D’Amato, M.; Linciano, P.; Chiarelli, L.R.; Pietrocola, G.; Iadarola, P.; Collina, S.; Grignano, M.A.; Gregorini, M.; Rampino, T.; Viglio, S.
The Differential Redox Resilience of Alvelestat and Sivelestat: A Mechanistic Hypothesis for Inhibitor Performance Under Oxidative Stress. Molecules 2026, 31, 1454.
https://doi.org/10.3390/molecules31091454
AMA Style
D’Amato M, Linciano P, Chiarelli LR, Pietrocola G, Iadarola P, Collina S, Grignano MA, Gregorini M, Rampino T, Viglio S.
The Differential Redox Resilience of Alvelestat and Sivelestat: A Mechanistic Hypothesis for Inhibitor Performance Under Oxidative Stress. Molecules. 2026; 31(9):1454.
https://doi.org/10.3390/molecules31091454
Chicago/Turabian Style
D’Amato, Maura, Pasquale Linciano, Laurent R. Chiarelli, Giampiero Pietrocola, Paolo Iadarola, Simona Collina, Maria Antonietta Grignano, Marilena Gregorini, Teresa Rampino, and Simona Viglio.
2026. "The Differential Redox Resilience of Alvelestat and Sivelestat: A Mechanistic Hypothesis for Inhibitor Performance Under Oxidative Stress" Molecules 31, no. 9: 1454.
https://doi.org/10.3390/molecules31091454
APA Style
D’Amato, M., Linciano, P., Chiarelli, L. R., Pietrocola, G., Iadarola, P., Collina, S., Grignano, M. A., Gregorini, M., Rampino, T., & Viglio, S.
(2026). The Differential Redox Resilience of Alvelestat and Sivelestat: A Mechanistic Hypothesis for Inhibitor Performance Under Oxidative Stress. Molecules, 31(9), 1454.
https://doi.org/10.3390/molecules31091454
