Metallacarboranes in Medicinal Chemistry: Current Advances and Future Perspectives.

Metallacarboranes, exemplified by cobalt bis(dicarbollide) ([COSAN]-), have excelled their historical metallocene analogue label to become promising in drug design, medical studies, and fundamental biological research. Serving as a unique platform for conjugation with biomolecules, they also constitute an auspicious building block for biologically active derivatives and a carrier for cellular transport of membrane-impermeable cargos. Modified [COSAN]- exhibits specific antimicrobial, antiviral, and anticancer actions showing promise for preclinical trials. Contributing to the ongoing development in medicinal chemistry, metallacarboranes offer desirable physicochemical properties and low acute toxicity. This article presents a critical look at metallacarboranes in the context of their application in medicinal chemistry, emphasizing [COSAN]- as a potential game-changer in drug design and biomedical sciences. As medicinal chemistry seeks innovative building blocks, metallacarboranes emerge as an important novelty with versatile solutions and promising implications.

Structural Patterns Enhancing the Antibacterial Activity of Metallacarborane-Based Antibiotics.

Healthcare systems heavily rely on antibiotics to treat bacterial infections, but the widespread presence of multidrug-resistant bacteria puts this strategy in danger. Novel drugs capable of overcoming current resistances are needed if our ability to treat bacterial infections is to be maintained. Boron clusters offer a valuable possibility to create a new class of antibiotics and expand the chemical space of antibiotics beyond conventional carbon-based molecules. In this work, we identified two promising structural patterns providing cobalta bis(dicarbollide)(COSAN)-based compounds with potent and selective activity toward Staphylococcus aureus (including clinical strains): introduction of the α-amino acid amide and addition of iodine directly to the metallacarborane cage. Furthermore, we found that proper hydrophilic-lipophilic balance is crucial for the selective activity of the tested compounds toward S. aureus over mammalian cells. The patterns proposed in this paper can be useful in the development of metallacarborane-based antibiotics with potent antibacterial properties and low cytotoxicity.

Cobalt bis(dicarbollide) is a DNA-neutral pharmacophore.

Cobalt bis(dicarbollide) (COSAN) is a metallacarborane used as a versatile pharmacophore to prepare biologically active hybrid organic-inorganic compounds or to improve the pharmacological properties of nucleosides, antisense oligonucleotides, and DNA intercalators. Despite these applications, COSAN interactions with nucleic acids remain unclear, limiting further advances in metallacarborane-based drug development. Although some studies showed that COSAN intercalates into DNA, COSAN-containing intercalators do not, and while COSAN shows low cytotoxicity, intercalators are often highly toxic. The present study aimed at comprehensively characterizing interactions between COSAN and DNA using a wide range of techniques, including UV-Vis absorption, circular (CD) and linear (LD) dichroism, nuclear magnetic resonance (NMR) spectroscopy, thermal denaturation, viscosity, differential scanning calorimetry (DSC), isothermal titration calorimetry (ITC), and equilibrium dialysis measurements. Our results showed that COSAN has no effect on DNA structure, length, stability, or hybridization, with no or only faint signs of COSAN binding to DNA. Moreover, DNA is not necessary for COSAN to induce cytotoxicity at high concentrations, as shown by in vitro experiments. These findings demonstrate that COSAN is a DNA-neutral pharmacophore, thus confirming the general safety and biocompatibility of metallacarboranes and opening up new opportunities for further developing metallacarborane-based drugs.

Metallacarborane Derivatives as Innovative Anti-Candida albicans Agents.

Infections caused by Candida species have increased significantly in the past decades and are among the leading causes of morbidity and mortality worldwide, resulting in serious public health problems. Currently, conventional antifungals are often ineffective as Candida spp. have developed growing resistance to systemic drugs. Since inorganic metallacarboranes are known to affect cellular events, new derivatives of these abiotic compounds were tested against Candida albicans. Compounds based on cobalt bis-dicarbollide [COSAN] were studied on Candida albicans strains, including a panel of 100 clinical isolates. The presented data prove that metallacarborane derivatives are effective against clinical isolates of Candida albicans, even those resistant to systemic drugs, and show synergistic potential in combination with amphotericin B, and low toxicity against human cells and Danio rerio embryos. This paper is a consequential step in the investigations of the broad spectrum and valuable future medical applications of metallacarboranes, especially in the fight against drug-resistant pathogens.