Albert Sorribas - Papers (1991-1995)

  1. Fernández,E.; Betriu,M.A.; Sorribas,A.; Montoliu,J.
    Reprecusión sobre la eficacia de diálisis del aumento del hematocrito inducido por eritropoyetina humana recombiante
    Nefrología (1991) XI:66-71
  2. Prat,J.; Pamplona,R.; Sorribas,A.; Navarro,X.
    Glicación de apolipoproteinas. Implicaciones en las complicaciones cardiovasculares de la diabetes
    Cardiovascular Reviews & Reports (1991) 12:155-160
  3. Calderó,J.; Casanovas,A.; Sorribas,A; Esquerda,J.
    Calcitonin gene-related peptide in rat spinal cord motoneurons: subcellular distribution and chnages induced by axotomy Neuroscience (1992) 48:449-461
  4. Cascante, M., Sorribas, A., Franco, R., & Canela E.I., (1991). Biochemical Systems Theory: Increassing predictive power by using Second-order derivatives measurements.  J.Theor.Biol., 149, 521-535.
  5. Sorribas, A. (1991). Optimal strategies for modeling biochemical systems. In E.O. Voit (Ed.), Canonical nonlinear modeling: S-system approach to understanding complexity (pp. 67-75). New York: Van Nostrand Reinhold.
  6. Sorribas,A.; Samitier,S.; Canela,E.I.; Cascante,M.Metabolic pathway characterization from transient response data obtained in situ: parameter estimation in S-system models. J.Theor.Biol. (1993) 162:81-102
  7. Sorribas, A. & Cascante, M. (1993). Steady-state measurements and identifiability of regulatory patterns in metabolic studies. In S. Schuster (Ed.), Modern Trends in Biothermokinetics (pp. 125-131). New York: Plenum Press.
  8. Torres, N.V., Regalado, C., Sorribas, A., & Cascante, M. (1993). Quality assessment of a metabolic model and systems analysis of citric acid production by Aspergillus niger. In S. Schuster (Ed.), Modern Trends in Biothermokinetics (pp. 115-124). New York: Plenum Press.
  9. Sorribas,A.; Cascante,M. Structure identifiability in metabolic pathways: parameter estimation in models based on the power-law formalism Biochem.J. (1994) 298:303-311
  10. Cascante, M., Sorribas, A., & Canela, E.I. (1994). Enzyme-enzyme interactions and metabolite channelling: alternative mechanisms and their evolutionary significance.  Biochem.J., 298, 313-320.
  11. Cascante, M., Curto, R., & Sorribas, A. (1995). Comparative characterization of the fermentation pathway of Saccharomyces cerevisiae using biochemical systems theory and metabolic control analysis: steady-state analysis.  Math.Biosci., 130, 51-69.
  12. Curto, R., Sorribas, A., & Cascante, M. (1995). Comparative characterization of the fermentation pathway of Saccharomices cerevisiae using biochemical systems theory and metabolic control analysis: model definition and nomenclature.  Math.Biosci., 130, 25-50.
  13. Sorribas, A., Curto, R., & Cascante, M. (1995). Comparative characterization of the fermentation pathway of Saccharomyces cerevisiae using biochemical systems theory and metabolic control analysis: model validation and dynamic behavior.  Math.Biosci., 130, 71-84.
  14. Cascante, M., Curto, R., & Sorribas, A. (1995). Testing the robusthttps://www.worldscientific.com/doi/abs/10.1142/S0218339095000101ness of the steady-state characteristics of a metabolic pathway: parameter sensitivities as a basic feature for model validation.  J.Biol.Systems, 3, 105-113.
  15. Puigjaner, J., Cascante, M., & Sorribas, A. (1995). Assesing optimal designs in metabolic pathways.  J.Biol.Systems, 3, 197-206.
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