Cancer is rapidly becoming the top killer in the world. Most of the FDA approved anticancer drugs are organic molecules, while metallodrugs are very scarce. The advent of first metal based therapeutic agent, cisplatin, launched a new era in the application of transition metal complexes for therapeutic design. Due to their unique and versatile biochemical properties, ruthenium-based compounds have emerged as promising anti-cancer agents that serve as alternatives to cisplatin and its derivertives. The ruthenium(III) complexes have successfully been used in clinical research and their mechanisms of anticancer action have been reported in large volumes over the past few decades. Ruthenium(II) complexes have also attracted significant attention as anticancer candidates; however, only few of them have been reported comprehensively. In this review, we discuss the development of ruthenium(II) complexes as anticancer candidates and biocatalysts, including arene ruthenium complexes, polypyridyl ruthenium complexes, and ruthenium nanomaterial complexes. This review focuses on the likely mechanisms of action of ruthenium(II)-based anticancer drugs and the relationship between their chemical structures and biological properties. This review also highlights the catalytic activity and the photoinduced activation of ruthenium(II) complexes, their targeted delivery, and their activity in nanomaterial systems.
We report the rational design and photodynamic anticancer mechanism studies of iridium(iii) complexes with pH-responsive singlet oxygen (1O2) production and lysosome-specific imaging properties.
Recently, coordinatively saturated and substitutionally inert Ru(II) complexes have been investigated as anticancer agents. Herein a cyclometalated Ru(II) complex, [Ru(bpy)(phpy)(dppz)](+), was found to be rapidly taken up by cancer cells, and nearly 90% of the complex accumulated in the nuclei of cancer cells after a 2 h incubation. The anticancer activity of this complex was screened against a panel of cancer cell lines. Remarkably, it exhibited IC50 values that were an order of magnitude lower than those of cisplatin. This complex also displayed potencies superior to those of cisplatin against 3D tumor spheroids. Further studies revealed that the high DNA binding affinity of [Ru(bpy)(phpy)(dppz)](+) resulted in effective disruption of the binding of transcription factor NF-κB to DNA sequences, thereby inhibiting cellular transcription and leading to irreversible cancer cell apoptosis. Our work provides new insights into understanding the biological interactions and anticancer molecular mechanisms of DNA-specific Ru(II) polypyridyl complexes.
We report a rational design and mechanism studies of mitochondria-immobilized iridium(iii) complexes that can kill cancer cells by targeting mitochondrial metabolism.
Combination therapy shows great promise in circumventing cisplatin resistance. We report herein the development of a novel nanoscale drug delivery system (nDDS) based nanotherapeutic that combines chemotherapy and photodynamic therapy (PDT) into one single platform to achieve synergistic anticancer capacity to conquer cisplatin resistance. Mesoporous silica nanoparticle (MSNs) was used as the drug delivery vector to conjugate cisplatin prodrug and to load photosensitizer chlorin e6 (Ce6) to afford the dual drug loaded delivery system MSNs/Ce6/Pt. The hybrid nanoparticles have an average diameter of about 100 nm and slightly positive surface charge of about 18.2 mV. The MSNs/Ce6/Pt nanoparticles can be efficiently internalized by cells through endocytosis, thereby achieving much higher cellular Pt uptake than cisplatin in cisplatin-resistant A549R lung cancer cells. After 660 nm light irradiation (10 mW/cm(2)), the cellular reactive oxygen species (ROS) level in MSNs/Ce6/Pt treated cells was elevated dramatically. As a result of these properties, MSNs/Ce6/Pt exhibited very potent anticancer activity against A549R cells, giving a half-maximal inhibitory concentration (IC50) value for the combination therapy of 0.53 μM, much lower than that of cisplatin (25.1 μM). This study suggests the great potential of nDDS-based nanotherapeutic for combined chemo-photodynamic therapy to circumvent cisplatin resistance.
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