posted on 2018-04-12, 00:00authored byXiang-long Tang, Feng Jing, Ben-lan Lin, Sheng Cui, Ru-tong Yu, Xiao-dong Shen, Ting-wei Wang
By
overcoming drug resistance and subsequently enhancing the treatment,
the combination therapy of photodynamic therapy (PDT) and chemotherapy
has promising potential for cancer treatment. However, the major challenge
is how to establish an advanced nanoplatform that can be efficiently
guided to tumor sites and can then stably release both chemotherapy
drugs and a photosensitizer simultaneously and precisely. In this
study, which considered the possibility and targeting efficiency of
a magnetic targeting strategy, a novel Fe3O4@mSiO2(DOX)@HSA(Ce6) nanoplatform was successfully built;
this platform could be employed as an efficient synergistic antitumor
nanoplatform with magnetic guidance for highly specific targeting
and retention. Doxorubicin (DOX) molecules were loaded into mesoporous
silica with high loading capability, and the mesoporous channels were
blocked by a polydopamine coating. Human serum albumin (HSA) was conjugated
to the outer surface to increase the biocompatibility and blood circulation
time, as well as to provide a vehicle for loading photosensitizer
chlorin e6 (Ce6). The sustained release of DOX under acidic conditions
and the PDT induced by red light exerted a synergistic inhibitory
effect on glioma cells. Our experiments demonstrated that the pH-responsive
Fe3O4@mSiO2(DOX)@HSA(Ce6) nanoplatform
was guided to the tumor region by magnetic targeting and that the
nanoplatform suppressed glioma tumor growth efficiently, implying
that the system is a highly promising photodynamic therapy/chemotherapy
combination nanoplatform with synergistic effects for cancer treatment.