27. Transport of glucose by the plasma membrane affects the removal and concentration of Ca2+ at rest in neurons - Implications of a condition prior to Alzheimer´s disease? Alves V.S., Arcisio-Miranda M., Carrettiero D.C., Oliveira F.A. Neuroscience, v. 431, p. 52 - 63, 2020. [Article link]

​

26. A comparison of activity, toxicity, and conformation of tritrpticin and two TOAC-labeled analogues. Effects on the mechanism of action. Bozelli J.C. Jr, Salay L.C., Arcisio-Miranda M., Procopio J., Riciluca K.C.T., Silva Junior P.I., Nakaie C.R., Schreier S. Biochim Biophys Acta Biomembr., v. 1862, p. 183110, 2020. [Article link]

​

25. Calcium Signaling in Neurons and Glial Cells: Role of Cav1 channels. Alves V.S., Alves-Silva H.S., Orts D.J.B., Ribeiro-Silva L., Arcisio-Miranda M., Oliveira F.A. Neuroscience, v. 421, p. 95-111, 2019. [Article link]

​

24. Synthesis and Characterization of peptide-chitosan (PepChis) with lipid bilayer affinity and antibacterial activity. Petrin T.H., Fadel V., Martins D.B., Dias S.A., Cruz A., Sergio L.M., Arcisio-Miranda M., Castanho M.S., Dos Santos Cabrera M.P. Biomacromolecules, v.20, p. 2743-2753, 2019. [Article link]

​

23. AbeTx1 is a novel sea anemone toxin with dual mechanism of action on Shaker-type K+ channels activation. B Orts D.J., Silva-Gonçalves L.C., Arcisio-Miranda M., P W Bicudo J.E., Tytgat L. Marine Drugs, v.16, p. E360, 2018. [Article link]

​

22. Pro-necrotic Activity of Cationic Mastoparan Peptides in Human Glioblastoma Multiforme Cells Via Membranolytic Action. da Silva A.M.B., Silva-Gonçalves L.C., Oliveira F.A., Arcisio-Miranda M. Molecular Neurobiology, v. 55, p. 5490-5504, 2018. [Article link]

​

21. Chitosan derivatives targeting lipid bilayers: Synthesis, biological activity and interaction with model membranes. Martins D.B., Nasário F.D., Silva-Gonçalves L.C., de Oliveira Tiera V.A., Arcisio-Miranda M., Tiera M.J., Dos Santos Cabrera M.P. Carbohydrate Polymers, v. 181, p. 1213-1223, 2018. [Article link] 

​

20. Down-regulation of Kir2.6 channel by c-termini mutation D252N and its association with the susceptibility to Thyrotoxic Periodic Paralysis. Paninka R.M., Carlos-Lima E., Lindsey S.C., Kunii I.S., Dias-da-Silva M.R., Arcisio-Miranda M. Neuroscience, v. 346, p.197-202, 2017. [Article link]

​

19. Membrane-mediated action of the endocannabinoid anandamide on membrane proteins: implications for understanding the receptor-independent mechanism. Medeiros D., Silva-Gonçalves L.C., da Silva A.M., Dos Santos Cabrera M.P., Arcisio-Miranda M. Scientific Reports., v. 7, p. 41362, 2017. [Article link]

​

18. Luminescent Ru(II) Phenanthroline complexes as a probe for real-time imaging of Aβ self-aggregation and therapeutic applications in Alzheimer's Disease. Silva D.E., Cali M.P., Pazin W.M., Carlos-Lima E., Salles Trevisan M.T., Venâncio T., Arcisio-Miranda M., Ito A.S., Carlos R.M. Journal of Medicinal Chemistry, v. 59, p. 9215-9227, 2016. [Article link]

​

17. Whole genome and exome sequencing realignment supports the assignment of KCNJ12, KCNJ17, and KCNJ18 paralogous genes in thyrotoxic periodic paralysis locus: functional characterization of two polymorphic Kir2.6 isoforms. Paninka R.M., Mazzotti D.R., Kizys M.M., Vidi A.C., Rodrigues H., Silva S.P., Kunii I.S., Furuzawa G.K., Arcisio-Miranda M., Dias-da-Silva M.R. Molecular Genetics and Gemomics, v. 29, p. 1535-1544, 2016. [Article link]

​

16. Voltage-Gated Proton Channel in Human Glioblastoma Multiforme Cells. Ribeiro-Silva L., Queiroz F.O., da Silva A.M., Hirata A.E., Arcisio-Miranda M. ACS Chem Neurosci., v. 7, p. 864-9, 2016. [Article link]

(Featured in "Highlighting Outstanding Work from Authors in Brazil) pdf

​

15. Combining experimental evidence and molecular dynamic simulations to understand the mechanism of action of the antimicrobial octapeptide jelleine-I.  Dos Santos Cabrera M.P., Baldissera G., Silva-Gonçalves L.C., de Souza B.M., Riske K.A., Palma M.S., Ruggiero  J.R., Arcisio-Miranda, M. Biochemistry, v. 53, p. 4857-4868, 2014. [Article link]

​

14. Domain IV voltage-sensor movement is both sufficient and rate limiting for fast inactivation in sodium channel. Capes D.L.*, Goldschen-Ohm M.P.*, Arcisio-Miranda M.*, Bezanilla F., Chanda B. (*co-first authors) The Journal of General Physiology, v. 142, p. 101-112, 2013. [Article link]

​

13. Influence of the bilayer composition on the binding and membrane disrupting effect of Polybia-MP1, an antimicrobial peptide with leukemic T-lymphocyte cell selectivity.  Dos Santos Cabrera M.P.*, Arcisio-Miranda M.*, Gorjão R., Leite N.B., Souza B.M., Curi R., Procopio J., Ruggiero Neto J., Palma, M.S. (*co-corresponding authors) Biochemistry, v. 51, p. 4898-4908, 2012. [Article link]

​

12. Gating transitions in the selectivity filter region of a sodium channel are coupled to the domain IV voltage sensor.  Capes DL, Arcisio-Miranda M, Jarecki BW, French RJ, Chanda, B. Proceedings of the National Academy of Sciences of the United States of America, v. 109, p. 2648-2653, 2012. [Article link]



11. Molecular mechanism of allosteric modification of voltage-dependent sodium channels by local anesthetics.  Arcisio-Miranda M*, Muroi Y*, Choedhury S, Chanda, B. (*co-first authors) The Journal of General Physiology, v. 136, p. 541-554, 2010. [Article link]

​

10. Molecular determinants of coupling between the domain III voltage-sensor and pore of a sodium channel.  Muroi Y*, Arcisio-Miranda M*, Chowdhury S, Chanda, B. (*co-first authors) Nature Structural & Molecular Biology, v. 17, p. 230-237, 2010. [Article link]



9. Comparative effects of DHA and EPA on cell function.  Gorjão R, Azevedo-Martins AK, Rodrigues HG, Abdulkader F, Arcisio-Miranda M, Procopio J, Curi, R. Pharmacology & Therapeutics, v. 122, p. 56-64, 2009. [Article link]



8. Proton flux induced by free fatty acids across phospholipid bilayers: new evidences based on short-circuit measurements in planar lipid membranes.  Arcisio-Miranda M, Abdulkader F, Brunaldi K, Curi R, Procopio, J. Archives of Biochemistry and Biophysics, v. 484, p. 63-69, 2009. [Article link]



7. Interactions of mast cell degranulating peptides with model membranes: a comparative biophysical study.  Dos Santos Cabrera MP, Arcisio-Miranda M, Da Costa LC, Souza BM, Broggio Costa ST, Palma MS, Ruggiero Neto J, Procopio, J. Archives of Biochemistry and Biophysics, v. 486, p. 1-11, 2009. [Article link]



6. Study of the mechanism of action of Anoplin, a helical antimicrobial decapeptide with ion channel-like activity, and the role of the amidated C-terminus. Dos Santos Cabrera MP, Arcisio-Miranda M, Broggio Costa ST, Konno K, Ruggiero JR, Procopio J., Ruggiero Neto, J. Journal of Peptide Science, v. 14, p. 661-669, 2008. [Article link]



5. Effects of the cationic antimicrobial peptide Eumenitin from the venom of solitary wasp Eumenes Rubronotatus in planar lipid bilayers: surface charge and pore formation activity. Arcisio-Miranda M, Dos Santos Cabrera MP, Konno K, Rangel M, Procopio, J. Toxicon, v. 51, p. 736-745, 2008. [Article link]



4. Surface potential determination in planar lipid bilayers: a simplification of the conductance-ratio method. Abdulkader F, Arcisio-Miranda M, Curi R, Procopio J. Journal of Biochemical and Biophysical Methods, v. 70, p. 515-518, 2007. [Article link]



3. Chewing over physiology integration. Abdulkader F, Azevedo-Martins AK, Arcisio-Miranda M, Brunaldi K. Advances in Physiology Education, v. 29, p. 51-53, 2005. [Article link]



2. Fatty acid flip-flop and proton transport determined by short-circuit current in planar bilayers. Brunaldi K, Miranda MA, Abdulkader F, Curi R, Procopio J. Journal of Lipid Research, v. 46, p. 245-251, 2005. [Article link]



1. Effects of palmitic and cholesterol on proton transport across black lipid membranes. Brunaldi K, Miranda MA, Abdulkader F, Curi R, Procopio J. Bioelectrochemistry, v. 65, p. 9-13, 2004. [Article link]