Articaine interaction with phospholipid bilayers

Érica Teixeira Prates; Gustavo Henrique Rodrigues da Silva; Thais F. Souza; Munir S. Skaf; Mónica Pickholz; Eneida de Paula

doi:10.1016/j.molstruc.2020.128854

Articaine interaction with phospholipid bilayers

Érica Teixeira Prates, Gustavo Henrique Rodrigues da Silva, Thais F. Souza, Munir S. Skaf, Mónica Pickholz, Eneida de Paula

Computational and Predictive Biology

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Local anesthetics promote analgesia by interacting with excitable membranes. Articaine (ATC) has a unique composition among local anesthetics as it possesses a thiophene instead of the typical phenyl ring. Aiming to characterize the interaction of neutral articaine (nATC) with phospholipid membranes, we have employed a synergistic approach of experimental and computational techniques. Fluorescence measurements supported nATC partitioning into the membranes, since its intrinsic fluorescence anisotropy increased from 0.03 in water to 0.29 in the presence of egg phosphatidylcholine (EPC) liposomes, and the fluorescence of AHBA, a probe that monitors the water-membrane interface, was quenched by nATC. ¹H NMR experiments revealed changes in the chemical shifts of articaine and EPC hydrogens after partitioning, and shorter T₁ values of nATC hydrogens when inserted into the EPC vesicles. Contacts of nATC and the phospholipid polar head group were inferred from 2D-NOE. Taken together, these results indicate a superficial insertion of the nATC molecules inside EPC bilayers. This conclusion was confirmed by molecular dynamics simulations, which allowed the identification of the key interactions underlying the preferential location of nATC in the bilayer. Contrary to what is often stated (that articaine is a high lipophilic local anesthetic agent) our results place ATC among the hydrophilic ones, such as lidocaine, prilocaine, and mepivacaine, for which the water/membrane interface is the preferred location.

Original language	English
Article number	128854
Journal	Journal of Molecular Structure
Volume	1222
DOIs	https://doi.org/10.1016/j.molstruc.2020.128854
State	Published - Dec 15 2020

Funding

The authors are grateful to Dr. Leonardo F. Fraceto ( São Paulo State University, UNESP /Sorocaba, SP, Brazil) for the collection and treatment of NMR data and Dr. Amando S. Ito (FFCLRP/USP) for providing the AHBA fluorophore. We also thank FAPESP (# 07/02629-2 ; # 14/14457-5 grant; # 17/15174-5 ), CNPq (# 309625/2017-3 ), CONICET (# 0131-2014 ), ANPCyT (# PICT-2014-3653 ) for finantial support and Aventis Pharma for kindly donate articaine. The authors are grateful to Dr. Leonardo F. Fraceto (S?o Paulo State University, UNESP/Sorocaba, SP, Brazil) for the collection and treatment of NMR data and Dr. Amando S. Ito (FFCLRP/USP) for providing the AHBA fluorophore. We also thank FAPESP (#07/02629-2; #14/14457-5 grant; #17/15174-5), CNPq (# 309625/2017-3), CONICET (# 0131-2014), ANPCyT (# PICT-2014-3653) for finantial support and Aventis Pharma for kindly donate articaine.

Keywords

Articaine
Fluorescence
Local anesthetics
Molecular dynamics
NMR

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10.1016/j.molstruc.2020.128854

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title = "Articaine interaction with phospholipid bilayers",

abstract = "Local anesthetics promote analgesia by interacting with excitable membranes. Articaine (ATC) has a unique composition among local anesthetics as it possesses a thiophene instead of the typical phenyl ring. Aiming to characterize the interaction of neutral articaine (nATC) with phospholipid membranes, we have employed a synergistic approach of experimental and computational techniques. Fluorescence measurements supported nATC partitioning into the membranes, since its intrinsic fluorescence anisotropy increased from 0.03 in water to 0.29 in the presence of egg phosphatidylcholine (EPC) liposomes, and the fluorescence of AHBA, a probe that monitors the water-membrane interface, was quenched by nATC. 1H NMR experiments revealed changes in the chemical shifts of articaine and EPC hydrogens after partitioning, and shorter T1 values of nATC hydrogens when inserted into the EPC vesicles. Contacts of nATC and the phospholipid polar head group were inferred from 2D-NOE. Taken together, these results indicate a superficial insertion of the nATC molecules inside EPC bilayers. This conclusion was confirmed by molecular dynamics simulations, which allowed the identification of the key interactions underlying the preferential location of nATC in the bilayer. Contrary to what is often stated (that articaine is a high lipophilic local anesthetic agent) our results place ATC among the hydrophilic ones, such as lidocaine, prilocaine, and mepivacaine, for which the water/membrane interface is the preferred location.",

keywords = "Articaine, Fluorescence, Local anesthetics, Molecular dynamics, NMR",

author = "Prates, \{{\'E}rica Teixeira\} and \{Rodrigues da Silva\}, \{Gustavo Henrique\} and Souza, \{Thais F.\} and Skaf, \{Munir S.\} and M{\'o}nica Pickholz and \{de Paula\}, Eneida",

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doi = "10.1016/j.molstruc.2020.128854",

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T1 - Articaine interaction with phospholipid bilayers

AU - Prates, Érica Teixeira

AU - Rodrigues da Silva, Gustavo Henrique

AU - Souza, Thais F.

AU - Skaf, Munir S.

AU - Pickholz, Mónica

AU - de Paula, Eneida

PY - 2020/12/15

Y1 - 2020/12/15

N2 - Local anesthetics promote analgesia by interacting with excitable membranes. Articaine (ATC) has a unique composition among local anesthetics as it possesses a thiophene instead of the typical phenyl ring. Aiming to characterize the interaction of neutral articaine (nATC) with phospholipid membranes, we have employed a synergistic approach of experimental and computational techniques. Fluorescence measurements supported nATC partitioning into the membranes, since its intrinsic fluorescence anisotropy increased from 0.03 in water to 0.29 in the presence of egg phosphatidylcholine (EPC) liposomes, and the fluorescence of AHBA, a probe that monitors the water-membrane interface, was quenched by nATC. 1H NMR experiments revealed changes in the chemical shifts of articaine and EPC hydrogens after partitioning, and shorter T1 values of nATC hydrogens when inserted into the EPC vesicles. Contacts of nATC and the phospholipid polar head group were inferred from 2D-NOE. Taken together, these results indicate a superficial insertion of the nATC molecules inside EPC bilayers. This conclusion was confirmed by molecular dynamics simulations, which allowed the identification of the key interactions underlying the preferential location of nATC in the bilayer. Contrary to what is often stated (that articaine is a high lipophilic local anesthetic agent) our results place ATC among the hydrophilic ones, such as lidocaine, prilocaine, and mepivacaine, for which the water/membrane interface is the preferred location.

AB - Local anesthetics promote analgesia by interacting with excitable membranes. Articaine (ATC) has a unique composition among local anesthetics as it possesses a thiophene instead of the typical phenyl ring. Aiming to characterize the interaction of neutral articaine (nATC) with phospholipid membranes, we have employed a synergistic approach of experimental and computational techniques. Fluorescence measurements supported nATC partitioning into the membranes, since its intrinsic fluorescence anisotropy increased from 0.03 in water to 0.29 in the presence of egg phosphatidylcholine (EPC) liposomes, and the fluorescence of AHBA, a probe that monitors the water-membrane interface, was quenched by nATC. 1H NMR experiments revealed changes in the chemical shifts of articaine and EPC hydrogens after partitioning, and shorter T1 values of nATC hydrogens when inserted into the EPC vesicles. Contacts of nATC and the phospholipid polar head group were inferred from 2D-NOE. Taken together, these results indicate a superficial insertion of the nATC molecules inside EPC bilayers. This conclusion was confirmed by molecular dynamics simulations, which allowed the identification of the key interactions underlying the preferential location of nATC in the bilayer. Contrary to what is often stated (that articaine is a high lipophilic local anesthetic agent) our results place ATC among the hydrophilic ones, such as lidocaine, prilocaine, and mepivacaine, for which the water/membrane interface is the preferred location.

KW - Articaine

KW - Fluorescence

KW - Local anesthetics

KW - Molecular dynamics

KW - NMR

UR - https://www.scopus.com/pages/publications/85088143346

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DO - 10.1016/j.molstruc.2020.128854

M3 - Article

AN - SCOPUS:85088143346

SN - 0022-2860

VL - 1222

JO - Journal of Molecular Structure

JF - Journal of Molecular Structure

M1 - 128854

ER -

Articaine interaction with phospholipid bilayers

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