A triple enhanced permeable gold nanoraspberry designed for positive feedback interventional therapy.

Due to the unique microenvironment, nanoparticles cannot easily penetrate deeply into tumours, which decreases their therapeutic efficacy. Thus, new strategies should be developed to solve this problem and increase the efficacy of nanomedicine. In this study, gold nanoraspberries (GNRs) were constructed using ultrasmall gold nanospheres (UGNPs) with a matrix metalloproteinase (MMP)-2/9-sensitive peptide as a cross-linking agent. These UGNPs were then modified with trastuzumab (TRA) and mertansine derivatives (DM1) via the AuS bond. TRA targets the human epidermal growth factor receptor-2 (Her-2) which is overexpressed on Her-2 breast cancer cells. The AuS bond in GNRs-DM1 can be replaced by the free sulfhydryl group of GSH, which could achieve GSH dependent redox responsive release of the drug. In the mouse model of Her-2 breast cancer, a "positive feedback" triple enhanced penetration platform was construct to treat tumours. Firstly, near-infrared light-triggered photothermal conversion increased vascular permeability, resulting in nanoparticle penetration. Secondly, GNRs disintegrated into UGNPs in response to stimulation with MMPs. GNRs with larger particle sizes reached the tumour site through EPR effect and active targeting. Meanwhile, UGNPs with smaller particle sizes penetrated deeply into the tumour through diffusion. Thirdly, the UGNPs transformed activated cancer-associated fibroblasts to a quiescent state, which reduced intercellular pressure and promoted the penetration of the UGNPs into the interior of the tumour. In turn, an increase in the number of nanoparticles penetrating into the tumour led to a "positive feedback" loop of triple enhanced photothermal effects and further self-amplify the permeability in vivo. Interventional photothermal therapy (IPTT) was used to improve the therapeutic efficacy by reducing the laser power attenuation caused by percutaneous irradiation. The GNRs also showed excellent multimode imaging (computed tomography, photoacoustic imaging and photothermal imaging) capabilities and high anti-tumour efficacy due to efficient tumour targeting and triple enhanced deep penetration into the tumour site. Thus, these MMP-2/redox dual-responsive GNRs are promising carriers of drugs targeting human epidermal growth factor receptor 2+ breast cancer.