Your search keyword '"Turánek, Jaroslav"' showing total 2 results

1. Thrombus Imaging Using 3D Printed Middle Cerebral Artery Model and Preclinical Imaging Techniques: Application to Thrombus Targeting and Thrombolytic Studies.

Author

Vítečková Wünschová, Andrea, Novobilský, Adam, Hložková, Jana, Scheer, Peter, Petroková, Hana, Jiřík, Radovan, Kulich, Pavel, Bartheldyová, Eliška, Hubatka, František, Jonas, Vladimír, Mikulík, Robert, Malý, Petr, Turánek, Jaroslav, and Mašek, Josef

Subjects

CEREBRAL arteries, THREE-dimensional imaging, TISSUE plasminogen activator, FIBRIN, THROMBOSIS, X-ray computed microtomography

Abstract

Diseases with the highest burden for society such as stroke, myocardial infarction, pulmonary embolism, and others are due to blood clots. Preclinical and clinical techniques to study blood clots are important tools for translational research of new diagnostic and therapeutic modalities that target blood clots. In this study, we employed a three-dimensional (3D) printed middle cerebral artery model to image clots under flow conditions using preclinical imaging techniques including fluorescent whole-body imaging, magnetic resonance imaging (MRI), and computed X-ray microtomography (microCT). Both liposome-based, fibrin-targeted, and non-targeted contrast agents were proven to provide a sufficient signal for clot imaging within the model under flow conditions. The application of the model for clot targeting studies and thrombolytic studies using preclinical imaging techniques is shown here. For the first time, a novel method of thrombus labeling utilizing barium sulphate (Micropaque®) is presented here as an example of successfully employed contrast agents for in vitro experiments evaluating the time-course of thrombolysis and thus the efficacy of a thrombolytic drug, recombinant tissue plasminogen activator (rtPA). Finally, the proof-of-concept of in vivo clot imaging in a middle cerebral artery occlusion (MCAO) rat model using barium sulphate-labelled clots is presented, confirming the great potential of such an approach to make experiments comparable between in vitro and in vivo models, finally leading to a reduction in animals needed. [ABSTRACT FROM AUTHOR]

Published

2020

2. Targeting Human Thrombus by Liposomes Modified with Anti-Fibrin Protein Binders.

Author

Petroková, Hana, Mašek, Josef, Kuchař, Milan, Vítečková Wünschová, Andrea, Štikarová, Jana, Bartheldyová, Eliška, Kulich, Pavel, Hubatka, František, Kotouček, Jan, Turánek Knotigová, Pavlína, Vohlídalová, Eva, Héžová, Renata, Mašková, Eliška, Macaulay, Stuart, Dyr, Jan Evangelista, Raška, Milan, Mikulík, Robert, Malý, Petr, and Turánek, Jaroslav

Subjects

FIBRIN, RIBOSOMES, THROMBOSIS, LIPOSOMES, ENZYME-linked immunosorbent assay, PROTEINS, G proteins

Abstract

Development of tools for direct thrombus imaging represents a key step for diagnosis and treatment of stroke. Nanoliposomal carriers of contrast agents and thrombolytics can be functionalized to target blood thrombi by small protein binders with selectivity for fibrin domains uniquely formed on insoluble fibrin. We employed a highly complex combinatorial library derived from scaffold of 46 amino acid albumin-binding domain (ABD) of streptococcal protein G, and ribosome display, to identify variants recognizing fibrin cloth in human thrombus. We constructed a recombinant target as a stretch of three identical fibrin fragments of 16 amino acid peptide of the Bβ chain fused to TolA protein. Ribosome display selection followed by large-scale Enzyme-Linked ImmunoSorbent Assay (ELISA) screening provided four protein variants preferentially binding to insoluble form of human fibrin. The most specific binder variant D7 was further modified by C-terminal FLAG/His-Tag or double His-tag for the attachment onto the surface of nanoliposomes via metallochelating bond. D7-His-nanoliposomes were tested using in vitro flow model of coronary artery and their binding to fibrin fibers was demonstrated by confocal and electron microscopy. Thus, we present here the concept of fibrin-targeted binders as a platform for functionalization of nanoliposomes in the development of advanced imaging tools and future theranostics. [ABSTRACT FROM AUTHOR]

Published

2019