Desarrollo preclínico de antagonistas de canales TRPM8 para el tratamiento de la alodinia asociada a quimioterapia antitumoral

• Autores: Cristina Martín Escura
• Directores de la Tesis: María del Rosario González Muñiz (dir. tes.), Ana María Roa Arranz (codir. tes.)
• Lectura: En la Universidad de Alcalá ( España ) en 2021
• Idioma: español
• Tribunal Calificador de la Tesis: Jesus Mari Aizpurua Iparraguirre (presid.), Ana María Cuadro Palacios (secret.), Asia Fernández Carvajal (voc.)
• Programa de doctorado: Programa de Doctorado en Química Médica por la Universidad Complutense de Madrid; la Universidad de Alcalá y la Universidad San Pablo-CEU
• Materias:
  • Ciencias médicas
    • Patología
      • Neuropatología
• Enlaces
  • Tesis en acceso abierto en:  TESEO  e_Buah 
• Resumen
  • español

    La neuropatía periférica inducida por quimioterapia (CIPN) es una disfunción de los nervios del sistema periférico, que se produce en la mayoría de pacientes tratados con dosis altas de quimioterapia. La búsqueda de tratamientos efectivos para CIPN es un objetivo biomédico todavía no bien resuelto. Puesto que los canales TRPM8 están involucrados en la hipersensibilidad al frío inducida por quimioterapia, la modulación de estos canales podría ser una alternativa terapéutica a estudiar. Nuestro grupo de investigación descubrió una serie de compuestos ß-lactámicos antagonistas de canales TRPM8 que se recogen en la patente WO2017005950, licenciada a Alodia Farmacéutica SL. El trabajo de esta tesis de doctorado industrial se centró, por una parte, en el desarrollo de una ß-lactama, seleccionada entre los compuestos descritos en la patente, como ingrediente neurocosmético para aliviar la neuropatía periférica asociada a quimioterapia.

    Para ello, se realizó el escalado del producto seleccionado, obteniéndose un procedimiento que transcurre con mejores rendimientos y de manera más sostenible. Tras la caracterización in vitro y los estudios requeridos por las agencias reguladoras, los preparados cosméticos están listos para ser comercializados. Por otra parte, se sintetizaron nuevos análogos para establecer relaciones estructura-actividad e iniciar la caracterización farmacológica preclínica de los compuestos de esta familia, de cara a un futuro tratamiento farmacológico. Se han obtenido antagonistas potentes y selectivos de canales TRPM8 de rata y humanos, cuya actividad se ha confirmado también mediante estudios de electrofisiología. Como primeras pruebas de concepto, estos antagonistas de canales TRPM8 han mostrado actividad analgésica in vivo en tres modelos animales diferentes, que incluyen la neuropatía inducida por oxilaplatino, el dolor neuropático tras ligadura del nervio ciático y el dolor migrañoso inducido por nitroglicerina.

  • English

    Chemotherapy-Induced Peripheral Neuropathy (CIPN) is a dysfrunction of the peripheral system nerves, which is developed in many patients receiving standard doses of Chemotherapy, and in almost all patients treated with high doses. To date, there are no effective therapeutic strategies to combat this pathology, which causes pain, cold sensitivity, parestesia, inflammation and muscle weakness, normally starting by hands and feet. There are several experimental evidences that implicate TRPM8 channels in the cold hypersensitivity caused by chemotherapy, so the modulation of these channels could be considered a therapeutic alternative to treat CIPN.

    A few years ago, our research group discovered a series of β-lactam compounds that behave as TRPM8 channel antagonists (patent WO2017005950). After the interest of Alodia Farmacéutica SL in these compounds, the company licensed the patent, and we started the industrial PhD, program described in this report.

    Two main objectives were proposed: 1) To develop a β-lactam, selected among the patent compounds, as a neurocosmetic ingredient to alleviate cold allodynia induced by chemotherapeutic treatments. 2) To start the preclinical development of this family of compounds in order to find a topical treatment for this pathology.

    To achive the first objective, in Chapter 1, we describe the scale-up synthesis of the selected β-lactam, initially based on the patent procedure, and subsequently carried out under GLPs (Good Laboratory Practice), through modifications in some reaction steps. Next, the in vitro characterization of the pure selected compound, including activity on rat and human TRPM8 channels, selectivity against other pain-related receptors, and dermal irritancy and mutagenicity were performed. Finally, β-lactam was formulated into cosmetic preparations (hand cream and foot cream) and the dermal absortion, termal stability and the ability of the preservative against microbial contamination were studied.

    This part of the work concluded in the approval of the selected β-lactam as a neurocosmetic ingredient and in two creams that will be lanched to the market soon. As for to the second objective, in Chapter 2, we describe new β-lactam derivatives, prepared for stablishing structure-activity relationships (>50 new derivatives).

    Preliminary evaluation, identified 4-carboxamide derivatives as more potent compounds than the model β-lactam. Alternative synthesis strategies for the formation of these 2-azetidinones were also explored: while the combination of multicomponent UGI and cyclization reactions led to product mixtures, and solid-phase methodologies using a “Safety Catch”-resin did not allow cleavable compounds, a benzyl-type Wang-resin allowed the preparation of 4-carboxylate intermediates, without any intermediate purificaction. Moreover, studies on the influence of the configuration on the TRPM8 antagonist activity showed the best results for 3R,4R,2’R isomers. Finally, a photoswitchable β-lactam allowed the control of the TRPM8 antagonist activity by light.

    In Chapter 3, the pharmacological characterization of a selection of these new compounds was detailed. Initially, the preliminary activity was confirmed by electrophysiology (Patch-Clamp) and in HEK cells expressing the human hTRPM8 channels, showing that the compounds are also active. In addition, we performed selectivity studies, by measuring the activity against other pain-related channels and receptors, and evaluation of ADME pharmacokinetis properties. Finally, three animal pain models were used for the in vivo preclinical assays. Despite a fast metabolism in liver microsomes, the selected β-lactams were able to reduce cold allodynia in mice with peripheral neuropathy after chemotherapy (i.pl.), and cold and mechanical allodynia in a rat model of neurophatic pain (CCI, i.pl. and i.p.). One of these β-lactams also reduced migraineous pain in male mice and, preferentially, in female mice after i.v. administration.