This indicates that MWNT inhibits the development of smaller/younger GPCR Compound Library research buy vessels only. Our report is consistent with the results of another study showing that pristine MWNT displayed an anti-angiogenic effect on an in vivo VEGFA/bFGF-induced model [33] and in in vitro HUVEC
tubule formation assays [34]. However, doxorubicin conjugated with single-wall nanotubes had the opposite effects [35]. As expected, nanoparticles had less impact on the development of older vessels. Only ND, which exerted the strongest anti-angiogenic properties, induced a significant decrease in vessel length and the number of branch points. However, ND did not change the area of older vessels (100 to 200 μm). Reduced length and branching without significant changes in vessel area suggest that see more ND can inhibit the development of vessels with dimensions that slightly exceed 100 μm and smaller. The present results give new insights into the bioactive properties of ND and clearly show that this carbon nanoparticle can be considered for use in low-toxicity
anti-angiogenic therapy. Interestingly, our results demonstrated pro-angiogenic activity of pristine C60, which increased the number of branch points and vessel length. Fullerene C60 has been used to inhibit cancer growth [36] and is used as photosensitisers in photodynamic therapy [37]. However, Zogovic et al. [38] studied the effect of nanocrystaline fullerene on melanoma tumour and showed that fullerene, probably by immunosuppression, had tumour-promoting activity and increased the production of nitric oxide (NO), which can promote angiogenesis [39].
Furthermore, other reactive oxygen species can Methane monooxygenase also induce angiogenesis [40]. The ability of C60 to generate reactive oxygen species has been previously demonstrated [41, 42]. NO promotes angiogenesis by up-regulating the expression of the VEGFA receptor [43], which is consistent with our report. This appears to be the most probable mechanism underlying fullerene pro-angiogenic effects and may only be specific for pristine nanoparticles. Hydroxylated C60 has been shown to protect cells in vitro form oxidative stress, while pristine nanoparticles show pro-oxidant capacity [44, 45]. Moreover, C60 modified with multihydroxylated metal can simultaneously down-regulate more than ten angiogenic factors and significantly decrease the capillary vessels of tumours (average size 1.2 cm in diameter) [46]. Murugesan et al. [33] demonstrated that pristine MWNT and C60 inhibited the angiogenesis induced by exogenous VEGFA or bFGF. Our results indicated that C60 had the opposite effect on vessels not stimulated by exogenous pro-angiogenic factors. This suggests that C60 can have both anti- and pro-angiogenic activity depending on the physiological state of blood vessels. Conclusions We compared the anti-angiogenic properties of pristine carbon nanomaterials.