The development of novel nanoconstructs for biomedical applications requires the assessment of their biodis-tribution, metabolism and clearance in single cells, organs and entire organisms in a living environment. To reduce the number of in vivo experiments performed and to refine the methods used, in accordance with the 3Rs principle, this work proposes an ex vivo experimental system to monitor, using fluorescence microscopy, the distribution of nanoparticles in explanted murine skeletal muscle maintained in a bioreactor that can pre-serve the structural and functional features of the organ for long periods of time. Fluorescently-labelled lipo-somes and poly(lactide-co-glycolide) (PLGA)-based nanoparticles were injected into the intact soleus muscle (in the distal region close to the tendon) immediately after explants, and their distribution was analysed at increasing incubation times in cross cryosections from the proximal region of the belly. Both nanocarriers were clearly recognized in the muscle and were found to enter and migrate inside the myofibres, whereas their migra-tion in the connective tissue seemed to be limited. In addition, some fluorescence signals were observed inside the macrophages, demonstrating the physiological clearance of the nanocarriers that did not enter the myofi-bres. Our ex vivo system therefore provides more information than previous in vitro experiments on cultured muscle cells, highlighting the need for the appropriate functionalization of nanocarriers if myofibre targeting is to be improved.
An ex vivo experimental system to track fluorescent nanoparticles inside skeletal muscle / Calderan, L.; Carton, F.; Andreana, I.; Bincoletto, V.; Arpicco, S.; Stella, B.; Malatesta, M.. - In: EUROPEAN JOURNAL OF HISTOCHEMISTRY. - ISSN 2038-8306. - ELETTRONICO. - 67:3596(2023), pp. 1-6. [10.4081/ejh.2023.3596]
An ex vivo experimental system to track fluorescent nanoparticles inside skeletal muscle
Carton F.;
2023-01-01
Abstract
The development of novel nanoconstructs for biomedical applications requires the assessment of their biodis-tribution, metabolism and clearance in single cells, organs and entire organisms in a living environment. To reduce the number of in vivo experiments performed and to refine the methods used, in accordance with the 3Rs principle, this work proposes an ex vivo experimental system to monitor, using fluorescence microscopy, the distribution of nanoparticles in explanted murine skeletal muscle maintained in a bioreactor that can pre-serve the structural and functional features of the organ for long periods of time. Fluorescently-labelled lipo-somes and poly(lactide-co-glycolide) (PLGA)-based nanoparticles were injected into the intact soleus muscle (in the distal region close to the tendon) immediately after explants, and their distribution was analysed at increasing incubation times in cross cryosections from the proximal region of the belly. Both nanocarriers were clearly recognized in the muscle and were found to enter and migrate inside the myofibres, whereas their migra-tion in the connective tissue seemed to be limited. In addition, some fluorescence signals were observed inside the macrophages, demonstrating the physiological clearance of the nanocarriers that did not enter the myofi-bres. Our ex vivo system therefore provides more information than previous in vitro experiments on cultured muscle cells, highlighting the need for the appropriate functionalization of nanocarriers if myofibre targeting is to be improved.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione