Prodrug for Tumour Treatment

About

About this innovation Like in photodynamic therapy, such prodrugs can be used as poorly toxic antitumor treatments capable of stopping tumour growth or inducing tumour regression when light is irradiated on the tumour, which will ultimately minimize side effects for cancer patients. Due to their antitumor properties metal-based drugs such as cisplatin are commercially available as chemotherapeutic agents. Although they are very efficient for example against testicular or ovarian cancers, these metallodrugs induce severe side effects for cancer patients, such as kidney damages. In addition, acquired resistance is not uncommon. To overcome these drawbacks new anticancer agents based on ruthenium have been developed with excellent antitumor properties. However, general toxicity towards the organism remains an issue. In addition, their pharmaceutical applications are often limited by poor water solubility. To obviate these disadvantages, scientists at Leiden University developed a concept allowing for transforming a water-insoluble ruthenium anticancer compound that shows good cytotoxicity in the dark, into water-soluble, photoactivatable ruthenium-based prodrugs, which are much less toxic in the dark but can be selectively converted into an antitumor-active form upon visible light irradiation. Like in photodynamic therapy (PDT), the tumoricidal effect of the prodrug is limited at the irradiation site, thus minimizing side effects for the cancer patient. However, the mechanism of action is completely different than in PDT, which should make this new strategy eligible also in case of PDT-resistant tumours. Visible or near infrared light can be employed, which will minimize damages on living tissues. Key Benefits Potential activity against photodynamic-resistant tumours and cisplatin-resistant tumours Tumour irradiation with light enhances the local effectiveness of the drug while it minimizes side effects for the patient The prodrugs are soluble in water, allowing easier pharmaceutical preparation and different pharmacokinetics and pharmacodynamics, compared to conventional ruthenium drugs No premature release of the toxic/active species in the dark No UV-light needed; irradiation-induced damages on living tissues are minimized  Applications Anti-tumour photochemotherapy