Effect of 4-Chlorophenol on the vascular smooth muscle of the abdominal aorta of Wistar rats

Authors

Keywords:

vascular smooth muscle, vascular tone, vasodilation, aorta, contraction, 4-Chlorophenol.

Abstract

Introduction: In Dentistry, p-chlorophenol (4-chlorophenol) is one of the most widely used derivatives of chlorophenols. It is used as an antibacterial agent in root canal disinfection during pulp-radicular treatment. There are few scientific reports on its effects on vascular smooth musculature and the regulation of local blood flow.

Objective: To determine the effect of 4-chlorophenol on vascular smooth muscle of abdominal aorta from Wistar rats.

Material and Methods: A preclinical experimental research was carried out using 30 abdominal aortic rings (upper portion) obtained from adult Wistar rats. The preparations of about 5 mm were placed in an organ bath, recording the tension developed by the vascular smooth muscle after the addition of 4-chlorophenol at different concentrations and during different time intervals.

Results: The results demonstrate that 4-Chlorophenol induced vasorelaxation after the preactivation of the vascular smooth muscle of the abdominal aortic rings, which increased during the entire study time and with increased drug concentration. There were significant differences among average tension values registered at different intervals of time in relation to the initial base tension.

Conclusions: It is concluded that in vitro, p-chlorophenol induced relaxation of abdominal aorta vascular smooth muscle in Wistar rats.

Downloads

Download data is not yet available.

References

1. Igbinosa EO, Olanirán AO. Clorofenoles y otros derivados de riesgo medioambiental. Quimiosfera [Internet]. 2011 [Citado 07/11/2020];83(2011):1297-306. Disponible en: www.sciencedirect.com/science/article/abs/pii/S0045653511004000

2. Carey FA. Clorofenol. En: Encyclopaedia Britannica [Internet]. London: Encyclopaedia Britannica Inc; 2020 [Citado 24/11/2020]. Disponible en: https://www.britannica.com/science/chlorophenol

3. Agencia para Sustancias Tóxicas y el Registro de Enfermedades. Resúmenes de Salud Pública: Clorofenoles (Chlorophenols) [Internet]. Atlanta : Agencia para Sustancias Tóxicas y el Registro de Enfermedades; 2016 [Citado 24/11/2020]. Disponible en: https://www.atsdr.cdc.gov/es/phs/es_phs107.html

4. Drugbank Online. Paraclorofenol [Internet]. Vancouver: Educe Design & Innovation Inc; 2016 [Citado 24/11/2020]. Disponible en: https://go.drugbank.com/drugs/DB13154

5. Central Pollution Control Board. Phenol & phenolic compounds [Internet]. India: Ministry of Environment, Forests & Climate Change; 2016 [Citado 24/11/2020]. Disponible en: www.cpcb.nic.in

6. Kadmi Y, Favier L, Yehya T, Soutrel I, Simion AI, Vial C, et al. Controlling contamination for determination of ultra-trace levels of priority pollutants chlorophenols in environmental water matrices. Arab J Chem [Internet]. 2015 [Citado 24/11/2020];8:[Aprox. 2p.]. Disponible en: https://doi.org/10.1016/j.arabjc.2015.06.005

7. Ge T, Han J, Qi Y, Gu X, Ma L, Zhang C, et al. The toxic effects of chlorophenols and associated mechanisms in fish. Aquat Toxicol [Internet]. 2017 [Citado 24/11/2020];184:78-93. Disponible en: https://doi.org/10.1016/j.aquatox.2017.01.005

8. Anku WW, Mamo MA, Govender PP. Phenolic compounds in water: sources, reactivity, toxicity and treatment methods. En: Soto Hernandez M, Palma Tenango M, García Mateos MR, eds. Phenolic compounds - natural sources. Importance and Applications [Internet]. London: IntechOpen; 2017.p.419-43 [Citado 24/11/2020]. Disponible en: https://doi.org/10.5772/66927

9. Rincón Silva NG, Moreno Piraján JC, Giraldo L. Remoción de fenol, p-nitrofenol y p-clorofenol desde carbones activados químicamente con ácido sulfúrico desde material lignocelulosico de desecho: efecto de la concentración del agente activante. Afinidad [Internet]. 2017 [Citado 24/11/2020];74(578):112-3. Disponible en: https://www.raco.cat/index.php/afinidad/article/view/326513

10. Rodríguez Guerrero ME. Estudio comparativo in vitro del efecto antibacteriano entre tres sustancias utilizadas como medicamento intraconducto contra cepas de Enterococus faecalis [Tesis Especialidad Odontología]. Ecuador: Universidad Nacional de Loja; 2018 [Citado 24/11/2020]. Disponible en: https://dspace.unl.edu.ec/jspui/bitstream/123456789/20688/1/Tesis%20Marlon%20Rodriguez%20Guerrero.pdf

11. Pedraza Maquera KI. Medicación intraconducto frente al Enterococcus faecalis. Revista Odontológica Basadrina [Internet]. 2019 [Citado 24/11/2020]; 3(2):49-55. Disponible en: http://revistas.unjbg.edu.pe/index.php/rob/article/view/893

12. Himadri P, Arpita S, Lopamoodra D, Subrahata H, Subir S. Application of Intracanal Medicaments: A Review. Journal of Dental and Medical Sciences [Internet]. 2019 [Citado 24/11/2020];18(1):14-21. Disponible en: https://iosrjournals.org/iosr-jdms/papers/Vol18-issue1/Version-3/B1801031421.pdf

13. Canalda C. Medicación intraconducto. En: Canalda C, Brau E, eds. Endodoncia. Técnicas clínicas y Bases científicas [Internet]. España: Editorial Masson; 2019.p.184-93 [Citado 24/11/2020]. Disponible en: https://booksmedicos.org/endodoncia-tecnicas-clinicas-y-bases-cientificas/#more-139329

14. Pereira da Silva JD, Ballego G. Pharmacological characterization of the calcium influx pathways involved in nitric oxide production by endothelial cells. Einstein (Sao Paulo) [Internet]. 2019 Jun [Citado 01/04/2021];17(3):[Aprox. 2p.]. Disponible en: http://www.scielo.br/scielo.php?script=sci_arttext&pid=S1679-45082019000300204

15. Padilla Pérez J, Castillo Hernández MC, Padilla Keymole J, Crivelli Puga A, López Canales OA, Zambrano Padilla R. Técnicas de modelado para distinguir la cinética de la contracción de la aorta torácica inducida por fenilefrina en ratas de diferentes edades. Rev Hosp Jua Mex [Internet]. 2018 [Citado 01/04/2021];85(4):208-21. Disponible en: https://www.medigraphic.com/cgibin/new/resumen.cgi?IDARTICULO=84032

16. Aiello EA. Canales de potasio (K+) y Calcio (Ca2+) en el músculo liso vascular. En: Gómez Llambi H, Piskorz D, eds. Hipertensión arterial, epidemiología, fisiología, fisiopatología, diagnóstico y terapéutica [Internet]. Buenos Aires: Inter-Médica; 2016 [Citado 24/11/2020]. Disponible en http://www.saha.org.ar/pdf/libro/Cap.019.pdf

17. Syed AU, Le T, Navedo MF, Nieves Cintrón M. Canales iónicos y su regulación en el músculo liso vascular. En: Kaneez FS, ed. Comprensión básica y clínica de la microcirculación [Internet]. London: IntechOpen; 2019 [Citado 01/04/2021]. Disponible en: https://www.intechopen.com/books/basic-and-clinical-understanding-of-microcirculation/ion-channels-and-their-regulation-in-vascular-smooth-muscle

18. Jensen LJ, Nielsen MS, Salomonsson M, Sorensen ChM. T-type Ca2+ channels and autoregulation of local blood flow. Journal Channels [Internet]. 2017 [Citado 26/11/2020];11(3):183-95. Disponible en: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5463881/

19. Cheng W. Canales TR: desde la distribución hasta el montaje. En: Kaneez FS. Canales de iones en la salud y la enfermedad [Internet]. London: IntechOpen; 2017 [Citado 01/04/2021]. Disponible en: https://www.intechopen.com/books/ion-channels-in-health-and-sickness/trp-ion-channels-from-distribution-to-assembly

20. Feng T, Kalyaanamoorthy S, Bakarat K. Canales de calcio tipo L: estructura y funciones. En: Kaneez FS. Canales de iones en la salud y la enfermedad [Internet].London: IntechOpen; 2017 [Citado 01/04/2021]. Disponible en: https://www.intechopen.com/books/ion-channels-in-health-and-sickness/l-type-calcium-channels-structure-and-functions

21. Amado Piña D. Degradación de contaminantes fenólicos en agua, mediante el acoplamiento de procesos de oxidación avanzada (POA´s) [Tesis Doctorado en Ciencias Ambientales]. México: Universidad Autónoma del Estado México; 2018 [Citado 26/11/2020]. Disponible en: http://ri.uaemex.mx/bitstream/handle/20.500.11799/95074/TESIS_2018_DEYSI_biblioteca.pdf?sequence=1

22. Cantú SM, Lee HJ, Donoso A, Puyó AM, Peredo HA. El ácido araquidónico y sus derivados: generalidades de los prostanoides en relación con procesos inflamatorios. Ciencia e Investigación [Internet]. 2017 [Citado 01/04/2020];67(4):[Aprox. 8 p.]. Disponible en: http://aargentinapciencias.org/wp-content/uploads/2018/01/RevistasCeI/tomo67-4/1-cei67-4-2.pdf

23. Prieto Ocejo D, García Sacristán A. Citocromo P450 y función vascular. En: Monografías: Citocromo P450 [Internet]. España: Real Academia Nacional de Farmacia de España; 2004 [Citado 26/11/2020]. Disponible en: https://pdfs.semanticscholar.org/bf56/f4d7faf29ec0000fcd2b74715340233b9abc.pdf

Downloads

Published

2021-06-07

How to Cite

1.
Rodriguez Reyes O, Noack TK, Patejdl R, García Rodríguez RE, Fajardo Puig ME, Ambruster Sánchez NL. Effect of 4-Chlorophenol on the vascular smooth muscle of the abdominal aorta of Wistar rats. Rev haban cienc méd [Internet]. 2021 Jun. 7 [cited 2025 Jul. 1];20(4):e3901. Available from: https://revhabanera.sld.cu/index.php/rhab/article/view/3901

Issue

Vol. 20 No. 4: July-August 2021 (Issue in Progress)

Section

Biomedical Basic Sciences

License

All the content of this magazine is in Open Access, distributed according to the terms of the Creative Commons Attribution-Noncommercial 4.0 License that allows non-commercial use, distribution and reproduction without restrictions in any medium, provided that the primary source is duly cited.