Rats were injected with SPION MBs, free SPION or plain MBs and scanned dynamically at 3 T using a clinical MR scanner. The relaxation rate (R2*) was studied over time as a measure of the iron oxide concentrations to enable calculation of the pharmacokinetic parameters. The kinetics of SPION MBs in the liver was fitted to a one-compartment model. Furthermore, the biological fate of SPION MBs was examined via a histological survey of tissue samples using Perls' Prussian blue staining and immunohistochemistry (IHC). 1.2 h after injection of SPION MBs, T2* of the liver had decreased to its minimum. The elimination half-life of SPION MBs was 598.2 +/- 97.3 h, while the half-life for SPION was 222.6 +/- 26.4 h. Moreover, our study showed that SPION MBs were taken up by the macrophages in the lungs, spleen and liver. MBs labeled with SPION can be used for MR imaging. Moreover, MRI is a reliable and noninvasive tool that can be utilized in pharmacokinetic investigations of future contrast agents using SPION MBs and SPION in the rat., QC 20141103

Published
2014
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5. Biodistribution, kinetics, and biological fate of SPION microbubbles in the rat

Author

Barrefelt, Åsa, Saghafian, Maryam, Kuiper, Raoul, Ye, Fei, Egri, Gabriella, Klickermann, Moritz, Brismar, Torkel B., Aspelin, Peter, Muhammed, Mamoun, Daehne, Lars, Hassan, Moustapha, Barrefelt, Åsa, Saghafian, Maryam, Kuiper, Raoul, Ye, Fei, Egri, Gabriella, Klickermann, Moritz, Brismar, Torkel B., Aspelin, Peter, Muhammed, Mamoun, Daehne, Lars, and Hassan, Moustapha

Abstract

Background: In the present investigation, we studied the kinetics and biodistribution of a contrast agent consisting of poly(vinyl alcohol) (PVA) microbubbles containing superparamagnetic iron oxide (SPION) trapped between the PVA layers (SPION microbubbles). Methods: The biological fate of SPION microbubbles was determined in Sprague-Dawley rats after intravenous administration. Biodistribution and elimination of the microbubbles were studied in rats using magnetic resonance imaging for a period of 6 weeks. The rats were sacrificed and perfusion-fixated at different time points. The magnetic resonance imaging results obtained were compared with histopathologic findings in different organs. Results: SPION microbubbles could be detected in the liver using magnetic resonance imaging as early as 10 minutes post injection. The maximum signal was detected between 24 hours and one week post injection. Histopathology showed the presence of clustered SPION microbubbles predominantly in the lungs from the first time point investigated (10 minutes). The frequency of microbubbles declined in the pulmonary vasculature and increased in pulmonary, hepatic, and splenic macrophages over time, resulting in a relative shift from the lungs to the spleen and liver. Meanwhile, macrophages showed increasing signs of cytoplasmic iron accumulation, initially in the lungs, then followed by other organs. Conclusion: The present investigation highlights the biological behavior of SPION microbubbles, including organ distribution over time and indications for biodegradation. The present results are essential for developing SPION microbubbles as a potential contrast agent and/or a drug delivery vehicle for specific organs. Such a vehicle will facilitate the use of multimodality imaging techniques, including ultrasound, magnetic resonance imaging, and single positron emission computed tomography, and hence improve diagnostics, therapy, and the ability to monitor the efficacy of treatment., QC 20130906

Published
2013
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6. Thermostable Luciferase from Luciola cruciate for Imaging of Carbon Nanotubes and Carbon Nanotubes Carrying Doxorubicin Using in Vivo Imaging System

Author

El-Sayed, Ramy, Eita, Mohamed, Barrefelt, Åsa, Ye, Fei, Jain, Himanshu, Fares, Mona, Lundin, Arne, Crona, Mikael, Abu-Salah, Khalid, Muhammed, Mamoun, Hassan, Moustapha, El-Sayed, Ramy, Eita, Mohamed, Barrefelt, Åsa, Ye, Fei, Jain, Himanshu, Fares, Mona, Lundin, Arne, Crona, Mikael, Abu-Salah, Khalid, Muhammed, Mamoun, and Hassan, Moustapha

Abstract

In the present study, we introduce a novel method for in vivo imaging of the biodistribution of single wall carbon nanotubes (SWNTs) labeled with recombinant thermo-stable Luciola cruciata luciferase (LcL). In addition, we highlight a new application for green fluorescent proteins in which they are utilized as imaging moieties for SWNTs. Carbon nanotubes show great positive potential compared to other drug nanocarriers with respect to loading capacity, cell internalization, and biodegradability. We have also studied the effect of binding mode (chemical conjugation and physical adsorption) on the chemiluminescence activity, decay rate, and half-life. We have shown that through proper chemical conjugation of LcL to CNTs, LcL remained biologically active for the catalysis of D-luciferin in the presence of ATP to release detectable amounts of photons for in vivo imaging. Chemiluminescence of LcL allows imaging of CNTs and their cargo in nonsuperficial locations at an organ resolution with no need of an excitation source. Loading LcL-CNTs with the antitumor antibiotic doxorubicin did not alter their biological activity for imaging. In vivo imaging of LcL-CNTs has been carried out using "IVIS spectrum" showing the uptake of LcL-CNTs by different organs in mice. We believe that the LcL-CNT system is an advanced powerful tool for in vivo imaging and therefore a step toward the advancement of the nanomellicine field., QC 20130521

Published
2013
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7. Magnetite Nanoparticles Can Be Coupled to Microbubbles to Support Multimodal Imaging

Author

Brismar, Torkel B., Grishenkov, Dmitry, Gustafsson, Björn, Härmark, Johan, Barrefelt, Åsa, Kothapalli, Satya V. V. N., Margheritelli, Silvia, Oddo, Letizia, Caidahl, Kenneth, Hebert, Hans, Paradossi, Gaio, Brismar, Torkel B., Grishenkov, Dmitry, Gustafsson, Björn, Härmark, Johan, Barrefelt, Åsa, Kothapalli, Satya V. V. N., Margheritelli, Silvia, Oddo, Letizia, Caidahl, Kenneth, Hebert, Hans, and Paradossi, Gaio

Abstract

Microbubbles (MBs) are commonly used as injectable ultrasound contrast agent (UCA) in modern ultrasonography. Polymer-shelled UCAs present additional potentialities with respect to marketed lipid-shelled UCAs. They are more robust; that is, they have longer shelf and circulation life, and surface modifications are quite easily accomplished to obtain enhanced targeting and local drug delivery. The next generation of UCAs will be required to support not only ultrasound-based imaging methods but also other complementary diagnostic approaches such as magnetic resonance imaging or computer tomography. This work addresses the features of MBs that could function as contrast agents for both ultrasound and magnetic resonance imaging. The results indicate that the introduction of iron oxide nanoparticles (SPIONs) in the poly(vinyl alcohol) shell or on the external surface of the MBs does not greatly decrease the echogenicity of the host MBs compared with the unmodified one. The presence of SPIONs provides enough magnetic susceptibility to the MBs to accomplish good detectability both in vitro and in vivo. The distribution of SPIONs on the shell and their aggregation state seem to be key factors for the optimization of the transverse relaxation rate., QC 20150626

Published
2012
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8. Biodistribution, kinetics, and biological fate of SPION microbubbles in the rat.

Author

Barrefelt Å, Saghafian M, Kuiper R, Ye F, Egri G, Klickermann M, Brismar TB, Aspelin P, Muhammed M, Dähne L, and Hassan M

Subjects
Animals, Contrast Media chemistry, Contrast Media pharmacokinetics, Dextrans chemistry, Magnetite Nanoparticles chemistry, Male, Metabolic Clearance Rate, Organ Specificity physiology, Rats, Rats, Sprague-Dawley, Tissue Distribution, Capsules chemistry, Capsules pharmacokinetics, Dextrans pharmacokinetics, Magnetic Resonance Imaging methods, Polyvinyl Alcohol chemistry, Whole Body Imaging methods
Abstract

Background: In the present investigation, we studied the kinetics and biodistribution of a contrast agent consisting of poly(vinyl alcohol) (PVA) microbubbles containing superparamagnetic iron oxide (SPION) trapped between the PVA layers (SPION microbubbles)., Methods: The biological fate of SPION microbubbles was determined in Sprague-Dawley rats after intravenous administration. Biodistribution and elimination of the microbubbles were studied in rats using magnetic resonance imaging for a period of 6 weeks. The rats were sacrificed and perfusion-fixated at different time points. The magnetic resonance imaging results obtained were compared with histopathologic findings in different organs., Results: SPION microbubbles could be detected in the liver using magnetic resonance imaging as early as 10 minutes post injection. The maximum signal was detected between 24 hours and one week post injection. Histopathology showed the presence of clustered SPION microbubbles predominantly in the lungs from the first time point investigated (10 minutes). The frequency of microbubbles declined in the pulmonary vasculature and increased in pulmonary, hepatic, and splenic macrophages over time, resulting in a relative shift from the lungs to the spleen and liver. Meanwhile, macrophages showed increasing signs of cytoplasmic iron accumulation, initially in the lungs, then followed by other organs., Conclusion: The present investigation highlights the biological behavior of SPION microbubbles, including organ distribution over time and indications for biodegradation. The present results are essential for developing SPION microbubbles as a potential contrast agent and/or a drug delivery vehicle for specific organs. Such a vehicle will facilitate the use of multimodality imaging techniques, including ultrasound, magnetic resonance imaging, and single positron emission computed tomography, and hence improve diagnostics, therapy, and the ability to monitor the efficacy of treatment.

Published
2013
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