Ozolomide synergistically reduces the growth of glioma xenografts. The findings presented here now provide a rational for the design of novel anticancer strategies based on the use of cannabinoid-loaded MPs in combinational therapies.ConclusionsData presented in this manuscript show for the first time that in vivo administration of microencapsulated cannabinoids efficiently reduces tumor growth thus providing a proof of concept for theCannabinoid Microparticles Inhibit Tumor Growthutilization of this formulation in cannabinoid-based anti-cancer therapies.Author ContributionsConceived and designed the experiments: GV AITS ML DH. Performed the experiments: DH ML MEG-A ST EG-T MRA JM. Analyzed the data: DH ML MEG-A GV. Contributed reagents/materials/analysis tools: MEG-A MRA JM AITS. Wrote the paper: GV DH ML.AcknowledgmentsWe thank the “Luis Bru” UCM Microscopy Research Support Centre for valuable technical and professional assistance.
Activation of enteric neural 5-HT4-receptors by mosapride citrate (MOS) promotes the reconstruction of an enteric neural circuit injured after surgery, leading to the recovery of the `defecation reflex’ [1,2] in the distal gut of guinea pigs [3]. This neural plasticity involves neural stem cells [3]. Recently, we also revealed that MOS enhances neural network formation in gut-like organs differentiated from mouse embryonic stem cells [4]. Other 5-HT4 receptor agonists also increase neuronal numbers and length of neurites in enteric neurons developing in vitro from immunoselected neural crest-derived precursors [5]. 5-HT4 receptor-mediated neuroprotection and neurogenesis has also been demonstrated in the enteric nervous system of adult mice [6]. We therefore explored the ability of MOS to promote the generation of new enteric neurons at resected sites of the mouse small intestine in vivo. The new neurons are typically located in regions of granulation tissue, which is new connective I-BRD9 tissue formed by growth of fibroblasts and blood capillaries into injured tissue after transection and reanastomosis of the gut. Unfortunately, it is impossible for traditional fluorescence microscopy including confocal microscopy to perform highresolution deep imaging of the 300?00 mm thick granulationtissue that is formed during the tissue repairing process at the anastomotic site after transection of the gut. Even in in vitro whole mount preparations, in which the mucosal, submucosal and circular muscle layers were removed, imaging of newly formed neurons and axons is severely limited. Nonlinear optical microscopy, in particular two photon-excited fluorescence microscopy, offers a means to overcome this limitation by providing enhanced optical penetration. Two-photon microscopy (2PM) allows cellular imaging several hundred microns deep in various organs of living animals and ex vivo specimens [7]. In the present study, we employed 24786787 2PM to obtain 3-dimensional reconstructions of impaired enteric neural circuits within the thick granulation tissue in the ileum of Thy1-GFP mice [8], in which the GFP is expressed in the cytoplasm of enteric neurons. Although in vivo imaging of the muscularis propria and myenteric neurons with probe-based confocal laser endomicroscopy in porcine models has been recently reported [9], we obtained the first ever (deleted) clear three-dimensional imaging of newly FCCP web generated enteric neurons within the thick granulation tissue at the anastomosis, indicating that 2PM allows enteric neural imaging several.Ozolomide synergistically reduces the growth of glioma xenografts. The findings presented here now provide a rational for the design of novel anticancer strategies based on the use of cannabinoid-loaded MPs in combinational therapies.ConclusionsData presented in this manuscript show for the first time that in vivo administration of microencapsulated cannabinoids efficiently reduces tumor growth thus providing a proof of concept for theCannabinoid Microparticles Inhibit Tumor Growthutilization of this formulation in cannabinoid-based anti-cancer therapies.Author ContributionsConceived and designed the experiments: GV AITS ML DH. Performed the experiments: DH ML MEG-A ST EG-T MRA JM. Analyzed the data: DH ML MEG-A GV. Contributed reagents/materials/analysis tools: MEG-A MRA JM AITS. Wrote the paper: GV DH ML.AcknowledgmentsWe thank the “Luis Bru” UCM Microscopy Research Support Centre for valuable technical and professional assistance.
Activation of enteric neural 5-HT4-receptors by mosapride citrate (MOS) promotes the reconstruction of an enteric neural circuit injured after surgery, leading to the recovery of the `defecation reflex’ [1,2] in the distal gut of guinea pigs [3]. This neural plasticity involves neural stem cells [3]. Recently, we also revealed that MOS enhances neural network formation in gut-like organs differentiated from mouse embryonic stem cells [4]. Other 5-HT4 receptor agonists also increase neuronal numbers and length of neurites in enteric neurons developing in vitro from immunoselected neural crest-derived precursors [5]. 5-HT4 receptor-mediated neuroprotection and neurogenesis has also been demonstrated in the enteric nervous system of adult mice [6]. We therefore explored the ability of MOS to promote the generation of new enteric neurons at resected sites of the mouse small intestine in vivo. The new neurons are typically located in regions of granulation tissue, which is new connective tissue formed by growth of fibroblasts and blood capillaries into injured tissue after transection and reanastomosis of the gut. Unfortunately, it is impossible for traditional fluorescence microscopy including confocal microscopy to perform highresolution deep imaging of the 300?00 mm thick granulationtissue that is formed during the tissue repairing process at the anastomotic site after transection of the gut. Even in in vitro whole mount preparations, in which the mucosal, submucosal and circular muscle layers were removed, imaging of newly formed neurons and axons is severely limited. Nonlinear optical microscopy, in particular two photon-excited fluorescence microscopy, offers a means to overcome this limitation by providing enhanced optical penetration. Two-photon microscopy (2PM) allows cellular imaging several hundred microns deep in various organs of living animals and ex vivo specimens [7]. In the present study, we employed 24786787 2PM to obtain 3-dimensional reconstructions of impaired enteric neural circuits within the thick granulation tissue in the ileum of Thy1-GFP mice [8], in which the GFP is expressed in the cytoplasm of enteric neurons. Although in vivo imaging of the muscularis propria and myenteric neurons with probe-based confocal laser endomicroscopy in porcine models has been recently reported [9], we obtained the first ever (deleted) clear three-dimensional imaging of newly generated enteric neurons within the thick granulation tissue at the anastomosis, indicating that 2PM allows enteric neural imaging several.