Coenzyme Q10 microparticles formation with supercritical carbon dioxide

Ortiz-Estrada, C.H.; Díaz-Díaz, C. Y.; Cruz-Olivares, J.; Pérez-Alonso, C.

Servicios Personalizados

Revista

Articulo

Indicadores

Citado por SciELO
Accesos

Links relacionados

Similares en SciELO

Otros
Otros

Permalink

Revista mexicana de ingeniería química

versión impresa ISSN 1665-2738

Rev. Mex. Ing. Quím vol.14 no.1 Ciudad de México ene./abr. 2015

Biotecnología

Coenzyme Q₁₀ microparticles formation with supercritical carbon dioxide

Formación de micropartículas de coenzima Q₁₀ con dióxido de carbono supercrítico

C.H. Ortiz-Estrada^1,2*, C. Y. Díaz-Díaz², J. Cruz-Olivares³ y C. Pérez-Alonso³

¹ División Científica-PF, Comisión Nacional de Seguridad-SEGOB, Av. Constituyentes 947, Col. Belén de las Flores, Deleg. Álvaro Obregón, C.P. 01110, México, D.F. *Autor para la correspondencia. E-mail: ciro.ortiz@cns.gob.mx Tel. 52 55 5277 0596.

² Departamento de Ingeniería y Ciencias Químicas, Universidad Iberoamericana, Ciudad de México. Prol. Paseo de la Reforma 880, Lomas de Santa Fe, C.P. 01219, México, D.F.

³ Facultad de Química, Universidad Autónoma del Estado de México, Paseo Tollocan esq. Paseo Colón s/n, C.P. 50120, Toluca, Estado de México, México.

Recibido 4 de Noviembre 2014
Aceptado 15 de Febrero de 2015

Abstract

Coenzyme Q₁₀ is a powerful antioxidant used on cardiovascular, neurodegenerative and cancer diseases. Its hydrophobic nature do limit its applications, because human body absorbs it with difficulty, that is why it was proposed to increase its bioavailability by diminishing the particle size using supercritical carbon dioxide. It was determined experimentally the phase behavior of the coenzyme in a supercritical system. The equilibrium data and a factorial 2^k experimental design were utilized to find how the shape and _tize of the microparticles are affected by temperature, coQ₁₀ concentration and nozzle diameter. Microparticles were characterized using infrared spectrometry and chromatography. For verify the fundamental chemical structure, the size and the shape of trie microparticles was used scanning electronic microscopy. It was found a significant decrease in particle size and a modification of physical structure. The antioxidant power of coQ₁₀ after micronization was meas ured, showing an increase of this property. Finally, in order to evaluate the bioavailability, the kinetic of solubility was determined in elhanol, having a substantial increase on solubilization speed of micronized coQ₁₀ compared with the commercial one.

Key words: coenzyme Q₁₀, bioavailability, micronization, supercritical carbon dioxide.

Resumen

La coenzima Q₁₀ es un potente antioxidante utilizado en las enfermedades cardiovasculares, neurodegenerativas y el cáncer. Su naturaleza hidrofóbica limita sus aplicaciones, ya que el cuerpo humano la absorbe con dificultad, es por eso que se propone aumentar su biodisponibilidad al disminuir el tamano de partícula utilizando dióxido de carbono supercrítico. Se determinó experimentalmente el comportamiento de fases de la coenzima en un sistema supercrítico. Los datos de equilibrio y un diseño experimental factorial 2^k se utilizaron para encontrar cómo la forma y el tamaño de las micropartículas se ven afectados por la temperatura, la concentración de coQ₁₀ y diámetro de la boquilla. Las micropartículas se caracterizaron mediante espectrometría de infrarrojo y cromatografía. Para verificar la estructura química fundamental, el tamaño y la forma de las micropartículas se utilizó microscopía electrónica de barrido. Se encontró una disminución significativa en el tamaño de partícula y una modificación de la estructura física. El poder antioxidante de coQ₁₀ micronizada se incremento de manera importante. Por último, con el fin de evaluar la biodisponibilidad, se determinó la cinética de la solubilidad en etanol, y se encontró un aumento sustancial en la velocidad de solubilización de la coQ₁₀ micronizada en comparación con la coenzima Q₁₀ comercial.

Palabras clave: coenzima Q₁₀, biodisponibilidad, micronización, dióxido de carbono supercrítico.

DESCARGAR ARTÍCULO EN FORMATO PDF

Acknowledgements

Authors wish to acknowledge the grant obtained from the Mexican National Council of Sciences and Technology, given through the project 83842.

References

Alessi, P., Cortesi, A., Kikic, I., Foster, N., Macnaugfton, S.J. and Colombo, I. (1996). Production of Steroid Drugs Using Supercritical Fluid Processing. Industrial and Engineering Chemistry Research 35, 4718-4726. [ Links ]

Benedetti, L., Bertucco, A. and Pallado, P. (1996). Production of Micronic Particles of Biocompatible Polymer Using Supercritical Carbon Dioxide. Biotechnology and Bioengineering 53, 232-237. [ Links ]

Bhagavan, H.N. and Chopra, R.K. (2007). Coenzyme Q₁₀ Response to Oral Ingestion of Coenzyme Q₁₀ Formulations. Mitochondrion 7S, S78-S88. [ Links ]

Carrillo-Navas, H., González-Rodea, D.A., Cruz-Olivares, J., Barrera-Pichardo, J.F., Román-Guerrero, A. and Pérez-Alonso, C. (2011). Storage Stability and Physicochemical Properties of Passion Fruit Juice Microcapsules by Spray-Drying. Revista Mexicana de Ingeniería Química 10, 421-430. [ Links ]

Cavin, A., Hostettmann, K., Dyatmykow, W. and Potterat, O. (1998). Antioxidant and Lipophilic Constituents of Tinospora Crispa. Planta Medica 64, 393-396. [ Links ]

Chernyak, Y., Henon, F., Harris, R.B., Gould, R.D., Franklin, R.K., Edwards, J.R., DeSimone, J.M. and Carbonell, R.G. (2001). Formation of Perfluoropolyether Coatings by the Rapid Expansion of Supercritical Solutions (RESS) Process. Part 1: Experimental Results. Industrial and Engineering Chemistry Research 40, 6118-6126. [ Links ]

Chiou, A.H., Cheng, H.C. and D.P. Wang, D.P. (2006). Micronization and Microencapsulation of Felodipine by Supercritical Carbon Dioxide. Journal of Microencapsulation 23, 265-276. [ Links ]

Cotelle, N., Bernier, J., Catteau, J., Pommery, J., Wallet, J. and Gaydou, E. (1996). Antioxidant Properties of Hidroxy-flavones. Free Radical and Medicine 20, 35-43. [ Links ]

Foster, N.R., Fariba, D., Charoenchaitrakool, M. and Warwick, B. (2003). Application of Dense Gas Techniques for the Production of Fine Particles. AAPS PharmSciTech 5, 1-7. [ Links ]

Galpern, W.R. and Cudkowic, M.E. (2007). Coenzyme Q Treatment of Neurodegenerative Diseases of Aging. Mitochondrion 7S, S146-S153. [ Links ]

Gámez, E., Luyengi, L., Lee, S., Zhu, L., Zhou, B., Fong, H., Pezzuto, J. and Kinghorn, A. (1998). Antioxidant Flavonoid Glycosides from Daphniphyllum calycinum. Journal of Natural Products 61, 706-708. [ Links ]

García-Márquez, E., Román-Guerrero, A., Pérez-Alonso, C., Cruz-Sosa, F., Jiménez-Alvarado, R. and Vernon-Carter, E.J. (2012). Effect of Solvent-Temperature Extraction Conditions on the Initial Antioxidant Activity and Total Phenolic Content of Muitle Extracts and their Decay Upon Storage at Different pH. Revista Mexicana de Ingeniería Química 11, 1-10. [ Links ]

Helfgen, B., Hils, P., Holzknecht, Ch., Türk, M. and Schaber, K. (2001). Simulation of Particle Formation During the Rapid Expansion of Supercritical Solutions. Journal of Aerosol Science 32, 295-319. [ Links ]

Huang, J. and Moriyoshi, T. (2006). Fabrication of Fine Powders by RESS with a Clearance Nozzle. Journal of Supercritical Fluids 37, 292-297. [ Links ]

Huang, Z., Sun, G.B., Chiew, Y.C. and Kawi, S. (2005). Formation of Ultrafine Aspirin Particles Through Rapid Expansion of Supercritical Solutions (RESS). Powder Technology 160, 127-134. [ Links ]

Kwauk, X. and Debenedetti, P.G.J. (1993). Mathematical Modeling of Aerosol Formation by Rapid Expansion of Supercritical Solutions in a Converging Nozzle. Journal of Aerosol Science 24, 445-469. [ Links ]

Laplante, S., Souchet, N. and Bryl, P. (2009). Comparison of Low Temperature Processes for Oil and Coenzyme Q₁₀ Extraction from Mackerel and Herring. European Journal of Lipid Science and Technology 111, 135-141. [ Links ]

Lele, A.K. and Shine, A.D. (1994). Effect of RESS Dynamics on Polymer Morphology. Industrial and Engineering Chemistry Research 33, 1476-1485. [ Links ]

Liu, G.T. and Nagahama, K. (1996). Application of Rapid Expansion of Supercritical Solutions in the Crystallization Separation. Industrial and Engineering Chemistry Research 35, 4626-4634. [ Links ]

Pecar, D. and Dolecek, V. (2007). Thermodynamic Properties of Coenzyme Q₁₀ in Supercritical Carbon Dioxide. Journal of Supercritical Fluids 40, 200-207. [ Links ]

Reverchon, E., Donsi, G. and Gorgoglione, D. (1993). Salicylic Acid Solubilization in sc-CO₂ and its Micronization by RESS. Journal of Supercritical Fluids 6, 241-248. [ Links ]

Salinas-Hernández, R., Ruiz-Treviño, F.A., Ortiz-Estrada, C.H., Luna-Barcenas, G., Prokhorov, Y., Alvarado, J.F.J. and Sanchez, I.C. (2009). Chitin Microestrucutre Formation by Rapid Expansion Techniques with Supercritical Carbon Dioxide. Industrial and Engineering Chemistry Research 48, 769-778. [ Links ]

Sane, A. and Thies, M.C. (2005). The Formation of Fluorinated Tetraphenylporphyrin Nanoparticles via Rapid Expansion Processes: RESS vs. RESOLV. The Journal of Physical Chemistry B. 109, 19688-19695. [ Links ]

Santos, O.T. and Meireles, M.A.A. (2013). Micronization and Encapsulation of Functional Pigment Using Supercritical Carbon Dioxide. Journal of Food Process Engineering 36, 36-49. [ Links ]

Santoyo-Arreola, J.G. (2006). Formación de Partículas de PFOMA mediante CO₂SC. Tesis de Maestría en Ciencias en Ingeniería Química, Universidad Iberoamericana. México. [ Links ]

Tom, J.W. and Debenedetti, P.G. (1994). Formation of Bioerodible Polymeric Microspheres and Microparticles by Rapid Expansion of Supercritical Solutions. Biotechnology Progress 7, 403-411. [ Links ]

Türk, M. (2009). Manufacture of Submicron Drug Particles with Enhanced Dissolution Behaviour by Rapid Expansion Processes. Journal of Supercritical Fluids 47, 537-545. [ Links ]

Türk, M. (2000). Influence of Thermodynamic Behaviour and Solute Properties on Homogeneous Nucleation in Supercritical Solutions. Journal of Supercritical Fluids 18, 169-184. [ Links ]

Türk, M., Hils, P., Helfgen, B. Schaber, K., Martin, H.J. and Wahl, M.A. (2002). Micronization of Pharmaceutical Substances by the Rapid Expansion of Supercritical Solutions (RESS): A Promising Method to Improve Bioavailability of Poorly Soluble Pharmaceutical Agents. Journal of Supercritical Fluids 22, 75-84. [ Links ]

Türk, M. (1999). Formation of Small Organic Particles by RESS: Experimental and Theoretical Investigations. Journal of Supercritical Fluids 1, 79-89. [ Links ]

Yildiz, N., Tuna, S., Döker, O. and Calimli, A. (2007). Micronization of Salicylic Acid and Taxol (Paclitaxel) by Rapid Expansion of Supercritical Fluids (RESS). Journal of Supercritical Fluids 41, 440-451. [ Links ]