Introducción: Las nanopartículas tienen diversas aplicaciones científicas y tecnológicas. Su aplicación en el tratamiento tumoral constituye un campo de investigación abierto y en continuo desarrollo.

Objetivos: Modelar por simulación Monte Carlo una nanopartícula radiactiva de ¹⁹⁹Au y analizar su distribución de dosis.

Métodos: Una nanopartícula de ¹⁹⁹Au, de 200 nm de diámetro, se ubicó en el centro geométrico del modelo celular. El código PENELOPE v.2014 se empleó para calcular y cuantificar la distribución y el perfil de dosis de las partículas beta menos (β-) y gamma (γ) emitidas en la desintegración radiactiva de la nanopartícula de ¹⁹⁹Au en el interior de la célula.

Resultados: La cantidad depositada por las partículas β- resultó 100 veces mayor y con menor dispersión que la depositada por las γ. La simulación mostró que la dosis se deposita completamente dentro de la célula y que, en general, el rango de la radiación γ es mayor.

Conclusiones: PENELOPE v.2014 constituye una herramienta adecuada para el modelaje de célula simple con nanopartícula de ¹⁹⁹Au incorporada, y para obtener las distribuciones y perfiles de dosis que generan las partículas emitidas durante el decaimiento. Debido a la baja toxicidad y al alto grado de selección de la nanopartícula de ¹⁹⁹Au, sus aplicaciones en la terapia contra el cáncer se consideran prometedoras.

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