Cupressus lusitanica

Ethnobotanical Studies

1.

Ecuador

Uses: To control baldness.

DOI:: 10.3390/plants11121590
PubMed:: 35736741

Studies

1.

Changes in Physical and Water Sorption Characteristics of Three Solid Woods after One-Sided Surface Charring.

Tenorio C, Moya R and Tencio L (2024).; ACS Omega.
DOI:: 10.1021/acsomega.4c01110
PubMed:: 38973876

2.

Biodiversity and Structural Analysis of Woody Plant Species of Home Gardens in Basona Worana District, North Shoa Zone of Central Ethiopia.

Woldeyohannes A and Moges A (2024).; Scientifica (Cairo).
DOI:: 10.1155/2024/5563636
PubMed:: 38361969

3.

Chromium Recovery from Chromium-Loaded Cupressus lusitanica Bark in Two-Stage Desorption Processes.

Netzahuatl-Muñoz AR, Aranda-García E and Cristiani-Urbina E (2023).; Plants (Basel).
DOI:: 10.3390/plants12183222
PubMed:: 37765386

4.

GC-MS analysis and the effect of topical application of essential oils of Pinus canariensis C.Sm., Cupressus lusitanica Mill. and Cupressus arizonica Greene aerial parts in Imiquimod-Induced Psoriasis in Mice.

Dermatology

Kamal RM et al (2023).; J Ethnopharmacol.
DOI:: 10.1016/j.jep.2023.116947
PubMed:: 37482262

5.

Assessing heavy metal pollution load index (PLI) in biomonitors and road dust from vehicular emission by magnetic properties modeling.

Salazar-Rojas T et al (2023).; Environ Sci Pollut Res Int.
DOI:: 10.1007/s11356-023-28758-5
PubMed:: 37474860

6.

Plant-air partition coefficients for thirteen urban conifer tree species: Estimating the best gas and particulate matter associated PAH removers.

Giráldez P et al (2022).; Environ Pollut.
DOI:: 10.1016/j.envpol.2022.120409
PubMed:: 36228854

7.

Assessing magnetic properties of biomonitors and road dust as a screening method for air pollution monitoring.

Salazar-Rojas T, Cejudo-Ruiz FR and Calvo-Brenes G (2023).; Chemosphere.
DOI:: 10.1016/j.chemosphere.2022.136795
PubMed:: 36228732

8.

Comparison between machine linear regression (MLR) and support vector machine (SVM) as model generators for heavy metal assessment captured in biomonitors and road dust.

Salazar-Rojas T, Cejudo-Ruiz FR and Calvo-Brenes G (2022).; Environ Pollut.
DOI:: 10.1016/j.envpol.2022.120227
PubMed:: 36152719

9.

Genetic Variation for Economically Important Traits in Cupressus lusitanica in New Zealand.

Ismael A et al (2021).; Front Plant Sci.
DOI:: 10.3389/fpls.2021.651729
PubMed:: 34168664

10.

Activity and Cell-Death Pathway in Leishmania infantum Induced by Sugiol: Vectorization Using Yeast Cell Wall Particles Obtained From Saccharomyces cerevisiae.

Scariot DB et al (2019).; Front Cell Infect Microbiol.
DOI:: 10.3389/fcimb.2019.00208
PubMed:: 31259161

11.

Hydroclimatic variations reveal differences in carbon capture in two sympatric conifers in northern Mexico.

González-Cásares M et al (2019).; PeerJ.
DOI:: 10.7717/peerj.7085
PubMed:: 31218130

12.

Differential metabolism of diastereoisomeric diterpenes by Preussia minima, found as endophytic fungus in Cupressus lusitanica.

Ud Din Z et al (2018).; Bioorg Chem.
DOI:: 10.1016/j.bioorg.2018.04.003
PubMed:: 29702360

13.

Reproductive system, mating behavior and basic ecology of an extremely rare tropical snail: Drymaeus tripictus (Stylommatophora: Bulimulidae).

Barrientos Z et al (2016).; Rev Biol Trop.
PubMed:: 28862402

14.

Biosynthesis and mass spectral fragmentation pathways of (13)C and (15)N labeled cytochalasin D produced by Xylaria arbuscula.

Amaral LS et al (2017).; J Mass Spectrom.
DOI:: 10.1002/jms.3922
PubMed:: 28220590

15.

Airborne Monoterpenes Emitted from a Cupressus lusitanica Cell Culture Induce a Signaling Cascade that Produces β-Thujaplicin.

Fujita K et al (2016).; J Chem Ecol.
PubMed:: 27596215

16.

A novel synthetic pathway for tropolone ring formation via the olefin monoterpene intermediate terpinolene in cultured Cupressus lusitanica cells.

Fujita K et al (2014).; J Plant Physiol.
DOI:: 10.1016/j.jplph.2013.12.016
PubMed:: 24709152

17.

The chemical composition and antimicrobial activity of the leaf oil of Cupressus lusitanica from Monteverde, Costa Rica.

Antimicrobial

Hassanzadeh SL et al (2010).; Pharmacognosy Res.
DOI:: 10.4103/0974-8490.60585
PubMed:: 21808533

18.

Signal transduction and metabolic flux of beta-thujaplicin and monoterpene biosynthesis in elicited Cupressus lusitanica cell cultures.

Zhao J et al (2006).; Metab Eng.
PubMed:: 16242983

19.

Feedback regulation of beta-thujaplicin production and formation of its methyl ether in a suspension culture of Cupressus lusitanica.

Yamada J, Fujita K and Sakai K (2002).; Phytochemistry.
PubMed:: 12052509

20.

Cupressus lusitanica (Cupressaceae) leaf extract induces apoptosis in cancer cells.

Cancer

Lopéz L et al (2002).; J Ethnopharmacol.
PubMed:: 12007700

21.

Production of beta-thujaplicin in Cupressus lusitanica suspension cultures fed with organic acids and monoterpenes.

Zhao J, Fujita K and Sakai K (2001).; Biosci Biotechnol Biochem.
PubMed:: 11440113

22.

Lignans from Cupressus lusitanica (Cupressaceae).

Cowan S et al (2001).; Biochem Syst Ecol.
PubMed:: 11068128