A GSH-Responsive Prodrug with Simultaneous Triple-Activation Capacity for Photodynamic/Sonodynamic Combination Therapy with Inhibited Skin Phototoxicity.

Herein, a dual-sensitizer prodrug, named pro-THPC, has been designed to function as both a photosensitizer and a sonosensitizer prodrug for precise antitumor combination therapy with minimized skin phototoxicity. Pro-THPC could be activated by glutathione (GSH) to release the dual-sensitizer, THPC, which simultaneously switches on fluorescence emission and combined capabilities of photodynamic therapy (PDT) and sonodynamic therapy (SDT). Pro-THPC is further formulated into nanoparticles (NPs) for water dispersity to enable in vivo applications. In vivo fluorescence imaging shows that the pro-THPC NPs group exhibits a significantly higher tumor-to-normal tissue ratio (T/N) (T/N = 5.2 ± 0.55) compared to the "always on" THPC NPs group (T/N = 2.9 ± 0.47) and the pro-THPC NPs group co-administrated with GSH synthesis inhibitor (buthionine sulfoximine, BSO) (T/N = 3.2 ± 0.63). In addition, the generation of the designed dual-sensitizer's reactive oxygen species (ROS) is effectively confined within the tumor tissues due to the relatively strong correlation between ROS generation and fluorescence emission. In vivo studies further demonstrate the remarkable efficacy of the designed pro-THPC NPs to eradicate tumors through the combination of PDT and SDT while significantly reducing skin phototoxicity.

GSH-activated Porphyrin Sonosensitizer Prodrug for Fluorescence Imaging-guided Cancer Sonodynamic Therapy.

Sonodynamic therapy (SDT), which uses ultrasound to trigger a sonosensitizer to generate reactive oxygen species (ROS), is a promising form of cancer therapy with outstanding tissue penetration depth. However, the sonosensitizer may inevitably spread to surrounding healthy tissue beyond the tumor, resulting in undesired side effects under an ultrasound stimulus. Herein, as glutathione (GSH) is overexpressed in the tumor microenvironment, a GSH-activatable sonosensitizer prodrug was designed by attaching a quencher to tetraphydroxy porphyrin for tumor therapy. The prodrug exhibited poor fluorescence and low ROS generation capacity under ultrasound irradiation but it can be activated by GSH to simultaneously switch on fluorescence emission and ROS generation in tumor site. Compared with the non-quenched sonosensitizer, the designed prodrug exhibited significantly higher tumor/healthy organ fluorescence ratios, due to the specific fluorescence and ROS activation by overexpressed GSH in the tumor. Finally, the prodrug exhibited efficient tumor growth inhibition under ultrasound irradiation, further demonstrating its promise as a GSH-activated sonosensitizer prodrug for highly effective cancer treatment.

A nanoparticle composed of totally hospital-available drugs and isotope for fluorescence/SPECT dual-modal imaging-guided photothermal therapy to inhibit tumor metastasis.

As primary sites of tumor metastasis, sentinel lymph nodes (SLNs) require a highly biocompatible theranostic platform for precise localization and treatment to inhibit tumor metastasis. Herein, indocyanine green-human serum albumin (ICG-HSA) nanoparticles (NPs) were fabricated by ICG-induced self-assembly and radiolabeled with technetuim-99 m (99mTc). The fabricated NPs were composed of hospital-available drugs and isotopes, making them highly biocompatible for in vivo applications. In a mouse model of SLN metastasis, the prepared NPs exhibited excellent capacity for preoperative planning by single-photon emission computed tomography (SPECT) imaging-enabled SLN localization, near-infrared fluorescence (NIRF) imaging-enabled intraoperative real-time monitoring, and SLN photothermal treatment. Photothermal treatment with SLN enhanced the inhibition of lung metastasis and significantly increased the survival time of mice. The prepared NPs were highly biocompatible and exhibited efficient theranostic properties for inhibiting cancer metastasis, making them promising candidates for clinical translation.

Rationally assembled albumin/indocyanine green nanocomplex for enhanced tumor imaging to guide photothermal therapy.

Herein, a novel phototheranostic nanocomplex that is self-assembled from bovine serum albumin (BSA) and indocyanine green (ICG) is developed for enhanced near-infrared (NIR) fluorescence imaging, which benefits the guidance on in vivo cancer photothermal therapy (PTT). The study confirms that the binding of ICG with the bind sits on the albumin will result in improved hydrolytic stability and high photoluminescence quantum yield (PLQY). The ICG loading ratio in the nanocomplex is optimized and confirms the loading ratio of 0.5% ICG to be the optimal content. The optimized ICG-BSA nanocomplex (ICG-BSA NC) possesses a higher PLQY of 16.8% than that of free ICG (2.7%). The high PLQY and efficient passive targeting ability of ICG-BSA NC help improve its in vivo tumor accumulation and NIR fluorescence imaging significantly. Under laser irradiation, efficient PTT with obvious tumor growth suppression on a triple negative breast tumor model can be observed in the ICG-BSA NC treated group.

Nanosized Modification Strategies for Improving the Antitumor Efficacy of MEK Inhibitors.

The RAS-RAF-MEK-ERK signaling pathway (MAPK signaling) is hyperactivated in more than 30% of human cancers. The abnormal activation of this pathway is mainly due to the gain-offunction mutations in RAS or RAF genes. Furthermore, the crucial roles of mitogen-activated protein kinase kinase (MEK) in tumorigenesis, cell proliferation and apoptosis inhibition, make MEK inhibitors (MEKi) attractive candidates for the targeted therapy of MAPK pathway-related cancer. Several highly selective and potent non-ATP-competitive allosteric MEKi have been developed and have led to substantial improvements in clinical outcomes. However, the drug efficacies and response rates are limited due to complex pathway cross-talk and pessimistic drug solubility. Nanosized modifications have made great contributions to improving drug efficacies over the past decades. In this review, the important biological status of MEK kinase in the MAPK pathway is illuminated primarily to highlight the irreplaceable position and clinical status of MEKi. In addition, nanomodification strategies to enhance drug efficacy are briefly summarized, followed by the application advances of nanotechnology in the field of MEKi-related cancer theranostics. Finally, the obstacles impeding the development of nanosized MEKi are considered, and promising prospects are suggested. This informative report lays the groundwork for the clinical development of MEKi and outlines a rational frontline-treatment approach for personalized cancer treatment.