Next Article in Journal
Synthesis and Characterization of Chemically and Green-Synthesized Silver Oxide Particles for Evaluation of Antiviral and Anticancer Activity
Next Article in Special Issue
Antihyperglycemic and Hypolipidemic Activities of Flavonoids Isolated from Smilax Dominguensis Mediated by Peroxisome Proliferator-Activated Receptors
Previous Article in Journal
Application of 99mTc-Labeled WL12 Peptides as a Tumor PD-L1-Targeted SPECT Imaging Agent: Kit Formulation, Preclinical Evaluation, and Study on the Influence of Coligands
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Pharmaceuticals
Volume 17
Issue 7
10.3390/ph17070907
pharmaceuticals-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Medicinal Orchids of Mexico: A Review

by
Luis J. Castillo-Pérez
1,2,
Amauri Ponce-Hernández
3,
Angel Josabad Alonso-Castro
4,*,
Rodolfo Solano
5,
Javier Fortanelli-Martínez
6,
Luicita Lagunez-Rivera
5 and
Candy Carranza-Álvarez
2,*
1
Programa Multidisciplinario de Posgrado en Ciencias Ambientales, Universidad Autónoma de San Luis Potosí, San Luis Potosí 78290, Mexico
2
Facultad de Estudios Profesionales Zona Huasteca, Universidad Autónoma de San Luis Potosí, Ciudad Valles 79060, Mexico
3
Facultad de Ciencias Químicas, Universidad Autónoma de San Luis Potosí, San Luis Potosí 78290, Mexico
4
Departamento de Farmacia, División de Ciencias Naturales y Exactas, Universidad de Guanajuato, Guanajuato 36050, Mexico
5
Laboratorio de Extracción y Análisis de Productos Naturales Vegetales, Centro Interdisciplinario de Investigación para el Desarrollo Integral Regional, Unidad Oaxaca, Instituto Politécnico Nacional, Santa Cruz Xoxocotlán 71230, Mexico
6
Instituto de Investigación de Zonas Desérticas, Universidad Autónoma de San Luis Potosí, San Luis Potosí 78290, Mexico
*
Authors to whom correspondence should be addressed.
Pharmaceuticals 2024, 17(7), 907; https://doi.org/10.3390/ph17070907
Submission received: 4 June 2024 / Revised: 1 July 2024 / Accepted: 3 July 2024 / Published: 8 July 2024
(This article belongs to the Special Issue The 20th Anniversary of Pharmaceuticals—Ethnopharmacology in Latin America)
Browse Figures
Versions Notes

Abstract

:
Some species of the Orchidaceae family are used in Mexican traditional medicine. However, there are no current and critical compilations of the medicinal uses and pharmacological effects of the members of the Orchidaceae family. This review provides a current, critical, and comprehensive analysis of the traditional medicinal uses, pharmacological reports, and active compounds isolated from Mexican orchids. A total of 62 Mexican orchids with medicinal potential have been recorded, of which 14 have scientific evidence. The remaining 48 plant species have ethnomedicinal information but have not been validated with scientific studies. These orchids are distributed in 14 states of the Mexican Republic, mainly in the southern region of Mexico. The most common pharmacological activities reported are anti-inflammatory, vasorelaxant, antinociceptive, antioxidant, spasmolytic, antihypertensive, and hallucinogenic activities. It is necessary to increase the number of pharmacological, phytochemical, and toxicological studies with medicinal orchids from Mexico because there are scientific studies on only 22.5% of these species. In further studies, it will be possible to evaluate the pharmacological effects of Mexican orchids in clinical trials. In addition, the mechanisms of action by which plant extracts and their active compounds exert medicinal effects remain to be studied. Plant extracts from orchids and their active compounds show promising antinociceptive and spasmolytic effects, respectively.

Graphical Abstract

1. Introduction

Orchids are the most diverse group of flowering plants on the planet. Currently, more than 30,000 species are spread in a wide range of biogeographic regions. The distribution of the Orchidaceae family in the world is considered cosmopolitan because these plants are found in most of the planet’s ecosystems, except for the polar extremes and the most arid deserts [1].
Mexico has more than 1302 orchid species [2], which are most commonly used as ornaments due to the beautiful flowers that develop in different shapes and colors. However, several orchids in the country have apparent medicinal importance, and others, such as Vanilla planifolia, are used in the food industry [3]. Despite the great diversity of orchids that exist in the country, wild populations are decreasing due to anthropogenic activities, and, currently, 191 orchids are protected by the normative annex III of the Mexican normativity NOM-059-SEMARNAT-2010 [4], which includes the native flora and fauna species at risk.
Some Mexican orchids are used for medicinal purposes; however, few species have scientific research on the validation of their bioactive compounds or their pharmacological activities [3]. The validation of these properties is essential for obtaining drugs that can contribute to the prevention and treatment of several diseases [5]. Therefore, it is crucial to critically analyze the knowledge that is currently available on the ethnopharmacology of Mexican orchids and determine the gaps between traditional knowledge and evidence-based research.
To the best of our knowledge, there is not a current review that has been published on the aspects we discuss in this article about medicinal orchids from Mexico. Therefore, the main objective of this review is to provide updated and complete data on the distribution, ethnomedical uses, and phytochemical and pharmacology activities of the Mexican orchid species with medicinal potential. A bibliographic search was carried out for scientific reports in academic databases to analyze the diversity of medicinal orchids in Mexico. The information search was conducted in English and Spanish (due to the fact that Mexico is a Spanish-speaking country), and it was based on the following groups of keywords: Mexican medicinal orchids, Mexican orchid phytochemistry, and Mexican therapeutic orchids. The bibliographic search was conducted on the most relevant data in “PubMed”, “ScienceDirect”, “Scopus”, “Web of Science”, and “Google Scholar”, and in addition, physical and digital books were consulted. This review does not focus on Vanilla planifolia or its active compounds. Other reviews specifically address this orchid and can be consulted [6,7].

2. Distribution of Medicinal Orchids in Mexico

The distribution of the orchid species in Mexico is uneven. The humid forests in the tropical region of the country harbor the richest diversity of this family, whereas most of the northern part of the country presents environments unsuitable for these species [8]. Due to the marked distribution of the Orchidaceae family in the tropical southern region of Mexico, inhabitants from these states use orchids for medicinal purposes (Figure 1).
Table 1 shows 62 orchid species with medicinal properties used in Mexico. All the orchid names were corroborated and corrected, when necessary, by consulting the Missouri Botanical Garden (https://www.tropicos.org/home) and the International Plant Names Index (https://www.ipni.org) databases. Although all orchids are distributed in Mexico, not all are endemic to Mexico, and their distribution spreads to other countries on the American continent. These orchids have been reported in 14 of the 32 states of the Mexican Republic (Figure 1). Specific distributions for some species have not been reported, only the ethnic groups that use the plant. However, these data are inaccurate since many ethnic groups usually live in two or more states. For instance, Mayans live in several states in southern Mexico. For four orchid species, neither the state nor the ethnic group that uses the plants are registered (Table 1).
Veracruz was the state with the highest number of medicinal orchids (21 species), followed by the states of Chiapas (9 species), Oaxaca (9 species), San Luis Potosí (7 species), and Campeche (6 species) (Figure 1). Most of these territories have ecosystems such as cloud forests or rainforests, which are ideal for the growth and development of orchids [1,8], except for San Luis Potosí state, which has tropical weather and is in the central region of Mexico. This state is also the homeland of indigenous peoples, like the Tenek and Nahuatl, who use traditional medicine. The rest of the states are in the southern region of Mexico, where the tropical region is covered predominantly by jungles and rainforests. The characteristics of this region make it a suitable site for the growth of orchids and their use in ethnomedicine [64].
Chihuahua is the only state in northern Mexico with reports of medicinal orchids documented so far. In this state, two species have been reported, the Tepehuan ethnic group uses a species of the genus Malaxis for gastrointestinal diseases, and the Raramuri ethnic group uses T. brachyphyllum as a hallucinogenic during their religious ceremonies [59,60,61]. Mayans are another ethnic group that uses eight orchid species as medicinal plants, and the Nahuatl ethnic group uses seven orchid species to treat several ailments, especially those related to gastrointestinal diseases (Table 1).
In contrast, the medicinal properties of Trichocentrum luridum have been registered in seven states of the Mexican Republic, indicating that this orchid has a great range of distribution in Mexico (Table 1).
Regarding the diversity of medicinal orchids, 33 genera have been recorded. The genus Prosthechea, with seven species, presents the largest number of medicinal orchids in Mexico (Figure 2; Table 1), followed by the Epidendrum (six species), Bletia (four species), Laelia (four species), and Trichocentrum (three species) genera. Only two species of orchids are used for medicinal purposes in 18.2% of all the genera, whereas one orchid with medicinal purposes is reported in 60.6% of all the genera (Figure 2).

3. History of Ethnomedicinal Uses of Orchids

The wide herbal and cultural diversity in Mexico has resulted in a vast amount of ethnobotanical knowledge. Many indigenous communities living in rural areas of Mexico have preserved medicinal folk recipes, passed down from generation to generation [65]. These recipes have influenced the development of the current methodologies that seek to verify the validity of the therapeutic properties assigned to medicinal plants.
The Mexican population uses medicinal plants for the folk treatment of different diseases [5]. Of the 30,000 species of vascular plants in Mexico, between 3500 and 4000 have medicinal purposes. However, the chemical, pharmacological, and biomedical validation of the bioactive compounds has been carried out only in 5% of these species [66].
Regarding the Orchidaceae family in Mexico, the first reports of the medicinal use of Mexican orchids date back to the 16th century and correspond to the first herbal treaties based on native species of the country. Tlilxochitl (Vanilla planifolia Andrews) was the first native orchid of Mexico, the therapeutic uses of which were documented shortly after the arrival of the Spaniards. The medicinal uses of V. planifolia were reported in the Libellus de medicinalibus indorum herbis, a manuscript written in 1552 by Martin de la Cruz and translated into Latin by Juan Badiano [67], as well as in the “Historia General de las Cosas de la Nueva España” (General History of the Things of New Spain), written between 1540 and 1585 by Friar Bernardino de Sahagún [68]. Another manuscript from the early Mexican colonial period was written by Francisco Hernández between 1571 and 1577, describing and commenting on the medicinal uses of some orchids known to the Aztec people as tzauhtli, which means mucilage, a substance directly obtained from these plant species [10]. Furthermore, at the end of the colonial period, in 1801, Friar Juan Navarro wrote “Natural History or American Garden” [69] and documented the medicinal uses of V. planifolia.
In the second decade of the 19th century, Juan Lexarza described several orchids based on specimens collected in Michoacan. Some species were associated with the author Hernández [70]. In the early 20th century, Manuel Urbina determined the taxonomic names of Hernandez’s orchids, following Lexarza, and, in some cases, updated the names proposed by this author [9]. García-Peña and Peña [14] published the first review about the traditional uses of Mexican orchids, including medicinal species, and resorted to the names previously assigned by Urbina. Subsequent reviews on medicinal orchids [11,12,19,37,71,72,73,74,75], which included Mexican species, were mainly based on the names documented by the authors mentioned above.
Orchids with medicinal uses are more numerous in traditional medicines from China and India, and these countries stand out in the reviews on this subject. However, on the American continent, Mexico boasts the highest number of orchid species used for medicinal purposes, as reported by several authors [12,37,73]. Nevertheless, it is common in these studies for many of the names assigned to medicinal orchids from Mexico to have been based on Urbina [9], García-Peña and Peña [14], and Ospina [71], resulting in incorrect taxonomic identification. However, Hágsater et al. [1] have correctly identified the orchids documented by Hernandez, Lexarza, and Urbina.

4. Traditional Uses of Mexican Orchids

In this study, we found that of the 62 orchids recorded with medicinal uses, 77% are empirically used, but their biological activities have not been evaluated. Nevertheless, 14 species (22.5%) have reports on their pharmacological activities. Multidisciplinary work, including toxicological, pharmacological, and phytochemical investigations, are needed to evaluate the medicinal potential of the remaining 48 orchids without scientific evidence. Some of these orchids are shown in Figure 3. Orchids from the Epidendrum (six species), Prosthechea (six species), Bletia (four species), and Laelia (four species) genera have more orchids with medicinal purposes used in Mexican traditional medicine. Ethnomedicinal and pharmacological studies should be performed with other plant species from these genera.
In Mexican traditional medicine, 18 orchids (28.1%) (Arpophyllum spicatum; Bletia reflexa; B. coccinea; B. campanulata; B. purpurea; Camaridium densum; Epidendrum anisatum; E. cnemidophorum; Isochilus lactibracteus; Isochilus sp.; Laelia autumnalis; Malaxis sp.; Maxillariella tenuifolia; Pleurothallis cardiothallis; P. pastoris, Prosthechea sp. (probably P. concolor); P. vitellina; and Vanilla planifolia) are used to treat diseases related to the digestive system, such as dysentery and diarrhea, which are the main medicinal uses for orchids (Table 1).
The second most frequent use for medicinal orchids is pain and inflammation. Fifteen orchids are used for the folk treatment of pain and inflammatory diseases. These orchids are as follows: Camaridium densum; Laelia anceps; Laelia speciosa; Mormodes maculata var. unicolor; Myrmecophila christinae; Myrmecophila tibicinis; Oestlundia luteorosea; Oncidium sphacelatum; Scaphyglottis fasciculata; Scaphyglottis livida; Sobralia macrantha; Stanhopea oculata; Trichocentrum ascendens; Trichocentrum brachyphyllum; and Vanilla planifolia (Table 1). Gastrointestinal, respiratory, and musculoskeletal-related diseases are common among rural populations in Mexico, and medicinal plants are an alternative where no allopathic medicine is available for the general population [76]. In many rural areas, there is no access to potable water, which increases the possibility of gastrointestinal diseases. Musculoskeletal diseases, including rheumatoid arthritis, are common among the Mexican population. Approximately 1.5% of adults between 35 and 50 years old are diagnosed with rheumatoid arthritis [77].
It has been reported that Catasetum integerrimum, Prosthechea karwinskii, and Prosthechea michuacana have the potential to treat diabetes mellitus (Table 1), a disease that affects millions of Mexicans every year. In 2022, there were more than 14 million people with diabetes in Mexico, of which 4.5 million were not diagnosed [78].
The orchids Dichaea muricata, Ponera striata, Specklinia sp., Trichocentrum brachyphyllum, and Vanilla mexicana have been registered as medicinal, but the data for these species are scarce, with some studies only mentioning their uses and others only mentioning the places where these orchids are found and the ethnic groups that use them (Table 1). This indicates that more ethnobotanical studies carried out with Mexican orchids are needed. Our research group is focusing on providing more detailed information on the medicinal uses of medicinal orchids from Mexico and the methods of preparing and administering them.
Infusion is the most common way to prepare the medicine, and the main method of administration is by the oral route (Table 1). Some species of orchids are mixed with other plant species or some additive ingredients. For example, the leaves of Dichromanthus cinnabarinus, used to treat the common cold, are combined with Monina sp. leaves to form a kind of poultice [18]. The leaves and flowers of Epidendrum radicans are mixed with the leaves of Brugmansia sp. or with Polygonum punctatum to eliminate dandruff, pimples, coughs, and burns [18]. Sobralia macrantha is liquefied with water, lemon, and honey to decrease cough, fever, and inflammation [41,54]. Finally, the orchid Stanhopea hernandezii is mixed with red corn and other herbs to make tortillas, which are consumed to decrease weakness and a condition called “sunburn” [9,10] (Table 1). The pharmacodynamic and toxicological evaluations of these plant–plant combinations are topics for further research. Isobolographic studies might be helpful to evaluate the possible synergistic effects among combinations of medicinal plants.

5. Pharmacological Activity

The pharmacological activities of 14 Mexican orchids have been reported using in vivo and in vitro models, which is equivalent to 22.5% of the 62 species used in Mexican traditional medicine. The most common pharmacological uses for Mexican orchids are anti-inflammatory uses (six species), followed by vasorelaxant (five species), antinociceptive, antioxidant, and spasmolytic uses (three species each) (Figure 4). A few studies have been conducted on animal models using mice or rats. In vitro studies should be corroborated with in vivo studies to validate the pharmacological evaluation. In addition, chronic studies might be considered before planning clinical trials.
The most studied species in terms of its pharmacological properties is Vanilla planifolia. However, most research focuses on the study and effects of vanillin (4-hydroxy-3-methoxybenzaldehyde), a molecule not exclusive to the species V. planifolia but also found in other species of the genus, such as V. tahitensis and V. pompona [79]. This molecule can also be obtained by chemical synthesis. Further pharmacological and chemical studies are necessary with other plant sections of V. planifolia, such as the stem, leaves, roots, or flowers. For the other species of Mexican orchids, the pharmacological research is described and analyzed in detail in the following sections.

5.1. Anti-Inflammatory Activity

Anti-inflammatory activity has been recorded for six species of Mexican orchids. This section discusses recent investigations into the anti-inflammatory activity of Mexican orchids. López-Pérez [38] tested a hydroethanolic extract (1000 μg/paw) of Laelia furfuracea leaves, an endemic orchid from the state of Oaxaca. This extract showed an inhibition of inflammation of 43.36% in a model of subplantar edema induced with carrageenan in Wistar rats. These results situate this orchid as a species that can be used to inhibit inflammatory processes, probably due to the presence of phenolic compounds.
A hydroalcoholic extract of the leaves (300 mg/kg p.o.) of the epiphytic orchid Prosthechea karwinskii showed an improvement in the gastroprotective effects by 70% and in the anti-inflammatory activity in a carrageenan-induced edema paw model with similar activity to that shown by naproxen (30 mg/kg). This extract showed the presence of compounds such as quinic acid, malic acid, neochlorogenic acid, chlorogenic acid, rutin, embeline, pinelic acid, and azelaic acid [45].
The anti-inflammatory activity of different extracts of Prosthechea michuacana, a terrestrial orchid, applied at 20 mg/mL, was determined using the model of 12-O-Tetradecanoylphorbol-13-acetate (TPA)-induced ear edema. The extracts that showed the highest anti-inflammatory activities were chloroform (leaves) (34.88%), hexane (rhizomes) (34.88%), hexane (pseudobulbs) (25.58%), and methanol (pseudobulbs) (16.27%) [46]. Another investigation conducted by Pérez-Gutiérrez and Vargas-Solís [47] found that the hexane extract from the leaves and pseudobulbs (200 mg/kg) of this orchid has significant anti-inflammatory activity before 3 h (74.02%), since it was proven to block the release of prostaglandins and cyclooxygenase in the later phase of the acute inflammatory process. Interestingly, the combined methanol–dichloromethane whole-plant extract of the orchid Scaphyglottis livida (150–600 mg/kg) reduced the inflammatory process induced by carrageenan. These data suggest that this orchid has a significant dose-dependent, anti-inflammatory effect in rats and mice [17].
In this review, we report three investigations that adjudged the anti-inflammatory potential of the vanillin molecule, one of the natural and major components of Vanilla planifolia. Eun-Ju et al. [80] performed vascular permeability tests and observed that the vanillin showed inhibitions of the inflammatory process of 14.2%, 40.6%, and 49.8% at concentrations of 25, 50, and 100 mg/kg, respectively. For their part, Kwon et al. [81] developed a new inflammation-responsive polymeric vanillin antioxidant prodrug called poly vanillin oxalate (PVO), which achieved potent anti-inflammatory activity by reducing the expressions of proinflammatory cytokines in activated macrophages in vitro and in vivo. Finally, Niazi et al. [82] determined that with the administration of doses of 50 and 100 mg/kg of vanillin, a significant decrease in the inflammation observed in the volumes of the mouse paws was achieved, which they related to its antihistamine activity.
The evidence shown in these investigations suggests that the ingredients of these orchids might be used to create a safe drug that increases the anti-inflammatory potential. Chronic studies are necessary to validate the efficacy shown by orchids in acute-term studies. Several models of chronic inflammation, including TPA-induced ear edema, kaolin–carrageenan-induced monoarthritis, Freund’s complete adjuvant (FCA)-induced arthritis, and others, could be used with Mexican orchids. The effect of Mexican orchids on molecular targets of inflammation, such as cyclooxygenase-2 (COX-2), nuclear factor κB (NF-κB), tumor necrosis factor-alpha (TNF-α), and others, could be evaluated.

5.2. Vasorelaxant Activity

The vasorelaxant activity has been assessed in five orchid species, of which three belong to the Laelia genus. Vergara-Galicia et al. [31] made a methanolic extract with Laelia anceps roots, and when administered at 50 µg/mL, a relaxation of 64.37% was presented in the aortic rings with the endothelium. The vasorelaxant effect shown by the extract was not inhibited by the co-administration with 1H-[1,2,4]Oxadiazolo [4,3-a]quinoxalin-1-one (ODQ), 1-alprenolol, glibenclamide, or 2-Aminopurine (2-AP). This effect was associated with the presence of the compound 2,7-dihydroxy-3,4,9-trimethoxyphenanthrene, characterized by a High-Performance Liquid Chromatography (HPLC) analysis. Vergara-Galicia et al. [32] made two extracts with Laelia anceps, one with hexane and another with dichloromethane, and although the pseudobulbs and leaves were used, the root extracts were the most active (effective concentration 50, EC50 = 6.78 µg/mL with the endothelium and EC50 = 6.78 µg/mL without the endothelium).
Aguirre-Crespo et al. [35] prepared a methanolic extract with the aerial parts of Laelia autumnalis and observed the induction of a relaxation process (inhibitory concentration 50, IC50 = 4.37 × 10−8 ± 1.77 × 10−8 M) dependent on the concentration and independent of the endothelia in the aortas of rats. L-NG-Nitro arginine methyl ester (L-NAME) blocked relaxation, indicating that the vasodilatory properties of the extract are mediated by the endothelium due to the release of nitric oxide. Moreover, Vergara-Galicia et al. [36] obtained a methanolic extract using roots, pseudobulbs, leaves, and seedlings generated in vitro. This is one of the few works in which orchid vitroplants were used to investigate the vasorelaxant action. However, the roots (maximum effect, Emax = 64.37 ± 3.43% at 50 µg/mL with endothelium-intact aorta rings) and pseudobulbs (Emax = 83.32 ± 3.55% at 50 µg/mL with endothelium-intact aorta rings) of L. autumnalis were the extracts that produced the best vasorelaxant effects in a concentration-dependent and endothelium-independent manner on contractions induced by norepinephrine (NE) and potassium chloride (KCl) in rat thoracic aorta rings. Leaf and in vitro seedling extracts did not show relevant vasorelaxant activities. Finally, Aguirre-Crespo et al. [35] observed that L. autumnalis induced relaxation (IC50 = 34.61 ± 1.41 µg/mL and Emax = 85.0 ± 4.38% in endothelium-intact aorta rings) and determined that the extract of this orchid caused an inhibition of the sustained contraction of serotonin. The vasorelaxant effect of rat aortic rings is carried out through an endothelium-independent pathway, which implies the blockade of Ca2+ channels and a possible enhanced concentration of cyclic guanosine monophosphate (cGMP).
Laelia speciosa is the third species of the Laelia genus for which the vasorelaxant activity was investigated, specifically with hexane, dichloromethane, and methanol extracts from the roots and pseudobulbs. The results showed that all the extracts tested induced a concentration-dependent relaxation process in the precontracted aortic rings with and without the endothelium. However, the dichloromethane and hexane root extracts were less potent than the positive controls used (carbachol and sodium nitroprusside). A methanol extract of Laelia speciosa roots (EC50 = 2.75 µg/mL in aorta rings with the endothelium) showed the highest vasorelaxant activity. These results suggest that the secondary metabolites responsible for the vasorelaxant activity belong to a group of compounds with medium and low polarities, and that the roots are the main tissues of the plant where the vasorelaxant compounds are stored [32].
In the case of the orchid Scaphyglottis livida, the stilbenoid compounds gigantol (IC50 = 1.68 × 10−6 ± 0.052 M in endothelium-intact aorta rings) and 3,7-dihydroxy-2,4-dimethoxyphenantrene (IC50 = 5.10 × 10−5 ± 0.55 M in endothelium-intact aorta rings) were found to induce a significant concentration-dependent relaxation of norepinephrine-evoked contractions in endothelial-bearing rat aortic rings intact and naked [53].
Through the use of ex vivo assays, these works indicate that orchids have vasorelaxant actions, and that they should continue to be investigated from this perspective because these plant species could be a source of antihypertensive drugs. Chronic-term studies using in vivo models should also be considered to evaluate the antihypertensive actions of Mexican orchids.

5.3. Antinociceptive Activity

Research on antinociceptive activity is important to find biomolecules in plant species that can be used for pain treatment. This biological activity has been verified in Mexican medicinal orchids. Firstly, a combined dichloromethane–methanol extract of Camaridium densum (150–600 mg/kg p.o.), an orchid formerly known as Maxillaria densa, reduced acetic acid-induced abdominal writhing but failed to produce antinociception in the hot-plate test. In addition, the researchers were able to isolate two chemical compounds from this orchid, fimbriol A (Emax = 69% at 25 mg/kg p.o.) and erianthridin (Emax = 65% at 25 mg/kg p.o.), which partially reduced the contortions induced by acetic acid. This study showed that the extract used is relatively non-toxic and should be regarded as safe. Moreover, the doses tested did not provoke any side effects [17].
A second orchid species with antinociceptive potential is Cyrtopodium macrobulbon. Two research teams in Mexico have studied this orchid, specifically the pseudobulbs. Morales-Sánchez et al. [23] analyzed an aqueous extract and an organic extract with contortions induced by the acetic acid methodology and the hot-plate test and observed that only the organic extract of the pseudobulbs showed an improvement in the antinociceptive effect by 30% when administered at doses of 100 mg/kg.
Yáñez-Barrientos et al. [83] analyzed the roots of Laelia anceps and Cyrtopodium macrobulbon. Ethanolic extracts of C. macrobulbon (effective dose 50, ED50 = 17.8 mg/kg) and L. anceps (ED50 = 48.4 mg/kg) showed antinociceptive activity in the acetic acid-induced-writhing test. C. macrobulbon (ED50 =198 mg/kg in phase 1 and ED50 = 29 mg/kg in phase 2) and Laelia anceps (ED50 = 186 mg/kg in phase 1 and ED50 = 97 mg/kg in phase 2) also showed antinociceptive activity in the formalin test. Pre-treatment with L-NAME reverted the antinociceptive effects of the L. anceps extract and C. macrobulbon extract in the acetic acid test.
At this point of the review, it is important to mention that some assessments of the bioactivities of certain Mexican orchids have been conducted using extracts obtained from the roots of Cyrtopodium macrobulbon [83], Laelia anceps [31,32,83], L. autumnalis [36], L. speciosa [32], P. michuacana [46], Stanhopea tigrine [84], and Trichocentrum Brachyphyllum [85]. However, adult orchid plants still maintain associations with fungi, which form their mycorrhizae, with varying degrees of colonization [86]. Since most orchid roots consist of non-living cells and fungi that produce compounds with significant biological activities, it is unclear whether the effects reported by these studies are due to secondary metabolites produced by the orchid or its fungal endophytes. Studies are needed to verify which organism is responsible for the reported activity.
Finally, for the orchid Scaphyglottis livida, Déciga-Campos et al. [17] used the contortion test and analyzed the antinociceptive effects of a methanolic extract and another extract made with dichloromethane using the whole plant. The results showed that doses of 150, 300, and 600 mg/kg of the orchid methanolic extract reduced the number of stretches in the acetic acid-induced contortion test by 40–50%. Subsequently, the antinociceptive effects of four compounds isolated from S. livida were analyzed using the hot-plate test. The compounds 5α-lanosta-24,24-dimethyl-9(11),25-dien-3β-ol, and gigantol significantly increased the hot-plate latency compared to the vehicle-treated mice [17].
The antinociceptive activity of Mexican orchids seems promising, since Cyrtopodium macrobulbom has shown activities similar to those of reference drugs. In addition, the antinociceptive activities of several active compounds from Mexican orchids have been evaluated. The molecular mechanisms, including the inhibition of COX-2 and other molecules involved in the pain pathway, remain to be studied, especially with the active compounds.

5.4. Antioxidant Activity

Three Mexican medicinal orchids have antioxidant activity, two of which belong to the genus Prosthechea. In the case of the orchid P. karwinskii, the antioxidant capacity was determined by the 2 2-diphenyl-1-picrylhydrazyl (DPPH) method, and with these data, the IC50 and the antioxidant activity index (AAI) were generated. The highest antioxidant activity index was found in the leaf extract (AAI = 5.7), followed by the flower extract (AAI = 1.276) and pseudobulb extract (AAI = 0.925) [43].
Pérez-Gutiérrez et al. [50] used P. michuacana pseudobulbs and determined the antioxidant activity through the total content of phenols, the DPPH radical-scavenging effect, and the 2 2′-azino-bis(3-ethylbenzothiazoline-6- sulfonic acid) (ABTS) radical-scavenging test. This study reported the extraction and isolation of six compounds: two triterpenoids (3α-acetoxy, 24-hydroxy-24-methyl-5α-lanosta-9(11),25-diene (1) and 3α-acetoxy, 24- hydroxy -24-methyl-5α-lanosta-9(11)ene (2)); one stilbene (α-α′-dihydro,3′,5′,2-trimethoxy-3-hydroxy-4-acetyl-4′-isopentenylstilbene (3)); one phenanthrene (4,6,7-trihydroxy-2-methoxy-8-(methylbut-2-enyl)phenanthrene-1,1′-4′,6′,7′-trihydroxy-2′-methoxy-8′-(methylbut-2′-enyl) phenanthrene (4)); one diterpene (12-hydroxy-3β,7β,18α-triacetoxy-8,11,13-abietatriene (5)); and gigantol (6). Of these compounds isolated from P. michuacana, 4 (IC50 = 7.5 µg/mL in DPPH assay) and 5 (IC50 = 15.4 µg/mL in DPPH assay) showed the best antioxidant capacities.
The third orchid with studies on its antioxidant properties is Vanilla planifolia. Shyamala et al. [87] used vanilla fruits extracted with 60% aqueous ethyl alcohol (IC50 = 385 mg/L) and identified and purified the compounds vanillic acid, 4-hydroxybenzyl alcohol (IC50 = 220 mg/L), 4-hydroxy-3-methoxybenzyl alcohol (IC50 = 154 mg/L), 4-hydroxybenzaldehyde, and vanillin. Vanillic acid and vanillin did not cause 50% inhibition in the β-carotene linoleate method.
Some compounds (4 and 5) found in the study of Pérez-Gutiérrez et al. [50] showed similar antioxidant effects to those of reference compounds. Further, in vivo studies should be carried out with these compounds. The antioxidant activity of natural products, like these two compounds, can be used in the prevention and development of several chronic diseases. Protocols for the synthetic synthesis of compounds 4 and 5 are highly desirable. In addition, using biotechnological approaches can be useful to produce these two compounds.

5.5. Spasmolytic Activity

Three orchids used to reduce pain caused by contractures, spasms, and injuries have been recorded. Two compounds, derived from phenanthrenes, obtained from a Camaridium densum whole plant extracted with dichloromethane–methanol (IC50 = 0.62 ± 0.13 µg/mL), and their active compounds, 2,5-Dihydroxy-3,4-dimethoxyphenanthrene (IC50 = 0.95 µM), fimbriol-A (IC50 = 0.67 µM), nudol (IC50 = 0.73 µM), gymnopusin (IC50 = 5.8 µM), and erianthridin (IC50 = 7.1 µM), showed smooth-muscle-relaxant properties in the rat ileum. These compounds showed similar or higher potencies to that of papaverine (IC50 = 7.1 µM) [16]. The nitrergic and histaminergic systems, as well as the interference with the calcium influx in the smooth-muscle cells, are the possible mechanisms of these compounds [16].
A dichloromethane–methanol extract with the whole plant of Nidema boothii inhibited (IC50 = 6.26 ± 2.5 µg/mL) guinea-pig ileum contractions. Several compounds, including batatasin III (IC50 = 0.24 ± 0.11 µM), gigantol (IC50 = 0.26 ± 0.10 µM), lusianthridin (IC50 = 0.41 ± 0.03 µM), and 1,5,7-trimethoxyphenanthrene-2,6-diol (IC50 = 0.45 ± 0.03 µM) were isolated from the plant extract through bioassay-guided fractionation, and their spasmolytic activity was recorded [88].
The five aromatic compounds isolated from Scaphyglottis livida, 3,4′-dihydroxy-5,5′-dimethoxybibenzyl (IC50 = 5.8 µM), batatasin III (IC50 = 0.73 µM), coelonin (IC50 = 0.95 µM), 3,7-dihydroxy-2,4-dimethoxyphenanthrene (IC50 = 0.67 µM), and 3,7-dihydroxy-2,4,8-trimethoxyphenanthrene (IC50 = 7.1 µM), inhibited the contraction in the rat ileum, and the nitric oxide/cGMP pathway seems to be involved in the spasmolytic activities of these compounds [15].
The molecular mechanism of the spasmolytic effects exerted by nudol and gymnopusin, isolated from Camaridium densum, gigantol, and batatasin III, obtained from Nidema boothii, and 3,7-dihydroxy-2,4-dimethoxyphenanthrene and coelonin, obtained from Scaphyglottis livida, should be evaluated (Figure 5). As mentioned above, these compounds showed higher activities compared to the reference drugs. More molecular studies, in vivo assays, and toxicological studies are required with these promising compounds with spasmolytic activities.

5.6. Antihypertensive Activity

In Mexico, there are two orchids of the Laelia genus for which effective antihypertensive activity has been proven. A methanolic extract of Laelia autumnalis (100 mg/kg p.o.) decreased the systolic and diastolic blood pressures by 20%, as well as the heart rates, of spontaneously hypertensive rats after 2 h of treatment. Furthermore, the antihypertensive effect shown by the plant extract is caused by the blockade of Ca2+ channels and a possible enhanced concentration of cGMP [35].
A methanolic extract of Laelia anceps roots (100 mg/kg p.o.) decreased the systolic and diastolic blood pressure by 25% in hypertensive rats after 2 h of treatment. The reduction in the transient contraction induced by norepinephrine in a solution free of Ca2+ ions and the inhibition induced by the increase in external calcium suggest that the antihypertensive effect caused by the plant extract is conducted by blocking the channels of Ca2+ [31].
Arterial hypertension has had negative impacts on health in many countries. This condition represents a predisposition for the development of diseases such as metabolic syndrome, diabetes, kidney dysfunction, heart failure, and stroke [89]. Therefore, the development of research for the discovery of drugs that contribute to the treatment of these diseases is urgent. The results that the species of the Laelia genus have provided in terms of the discovery of metabolites with hypertensive activity suggest that this genus of orchids could be an excellent source of these compounds. Interestingly, in Mexico, there are 11 species belonging to this genus, of which, as shown in this research, only 2 have been studied.

5.7. Other Pharmacological Activities

Other pharmacological activities have been conferred on Mexican medicinal orchids. For example, Zenteno et al. [34] reported that, in Laelia autumnalis, the pseudobulbs have hemagglutinating properties four-fold higher in the presence of human A1 erythrocytes. Barragán-Zarate et al. [44] verified the anticoagulant activity of hydroalcoholic extracts of Prosthechea karwinskii pseudobulbs, leaves, and flowers. The three extracts prolonged the activated Partial Thromboplastin Time (aPTT) by approximately 15–20%. A hydroalcoholic extract of Prosthechea karwinskii leaves (100–1000 mg/kg p.o.) showed gastroprotective effects in a model of indomethacin-induced gastric ulcers in rats after 3 h of treatment [45].
After 6 h of treatment, hexane extracts of Prosthechea michuacana bulbs (400 mg/kg p.o.) decreased the levels of blood glucose (47.78%), cholesterol (46.08%), and triglycerides (46.27%) in streptozotocin-induced diabetic rats [52]. This extract (IC50 = 74.6 µg/mL) and the active compounds α-α′-dihydro, 3′,5′,2-trimethoxy-3-hydroxy-4-acetyl-4′-isopentenylstilbene (IC50 = 24.5 µM), 4,6,7-trihydroxy-2-methoxy-8-(methylbut-2-enylphenanthren)-1-1′-4′,6′,7′-trihydroxy-2′-methoxy′-(methylbut-2′-enyl) phenanthrene (IC50 = 71.6 µM), and gigantol (IC50 = 28.7 µM) also decreased the formation of advanced glycation end products (AGEs) using bovine serum albumin glycated in the presence of glucose [52].
The other biological activities that have been verified in the bulbs of this Mexican medicinal orchid are hepatoprotective and nephroprotective activities. These data situate P. michuacana as an important orchid for the manufacture of possible drugs for the treatment of diabetes mellitus, one of the diseases that currently afflicts Mexico and the world the most.
Ethanol extracts of Stanhopea tigrina leaves showed anxiolytic-like activities in the exploratory-cylinder test (ED50 = 49.34 mg/kg p.o.) and the hole-board test (ED50 = 11.52 mg/kg p.o.) without producing hypnotic, sedative, or locomotor impairments. The mechanisms of the anxiolytic-like effects of this plant extract are due to the involvement of the GABAergic, adrenergic, and serotonergic systems. At 50 and 100 mg/kg p.o., this plant extract exerted diuretic effects with the excretion of sodium and, to a lesser extent, potassium. The possible mechanism of the diuretic action of Stanhopea tigrina is through the participation of nitric oxide [56].
For Vanilla planifolia, it is worth discussing the biological activities of this orchid separately because what has been studied is mainly the vanilla molecule and very rarely the extract of some section of the plant. Therefore, we could consider the vanillin molecule as an excellent medicinal phytochemical compound, but not the Vanilla planifolia plant, because, in many cases, the molecule is synthesized in the laboratory and is not extracted naturally.

6. Active Compounds

The bioactive compounds isolated from the Orchidaceae family began to be studied approximately 25 years ago, and despite the great variety of species that this botanical family possesses, there are scarce reports about its phytoconstituents [44].
Analyses on the chemical composition, isolation, and identification of the compounds in the different parts of orchids (roots, leaves, pseudobulbs, stems, and flowers) have been performed by research groups from around the world [90].
This review presents the main compounds (terpenes and phenolic compounds) found in medicinal orchids used in Mexican traditional medicine. In the case of alkaloids, there is a study reporting the presence of alkaloids in Trichocentrum cebolleta, reported to have hallucinogenic activity [60]. In this review, 13 orchid species of the total 62 orchids reported with medicinal use in Mexico have studies on their chemical compositions.

6.1. Terpenes

Terpenes are the largest group of plant secondary metabolites, with more than 55,000 known chemical structures [91]. Terpenes are generally insoluble in water and are formed by the union of five-carbon compounds called an isoprene. Some terpenes produced by orchids and other plants attract insects, promote pollination, and produce toxins and repellents to defend plants from attacks by insects, herbivores, or pathogens, or their synthesis is due to a response to abiotic stress [92]. Some terpenes have shown antibiotic, antifungal, antiviral, and anticancer activities [91,93].
The presence of terpenes with biological importance has been reported for seven species of Mexican orchids. In the aerial parts of Cyrtopodium macrobulbon, three volatile terpenes, namely, 6,10,14-trimethyl-2-pentadecanone, eucalyptol, and isobornyl formate, have been reported. Among these terpenes, only eucalyptol showed antinociceptive activity [23]. Two triterpenes with antiasthma activity (24,24-dimethyl-9,19-cyclolanostane-25-en-3β-ol and 24-methyl-9,19-cyclolanost-25-en-3β-ol) were isolated from Epidendrum rigidum [94].
López-Pérez [38] reported the presence of sesquiterpene lactones, saponins, and cardiotonic glycosides in Laeila furfuracea. Among these molecules, sesquiterpene lactones and saponins have been identified as potent antioxidants, whereas cardiotonic glycosides produce effects on the heart muscle, specifically on Na+/K+ ATPases [95]. Triterpenes were reported in Prosthechea karwinskii and Stanhopea hernandezii. However, these molecules were not characterized. Similarly, the presence of four triterpenes was found in Scaphyglottis livida, and 5α-lanosta-24,24-dimethyl-9(11),25-dien-3β-ol (LDD), 5α-lanosta-24(S)-methyl-9(11),25-dien-3β-ol, 24,24-dimethyl-9,19-cyclolanosta-9(11),25-dien-3-one (cyclobalanone), and 9,19-cyclolanosta-24,24-dimethyl-25-en-3β-yl trans-p-hydroxycinnamate were identified.
Two triterpenes were isolated from the chloroform extract of P. michuacana bulbs, 3α-acetoxy,24-hydroxy-24-methyl-5α-lanosta-9(11),25-diene and 3α-acetoxy,24-hydroxy-24-methyl-5α-lanosta-9(11)ene, and a diterpene was identified as 12-hydroxy-3β,7β,18α-triacetoxy-8,11,13-abietatriene. According to the results obtained in the DPPH radical-scavenging tests, this diterpene showed antioxidant activity [50].
The presence of terpenoids in hexane and methanol/ethanol extracts from Vanilla planifolia leaves and stems has been reported in the literature, but the studies are just qualitative methodologies [96]. It is necessary to start with the characterization of these extracts and to identify the types of terpenes. However, chemical characterizations of some extracts for the identification of the compounds they contain have not been carried out, so this could be an important field of study that will add information on orchid terpenes.

6.2. Phenolic Compounds

Phenolic compounds, mainly of plant origin, are secondary metabolites with an aromatic ring and hydroxyl substituents. Some of these compounds act as a defense against herbivores and pathogens, such as via mechanical support, as pollinator attractors, and through plant allelopathy processes [97]. Stilbenoids and phenanthrenes are phenolic compounds found in the Orchidaceae family [98]. Orchid phenanthrenes have shown pharmacological activities, such as antimicrobial and antiproliferative effects against cancer cells and anti-inflammatory and antioxidant effects. The findings in Mexican medicinal orchids related to phenolic compounds are detailed below.
Phenanthrene derivatives like 9,10-dihydro-2,5-dihydroxy-3,4-dimethoxyphenanthrene, 2,5-dihydroxy-3,4-dimethoxyphenanthrene, nudol, erianthridin, fimbriol-A, and gymnopusin have been isolated and identified in Camaridium densum.
In Cyrtopodium macrobulbon, 10 different phenolic compounds were isolated from an organic extract of the pseudobulbs. Among these phenolic compounds, there are three derivatives of p-coumaric acid (n-hexacosyl-trans-p-coumarate, n-octacosyl-trans-p-coumarate, and n-triacontyl-trans-p-coumarate). Studies have indicated that p-coumaric acid and its derivatives can protect mammalian cells in culture against oxidative stress and genotoxicity [99]. Additionally, p-coumaric acids have shown antioxidant and cytotoxic effects [100]. The rest of the phenolic compounds isolated from C. macrobulbon are the stilbenoids 4-methoxy-benzylalcohol, 4-hydroxybenzaldehyde, 1,5,7-trimethoxy-9,10-dihydrophenanthrene-2,6-diol, confusarin, gigantol, batatasin III, and ephemeranthol B [23]. Of these compounds, gigantol and ephemeratrol B are known to possess antinociceptive, anti-inflammatory, and antioxidant activities.
One flavonol and two phenanthrenes (9,10-dihydro-2,5-dimethoxyphenanthrene-1,7-diol and 2,7-dihydroxy-3,4,9-trimethoxyphenantrene) were reported in the epiphytic orchid Laelia anceps. These phenanthrene-type compounds have an anti-inflammatory effect, whereas 5-hydroxy-3,7,4′-trimethoxyflavonol has antimutagenic, antifungal, antibacterial, and cytotoxic activities [30].
The presence of 13 phenolic compounds was recorded in Laelia furfuracea, used in the prevention of cardiovascular diseases. Syringic acid acetate, one of these compounds detected in the hydroethanolic extract of the leaves, reduced the coagulation times and had antioxidant, anti-inflammatory, and neuro- and hepatoprotective activities [101]. Protocatechuic acid possesses antithrombotic and antiplatelet activities, inhibits the granular secretion of dense granules and α-granules, and attenuates the activation of glycoproteins IIb/IIIa [102]. Rosmarinic acid has antioxidant, platelet inhibition, and anticoagulant activities [103]. Luteolin-7,3′-di-O-glucoside has antiplatelet and vasorelaxant activities, and kaempferol-3-O-rutinoside and kaempferol-7-O-glucoside have anticoagulant activity. The stilbenoid 4-hydroxybenzyl alcohol (HBA) has shown antiangiogenic, anti-inflammatory, and antinociceptive activities. Finally, malic acid and caffeic acid have antioxidant, anti-inflammatory, and cytotoxic effects [38].
The orchid Nidema boothii is not commonly used in traditional medicine. However, scientific evidence has shown that this orchid has a variety of phenolic compounds, including stilbenoids and phenanthrene derivatives. According to Hernández-Romero et al. [88], nine phenolic compounds have been found in this orchid, and, among them, six are derivatives of phenanthrenes (1,5,7-trimethoxyphenanthrene-2,6-diol; 1,5,7-trimethoxy-9,10-dihydrophenanthrene-2,6-diol; 2,4-dimethoxyphenanthrene-3,7-diol; ephemeranthol B; ephemeranthoquinone; and lusianthridin) and three are stilbenoids (aloifol II, batatasin III, and gigantol). The compounds aloifol II, 1,5,7-trimethoxy-9,10-dihydrophenanthrene2,6-diol, 1,5,7-trimethoxyphenanthrene2,6-diol, ephemeranthoquinone, gigantol, 2,4-dimethoxyphenanthrene-3,7-diol, lusianthridin, and batatasin III have concentration-dependent spasmolytic activity in mouse ilea [15].
Phenolic constituents such as 7-glucoside, caffeic acid, tyrosol, apigenin, vanillin, p-coumaric acid, and ferulic acid were identified in Prosthechea karwinskii. These compounds are known for their cardioprotective activity due to their ability to inhibit cholesterol oxidation [43], and some of these phenols inhibit the growth of adipose tissue due to their antiangiogenic activity [104].
Caffeoyl-quinic acids (chlorogenic acid and neochlorogenic acid) and flavonoid glycosides (rutin and kaempferol-3-O-rutinoside) were isolated from Prosthechea karwinskii [45]. These flavonoid glycosides showed anti-inflammatory and antidiabetic activities due to the inhibition of the mitogen-activated protein kinase (MAP kinases) and the kappa-light chain of the NF-κβ signaling pathways [105,106]). Rutin, kaempferol-3-O-rutinoside, and chlorogenic acid decreased the expression of COX-2. Also, chlorogenic acid and embelin decreased the levels of the proinflammatory cytokines interleukin 1 beta (IL-1β), TNF-α, and interleukin 6 (IL-6), whereas pinellic acid inhibited the production of prostaglandins, leukotrienes, and nitric oxide (NO) in cell cultures [45].
Ten phenolic compounds in Prosthechea michuacana have been recorded. Pérez-Gutiérrez et al. [49] isolated a phenanthrene from the chloroform extract (4,6,7-trihydroxy-2-methoxy-8-(methylbut-2-enyl) phenanthrene-1,1′-4′,6′,7′-trihydroxy-2′-methoxy-8′-(methylbut-2′-enyl) phenanthrene) and two stilbenzenes (α-α’-dihydro,3′,5′,2-trimethoxy-3-hydroxy-4-acetyl-4′-isopentenylstilbene and gigantol). These compounds exerted antioxidant and lipid antiperoxidation activities, which are important for the treatment of oxidative tissue damage caused by the generation of reactive oxygen species. An additional study by Pérez-Gutiérrez et al. [51] isolated four flavones (scutellarein 6-methyl ether; dihydroquercetin; apigenin-7-O-glucoside; and apigenin-7-neohesperidoside) and one flavonoid (apigenin-6-O-β-d-glucopyranosyl-3-O-α-l-rhamnopyranoside). Of these, the compounds scutellarein 6-methyl ether, apigenin-7-neohesperidoside, and apigenin-6-O-β-d-glucopyranosyl-3-O-α-l-rhamnopyranoside exerted moderate hepatoprotective activity in the model of carbon tetrachloride (CCl4). Dihydroquercetin has shown antioxidant and hepatoprotective activities and the inhibition of lipid peroxidation [51].
In Scaphyglottis livida, seven phenolic compounds have been identified, including four stilbenes (gigantol; 3,4′-dihydroxy-3′,4,5-trimethoxybibenzyl (DTB); Batatasin III; and 3,4-dihydroxy-5,5-dimethoxybibenzyl) and three phenanthrene derivatives (coelonin, 3,7-dihydroxy-2,4,8-trimethoxyphenanthrene, and 3,7-dihydroxy-2,4-dimethoxyphenanthrene) [17]. Coelonin showed anti-inflammatory activity by inhibiting the expressions of IL-1β, IL-6, and TNF-α [107]. Many phenolic compounds have been isolated and identified from the epiphytic orchid Vanilla planifolia. However, the pharmacological activities of many of these compounds remain to be determined. The pharmacological effects of some phenolic compounds are listed below. Shyamala et al. [87] reported that the compounds 4-hydroxy-3-methoxybenzyl alcohol and 4-hydroxybenzyl alcohol exhibited antioxidant activities of 65% and 45%, respectively, using the beta carotene–linoleate method, and 90% and 50%, respectively, using the DPPH method. In contrast, 4-hydroxy-3-methoxybenzaldehyde (vanillin) showed lower antioxidant activity compared to the compounds previously mentioned [87]. Vanillin showed antitumor and antimicrobial properties, including the inhibition of bacterial biofilms. Vanillin at 500 µg·mL−1 reduced the development of biofilms induced by Candida albicans [108]. Finally, Kim et al. [109] reported that 4-hydroxy-3-methoxybenzyl alcohol (vanillyl alcohol) showed neuroprotective, antioxidant, and antiapoptotic effects in a study of 1-methyl-4-phenylpyridinium neurotoxin-induced cytotoxicity in MN9D dopaminergic cells.

6.3. Other Compounds

The glycoprotein N-acetyl-D-galactosamine was isolated from the epiphytic orchid Laelia autumnalis. This lectin possesses the biological activity of agglutinating desalted human erythrocytes of the human blood groups A, O, and B [34]. There are no reports about the presence of alkaloids identified in the analyzed orchids.

7. Validation of the Scientific Names of Medicinal Orchids

In the interest of systematics, it is necessary to correct the assignment of improperly applied species names in the scientific literature, as imprecise naming could lead to the pharmacological application of a natural product based on the mistaken identification of a plant. The literature consulted for this review reports several names that are no longer current because these names turned out to be synonyms of other plant names. In some cases, these names were applied to other species not distributed in Mexico or corresponded to similar species.
Coatzontecoxochitl was identified as Stanhopea tigrina Bateman, but Kunth recognized that Hernandez’s drawing corresponds to a non-described species and named this plant species Anguloa hernandezii, later changed to Stanhopea hernandezii Schltr. Tzauhtli was identified as Bletia campanulata Lex, but Hernández’s illustration corresponds to Bletia jucunda Linden & Rchb.f. Chichiltictepetzacuxochitl was named Laelia autumnalis (Lex.) Lindl., but Hernández’s illustration shows the characteristic inflorescence and flower of Laelia speciosa. Cozticcoatzontecoxochitl was identified as Cattleya citrina Mart. (=Prosthechea citrina (Lex.) W.E.Higgins). Francisco Hernández did not illustrate this plant, but its description, etymology (yellow flower with snake-head shape), and use (“flowers usually adorn crowns, garlands, and bouquets whose use is frequent and constant among the Indians”) suggest that it is P. karwinskii, which still has these uses in indigenous communities in Oaxaca [45]. Atzauhtli and acaltzauhtli were determined as Cranichis speciosa Lex. and Cranichis tubularis Lex., respectively [9,70], but these binomials are considered unplaced names and are therefore not accepted (https://powo.science.kew.org, accessed on 2 July 2024).
Hernández-Romero et al. [27] identified the species studied as Epidendrum rigidum, but this name corresponds to a species the presence of which has not been confirmed in Mexico; possibly the orchid evaluated should be referred to as Epidendrum cardiophorum. The correct name for the species evaluated by Estrada et al. [15,53] and Déciga-Campos et al. [17] must be Scaphyglottis fasciculata instead of Scaphyglottis lívida. Oncidium cebolleta (=Trichocentrum cebolleta) was the name assigned to the orchid reported to be a substitute for peyote used by Raramuri in northeastern Mexico [58,59,60,61] and evaluated by Pérez-Barrón et al. [85] in Morelos. However, this name corresponds to a species that, in Mexico, is distributed only in the Yucatan Peninsula, whereas in the states of Chihuahua and Morelos, this orchid is distributed as “rat tail” Trichocentrum brachyphyllum. Specklinia gobryi (Bateman ex Lindl.) F. Barros is a South American orchid, but it was reported by Alayón-Gamboa [20] as medicinal in Campeche, Mexico. Very similar species to this orchid, such as S. marginata Lindl. and Pleurothallis choconiana S. Watson, are distributed in the Yucatan Peninsula (southern Mexico).
Other issues for validating the taxonomic identities of the species detected in this review relate to the origin of the plant material for the evaluations, the reliability of the voucher specimen deposited in an herbarium collection, or the absence of reporting it in the publication. It is required, without exception, that all reports of medicinal orchids include a specimen deposited in an herbarium collection, the label of which contains information about the community where the medicinal use was recorded, the conditions (symptoms) for which the plant is used, and the plant parts employed. Studies on pharmacological evaluation must mandatorily include information about the voucher specimen, which allows for the taxonomic validation of the species used. Additionally, it would be advisable for these studies to include a photograph of the evaluated plant, enabling its identity to be corroborated.

8. Perspectives

As mentioned previously, further ethnobotanical studies are necessary to obtain detailed information on the medicinal uses of Mexican orchids. In many cases, the ethnomedicinal information is not complete or lacks detailed information.
The current national legislation (NOM-059-SEMARNAT-2010) on ecological protection for flora and fauna in Mexico needs to be updated [4]. This list includes eleven plant species cited in this review: Epidendrum cnemidophorum Lindl. (not endemic to Mexico, threatened); Laelia autumnalis (Lex.) Lindl. (endemic, with special protection); Laelia furfuracea Lindl. (endemic, with special protection); Laelia speciosa (Kunth) Schltr. (endemic to Mexico, with special protection); Mormodes maculata var. unicolor (Hook.) L.O.Williams (endemic to Mexico, threatened); Prosthechea citrina (Lex.) Withner (endemic to Mexico, with special protection); Prosthechea karwinskii (Mart.) J.M.H.Shaw, Prosthechea vitellina (Lindl.) W.E.Higgins (not endemic to Mexico, with special protection); Stanhopea oculata (Lodd.) Lindl. (not endemic to Mexico, threatened); Stanhopea tigrina Bateman ex Lindl. (endemic to Mexico, threatened); and Vanilla planifolia Jacks. ex Andrews (not endemic to Mexico, with special protection). However, no recent information is available about the endangered status of Mexican orchids.
The preservation and propagation of Mexican orchids should be encouraged. Our work group has focused on the micropropagation of several orchids with medicinal potential and distribution in Mexico [55,110,111,112]. Biotechnological approaches (plant tissue culture and other techniques) can be a useful strategy for the preservation of these plant species. National legislation should be created to include more sites as protected natural areas to avoid the plunder of orchids [113].
No studies are available on the pharmacological effects of Mexican orchids in clinical trials. Studies on the molecular mechanisms by which orchid extracts and their active compounds exert their pharmacological activities are necessary. In some cases, a possible mechanism of using the inhibitors of signaling pathways has been described. However, it remains to be fully understood how the plant extracts and their active compounds exert their pharmacodynamic actions on their therapeutic targets. In addition, pharmacokinetic and toxicity studies to obtain information before planning clinical trials are needed. These studies can provide information on the safe use of orchids and their active compounds in chronic-term assays.
The isolation and identification of active compounds from Mexican orchids should be encouraged. Phytochemical studies are an opportunity to obtain more secondary metabolites from Mexican orchids. This review indicates that many compounds obtained from orchids show similar or higher activities to those of reference drugs. Therefore, orchids are a source of active compounds with future medicinal potential. Metabolomic studies will be useful to obtain information on how orchids produce their active compounds.

9. Conclusions

Ethnobotanical studies have led to the obtainment of information on the medicinal uses of Mexican orchids. However, less than one-quarter of the medicinal orchids in Mexico have studies on their phytochemistry and pharmacology. Many compounds with pharmacological effects have been identified and isolated from medicinal orchids. Nevertheless, the mechanisms of action remain to be studied. Multidisciplinary work is necessary to obtain information that validates the medicinal uses of these medicinal plants. No clinical trials have been performed with medicinal orchids. The ecological preservation and propagation of these plants should be encouraged among the scientific community. Further work should be carried out with orchids with antinociceptive and spasmolytic activities, which show promising effects.

Author Contributions

L.J.C.-P., A.J.A.-C., R.S. and C.C.-Á., conceptualization, methodology, and data analysis; L.J.C.-P., A.P.-H., R.S. and A.J.A.-C., writing—original draft preparation; A.J.A.-C., J.F.-M., L.L.-R., R.S. and C.C.-Á., writing—review and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This work was partially supported by Consejo Nacional de Humanidades, Ciencia y Tecnología (CONAHCYT, Mexico), grant numbers 269491/2016 (provided to C.C.-Á.) and CBF2023-2024-1888 (provided to A.J.A.-C.).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

No new data were created or analyzed in this study. Data sharing is not applicable to this article.

Acknowledgments

L.J.C.-P. acknowledges the support received from the Sistema Nacional de Posgrados (SNP), which belongs to Consejo Nacional de Humanidades Ciencia y Tecnología (CONAHCYT), for scholarship No. 773045.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Hágsater, E.; Soto-Arenas, M.A.; Salazar-Chávez, G.A.; Jiménez-Machorro, R.; López-Rosas, M.A.; Dressler, R.L. Las Orquídeas de México, 1st ed.; Instituto Chinoín: Mexico City, Mexico, 2005; p. 304. [Google Scholar]
  2. Solano-Gómez, R.; Salazar-Chávez, G.A.; Jiménez-Machorro, R.; Hágsater, E.; Cruz-García, G. Actualización del Catálogo de Autoridades Taxonómicas de Orchidaceae de México; Comisión Nacional para el Conocimiento y Uso de la Biodiversidad. Instituto Politécnico Nacional. Centro Interdisciplinario de Investigación para el Desarrollo Integral Regional Unidad Oaxaca. Base de datos SNIB-CONABIO, Proyecto No. KT005: Mexico City, Mexico, 2020. [Google Scholar]
  3. Castillo-Pérez, L.J.; Martínez-Soto, D.; Maldonado-Miranda, J.J.; Alonso-Castro, A.J.; Carranza-Álvarez, C. The endemic orchids of Mexico: A review. Biologia 2019, 74, 1–13. [Google Scholar] [CrossRef]
  4. SEMARNAT (Secretaría de Medio Ambiente y Recursos Naturales). Modificación del Anexo Normativo III, Lista de Especies en Riesgo de la Norma Oficial Mexicana NOM-059-SEMARNAT-2010, Protección Ambiental-Especies Nativas de México de Flora y Fauna Silvestres-Categorías de Riesgo y Especificaciones Para su Inclusión, Exclusión o Cambio-Lista de Especies en Riesgo. Diario Oficial de la Federación. Available online: https://www.dof.gob.mx/nota_detalle.php?codigo=5578808&fecha=14/11/2019#gsc.tab=0 (accessed on 14 November 2019).
  5. Alonso-Castro, A.J.; Ruiz-Padilla, A.J.; Ramírez-Morales, M.A.; Alcocer-García, S.G.; Ruiz-Noa, Y.; Ibarra-Reynoso, L.D.R.; Solorio-Alvarado, C.R.; Zapata-Morales, J.R.; Mendoza-Macías, C.L.; Deveze-Álvarez, M.A.; et al. Self-treatment with herbal products for weight-loss among overweight and obese subjects from central Mexico. J. Ethnopharmacol. 2019, 234, 21–26. [Google Scholar] [CrossRef] [PubMed]
  6. Ahmad, H.; Khera, R.A.; Hanif, M.A.; Ayub, M.A.; Jilani, M.I. Vanilla. In Medicinal Plants of South Asia: Novel Sources for Drug Discovery, 1st ed.; Hanif, M.A., Nawaz, H., Khan, M.M., Byrne, H.J., Eds.; Elsevier: Amsterdam, The Netherlands, 2020; pp. 657–669. [Google Scholar] [CrossRef]
  7. Sikarwar, P.S.; Vikram, B.; Sengupta, J.D.; Singh, A.; Kumar, N.; Mishra, A.; Dharmendra, K.; Kumar, V. Vanilla: A Review of Powerful Herb with Ayurvedic Medicinal Properties. Int. J. Environ. Clim. 2024, 14, 809–817. [Google Scholar] [CrossRef]
  8. Soto-Arenas, M.A.; Solano-Gómez, R.; Hágsater, E. Risk of extinction and patterns of diversity loss in Mexican orchids. Lankesteriana 2007, 7, 114–121. [Google Scholar] [CrossRef]
  9. Urbina, M. Notas Acerca de los Tzauchtli u Orquídeas Mexicanas, 1st ed.; Anales del Museo Nacional de México: Mexico City, Mexico, 1903; pp. 54–84. [Google Scholar]
  10. Hernández, F. Historia de Plantas de Nueva España; Instituto de Biología, Universidad Nacional Autónoma de México: Mexico City, Mexico, 1942; p. 837. [Google Scholar]
  11. Lawler, L.J. Ethnobotany of the Orchidaceae. In Orchid Biology: Review and Perspectives-3; Arditti, J., Ed.; Cornell University Press: Ithaca, NY, USA, 1984; pp. 27–149. [Google Scholar]
  12. Teoh, E.S. (Ed.) Medicinal Orchids of Central America. In Orchids as Aphrodisiac, Medicine or Food; Springer: Cham, Switzerland, 2019; pp. 139–158. [Google Scholar]
  13. Cox-Tamay, L.D. Orquídeas: Importancia y uso en México. Bioagrociencias 2013, 6, 4–7. [Google Scholar]
  14. García-Peña, M.R.; Peña, M. Uso de las orquídeas en México desde la época prehispánica hasta nuestros días. Orquídea 1981, 8, 59–75. [Google Scholar]
  15. Estrada, S.; Rojas, A.; Mathison, Y.; Israel, A.; Mata, R. Nitric oxide/cGMP mediates the spasmolytic action of 3,4′-dihydroxy-5,5′-dimethoxybibenzyl from Scaphyglottis livida. Planta Med. 1999, 65, 109–114. [Google Scholar] [CrossRef]
  16. Estrada, S.; López-Guerrero, J.J.; Villalobos-Molina, R.; Mata, R. Spasmolytic stilbenoids from Maxillaria densa. Fitoterapia 2004, 75, 690–695. [Google Scholar] [CrossRef] [PubMed]
  17. Déciga-Campos, M.; Palacios-Espinosa, J.F.; Reyes-Ramírez, A.; Mata, R. Antinociceptive and anti-inflammatory effects of compounds isolated from Scaphyglottis livida and Maxillaria densa. J. Ethnopharmacol. 2007, 114, 161–168. [Google Scholar] [CrossRef]
  18. Aguilar, A.; Camacho, J.R.; Chino, S.; Jácquez, P.; López, M.E. Herbario Medicinal del Instituto Mexicano del Seguro Social: Información etnobotánica; Instituto Mexicano del Seguro Social: Mexico City, Mexico, 1994; p. 253. [Google Scholar]
  19. Argueta, A.; Cano, L.M.; Rodarte, M.E. Atlas de las Plantas de la Medicina Tradicional Mexicana, Vols. I–III; Instituto Nacional Indigenista: Mexico City, Mexico, 1994. [Google Scholar]
  20. Alayón-Gamboa, J. Orquídeas en Huertos Familiares de Calakmul, Campeche, México; Comisión Nacional de Áreas Naturales Protegidas: Mexico City, Mexico, 2011; p. 135. [Google Scholar]
  21. Alonso-Castro, A.J.; Villarreal, M.L.; Salazar-Olivo, L.A.; Gómez-Sánchez, M.; Domínguez, F.; García-Carranca, A. Mexican medicinal plants used for cancer treatment: Pharmacological, phytochemical and ethnobotanical studies. J. Ethnopharmacol. 2011, 133, 945–972. [Google Scholar] [CrossRef]
  22. Cruz-García, G.; Solano-Gómez, R.; Lagunez-Rivera, L. Documentation of the medicinal knowledge of Prosthechea karwinskii in a Mixtec community in Mexico. Rev. Bras. Farmacogn. 2014, 24, 153–158. [Google Scholar] [CrossRef]
  23. Morales-Sánchez, V.; Rivero-Cruz, I.; Laguna-Hernández, G.; Salazar-Chávez, G.; Mata, R. Chemical composition, potential toxicity, and quality control procedures of the crude drug of Cyrtopodium macrobulbon. J. Ethnopharmacol. 2014, 154, 790–797. [Google Scholar] [CrossRef] [PubMed]
  24. Sánchez, R.P.; Camila, S.C.; Agustina, D.O.; Erick, C.P. Medicinal Plants Catalogue of Tlaquilpa and Astacinga, Veracruz (Internal Report); Universidad Autónoma de Chapingo: Mexico City, Mexico, 2003. [Google Scholar]
  25. Kong, J.M.; Goh, N.K.; Chia, L.S.; Chia, T.F. Recent advances in traditional plant drugs and orchids. Acta Pharmacol. Sin. 2003, 24, 7–21. [Google Scholar] [PubMed]
  26. Pérez-Nicolás, M.; Vibrans, H.; Romero-Manzanares, A.; Saynes-Vásquez, A.; Luna-Cavazos, M.; Flores-Cruz, M.; Lira-Saade, R. Patterns of knowledge and use of medicinal plants in Santiago Camotlán, Oaxaca, Mexico. Econ. Bot. 2017, 71, 209–223. [Google Scholar] [CrossRef]
  27. Hernández-Romero, Y.; Acevedo, L.; Sánchez, M.d.L.Á.; Shier, W.T.; Abbas, H.K.; Mata, R. Phytotoxic activity of bibenzyl derivatives from the orchid Epidendrum rigidum. J. Agric. Food Chem. 2005, 53, 6276–6280. [Google Scholar] [CrossRef]
  28. Cabrera, T. Ficha técnica de Epidendrum cnemidophorum. In Cuarenta y Ocho Especies de la Flora de Chiapas Incluidas en el PROY-NOM-059-ECOL-2000; Palacios, E., Ed.; Instituto de Historia Natural y Ecología: Mexico City, Mexico, 2006. [Google Scholar]
  29. Cano-Asseleih, L.M.; Menchaca-García, R.A.; Ruiz-Cruz, J.Y.S. Ethnobotany, pharmacology and chemistry of medicinal orchids from Veracruz. J. Agric. Sci. Technol. 2015, 5, 745–754. [Google Scholar] [CrossRef]
  30. Jimarez-Montiel, M.J. Fitoquímica y Determinación de la Actividad Antiinflamatoria y Citotóxica de Compuestos y Extractos Orgánicos de las Hojas de Laelia anceps Lindl. (Orchidaceae). Bachelor’s Thesis, Universidad Nacional Autónoma de México, Mexico City, Mexico, 2009. [Google Scholar]
  31. Vergara-Galicia, J.; Ortiz-Andrade, R.; Rivera-Leyva, J.; Castillo-España, P.; Villalobos-Molina, R.; Ibarra-Barajas, M.; Gallardo-Ortiz, I.; Estrada-Soto, S. Vasorelaxant and antihypertensive effects of methanolic extract from roots of Laelia anceps are mediated by calcium-channel antagonism. Fitoterapia 2010, 81, 350–357. [Google Scholar] [CrossRef] [PubMed]
  32. Vergara-Galicia, J.; Castillo-España, P.; Villalobos-Molina, R.; Estrada-Soto, S. Vasorelaxant effect of Laelia speciosa and Laelia anceps: Two orchids as potential sources for the isolation of bioactive molecules. J. Appl. Pharm. Sci. 2013, 3, 34–37. [Google Scholar] [CrossRef]
  33. Martínez, M. The Medicinal Plants of Mexico, 5th ed.; Ediciones Botas: Mexico City, Mexico, 1969; p. 656. [Google Scholar]
  34. Zenteno, R.; Chávez, R.; Portugal, D.; Páez, A.; Lascurain, R.; Zenteno, E. Purification of a N-acetyl-D-galactosamine specific lectin from the orchid Laelia autumnalis. Phytochemistry 1995, 40, 651–655. [Google Scholar] [CrossRef]
  35. Aguirre-Crespo, F.; Castillo-España, P.; Villalobos-Molina, R.; López-Guerrero, J.J.; Estrada-Soto, S. Vasorelaxant effect of Mexican medicinal plants on isolated rat aorta. Pharm. Biol. 2008, 43, 540–546. [Google Scholar] [CrossRef]
  36. Vergara-Galicia, J.; Aguirre-Crespo, F.; Castillo-España, P.; Arroyo-Mora, A.; López-Escamilla, A.L.; Villalobos-Molina, R.; Estrada-Soto, S. Micropropagation and vasorelaxant activity of Laelia autumnalis (Orchidaceae). Nat. Prod. Res. 2010, 24, 106–114. [Google Scholar] [CrossRef]
  37. Pant, B. Medicinal orchids and their uses: Tissue culture a potential alternative for conservation. Afr. J. Plant Sci. 2013, 7, 448–467. [Google Scholar] [CrossRef]
  38. López-Pérez, A. Extracción, Cuantificación y Actividad Antinflamatoria de Compuestos Fenólicos de Laelia furfuracea (Orchidacea). Master’s Thesis, Instituto Politécnico Nacional, Centro Interdisciplinario de Investigación para el Desarrollo Integral Regional, Oaxaca, Mexico, 2016. [Google Scholar]
  39. Leonti, M. Moko/La Rosa Negra, Ethnobotany of the Popoluca Veracruz, México. Doctoral Thesis, Swiss Federal Institute of Technology, Zurich, Switzerland, 2002. [Google Scholar]
  40. Leonti, M.; Fernando, R.R.; Sticher, O.; Heinrich, M. Medicinal flora of the Popoluca, Mexico: A botanical systematical perspective. Econ. Bot. 2003, 57, 218–230. [Google Scholar] [CrossRef]
  41. Hartmann, W. Las orquídeas en la medicina y otros usos prácticos. Orquídea 1972, 2, 70–71. [Google Scholar]
  42. Martínez, V. Usos Tradicionales y Comercialización de Orquídeas en dos Localidades de la Región Mixe, Oaxaca. Bachelor’s Thesis, Instituto Tecnológico del Valle de Oaxaca, Santa Cruz Xoxocotlán, Mexico, 2015. [Google Scholar]
  43. Rojas-Olivos, A.; Solano-Gómez, R.; Alexander-Aguilera, A.; Jiménez-Estrada, M.; Zilli-Hernández, S.; Lagunez-Rivera, L. Effect of Prosthechea karwinskii (Orchidaceae) on obesity and dyslipidemia in Wistar rats. Alex. J. Med. 2017, 53, 311–315. [Google Scholar] [CrossRef]
  44. Barragán-Zarate, G.S.; Lagunez-Rivera, L.; Solano-Gómez, R. Perfil fitoquímico y evaluación de actividad anticoagulante de hojas, flores y pseudobulbos de Prosthechea karwinskii. Rev. Mex. Agroecosistemas 2016, 3, 267–275. [Google Scholar]
  45. Barragán-Zarate, G.S.; Lagunez-Rivera, L.; Solano-Gómez, R.; Pineda-Peña, E.A.; Landa-Juárez, A.Y.; Chávez-Piña, A.E.; Carranza-Álvarez, C.; Hernández-Benavides, D.M. Prosthechea karwinskii, an orchid used as traditional medicine, exerts anti-inflammatory activity and inhibits ROS. J. Ethnopharmacol. 2020, 253, 112632. [Google Scholar] [CrossRef] [PubMed]
  46. Cervantes-Reyes, M.A. Evaluación Farmacológica de Prosthechea michuacana (Orchidaceae), Especie de Potencial Agronómico. Master’s Thesis, Instituto Politécnico Nacional, Oaxaca, Mexico, 2008. [Google Scholar]
  47. Pérez-Gutiérrez, R.M.; Vargas-Solis, R. Relaxant and antispasmodic effects of extracts of the orchid Encyclia michuacana on isolated guinea pig ileum. J. Nat. Med. 2009, 63, 65–68. [Google Scholar] [CrossRef]
  48. Pérez-Gutiérrez, R.M. Orchids: A review of uses in traditional medicine, its phytochemistry and pharmacology. J. Med. Plant Res. 2010, 4, 592–638. [Google Scholar] [CrossRef]
  49. Pérez-Gutiérrez, R.M.; Gómez, Y.G.; Bautista-Ramirez, E. Nephroprotective activity of Prosthechea michuacana against cisplatin-induced acute renal failure in rats. J. Med. Food 2010, 13, 911–916. [Google Scholar] [CrossRef]
  50. Pérez-Gutiérrez, R.M.; Neira-González, A.M.; García-Báez, E.; Lugardo-Diaz, S. Studies on the constituents of bulbs of the orchid Prosthechea michuacana and antioxidant activity. Chem. Nat. Compd. 2010, 46, 554–561. [Google Scholar] [CrossRef]
  51. Pérez-Gutiérrez, R.M.; Anaya-Sosa, I.; Hoyo-Vadillo, C.; Cruz-Victoria, T. Effect of flavonoids from Prosthechea michuacana on carbon tetrachloride induced acute hepatotoxicity in mice. Pharm. Biol. 2011, 49, 1121–1127. [Google Scholar] [CrossRef]
  52. Pérez-Gutiérrez, R.M.; Hoyo-Vadillo, C. Anti-diabetic activity of an hexane extract of Prosthechea michuacana in streptozotocin-induced diabetic rats. Bol. Latinoam. Caribe Plantas Med. Aromat. 2011, 10, 570–580. [Google Scholar]
  53. Estrada-Soto, S.; López-Guerrero, J.J.; Villalobos-Molina, R.; Mata, R. Endothelium-independent relaxation of aorta rings by two stilbenoids from the orchids Scaphyglottis livida. Fitoterapia 2006, 77, 236–239. [Google Scholar] [CrossRef] [PubMed]
  54. Gutiérrez-Báez, C. Plantas útiles de Yecuatla, Veracruz. La Ciencia y el Hombre 1994, 16, 59–75. [Google Scholar]
  55. Castillo-Pérez, L.J.; Martínez-Soto, D.; Fortanelli-Martínez, J.; Carranza-Álvarez, C. Asymbiotic seed germination, in vitro seedling development, and symbiotic acclimatization of the Mexican threatened orchid Stanhopea tigrina. Plant Cell Tissue Organ Cult. 2021, 146, 249–257. [Google Scholar] [CrossRef]
  56. del Carmen Díaz-Torres, R.; Yáñez-Barrientos, E.; Montes-Rocha, J.Á.; Morales-Tirado, D.J.; Alba-Betancourt, C.; Gasca-Martínez, D.; Gonzalez-Rivera, M.L.; del Carmen Juárez-Vázquez, M.; Deveze-Álvarez, M.A.; Isiordia-Espinoza, M.A.; et al. Ethnomedicinal study and pharmacological effects of the orchid Stanhopea tigrina Bateman ex Lindl. (Orchidaceae). Pharmaceuticals 2024, 17, 588. [Google Scholar] [CrossRef]
  57. Rodríguez-Castro, E.C. Las Plantas Medicinales Mayas. Un Estudio de los Factores de Riesgo Ambientales y Sociales en Maxcanú, Yucatán. Master’s Thesis, Centro de Investigación y de Estudios Avanzados Unidad Mérida, Mérida, Mexico, 2009. [Google Scholar]
  58. Willaman, J.J.; Li, H.L. Alkaloid-bearing plants and their contained alkaloids, 1957–1968. Lloydia 1970, 33, 1. [Google Scholar]
  59. Bye, R.A., Jr. Hallucinogenic plants of the Tarahumara. J. Ethnopharmacol. 1979, 1, 23–48. [Google Scholar] [CrossRef]
  60. Stermitz, F.R.; Suess, T.R.; Schauer, C.K.; Anderson, O.P.; Bye, R.A., Jr. New and old phenanthrene derivatives from Oncidium cebolleta, a peyote-replacement plant. J. Nat. Prod. 1983, 46, 417–423. [Google Scholar] [CrossRef]
  61. Schultes, R.E.; Hofmann, A. Plantas de los Dioses; Fondo de Cultura Económica: Mexico City, Mexico, 2000. [Google Scholar]
  62. Alonso-González, M.; Sotolongo-Baró, M.; Miranda-Flores, R.; Curí-Hernández, M.; Pérez-Santoya, E.; Perdomo-Paiba, M.E. Toxicidad en dosis repetidas del Oncidium luridum Lindl. Rev. Cubana Plant Med. 1997, 2, 9–13. [Google Scholar]
  63. Imaña-Encinas, J.; Riesco-Muñoz, G.; Vasconcelos de Oliveira, D. Plantas medicinales del área del Ecomuseo del Cerrado, Brasil. Investig. Agrar. 2023, 25, 108–112. [Google Scholar] [CrossRef]
  64. Fortanelli-Martínez, J.; Salazar, G.A.; Castillo-Lara, P.; García-Pérez, J.; Alfaro-Medina, C.S.; Castillo-Gómez, H.A.; Ramírez-Palomenque, T.L.; Morales-De la Torre, J.I.; De-Nova, J.A. Orchidaceae of San Luis Potosí, Mexico: Richness and distribution. Bot. Sci. 2022, 100, 223–246. [Google Scholar] [CrossRef]
  65. Medellín-Morales, S.G.; Barrientos-Lozano, L.; Mora-Olivo, A.; Almaguer-Sierra, P.; Mora-Ravelo, S.G. Diversidad de conocimiento etnobotánico tradicional en la Reserva de la Biosfera” El Cielo”, Tamaulipas, México. Ecol. Apl. 2017, 16, 49–61. [Google Scholar] [CrossRef]
  66. Juárez-Rosete, C.R.; Aguilar-Castillo, J.A.; Juárez-Rosete, M.E.; Bugarín-Montoya, R.; Juárez-López, P.; Cruz, C.E. Hierbas aromáticas y medicinales en México: Tradición e Innovación. Bio Cienc. 2013, 2, 119–129. [Google Scholar]
  67. De la Cruz, M. Libellus de Medicinalibus Indorum Herbis. Manuscrito Azteca de 1552 Según Traduccion Latina de Juan Badiano; Fondo de Cultura Economica: Mexico City, Mexico, 1991; p. 258. [Google Scholar]
  68. Sahagún, B. Historia General de las Cosas de la Nueva España. Edición de Carlos María Bustamante; Imprenta de Alejandro Valdéz: Mexico City, Mexico, 1829. [Google Scholar]
  69. Navarro, J. Historia Natural o Jardin Americano. Manuscrito de 1801; Universidad Nacional Autonoma de Mexico, Instituto Mexicano del Seguro Social, Instituto de Seguridad y Servicios Sociales de los Trabajadores Mexicanos: Mexico City, Mexico, 1992; p. 314. [Google Scholar]
  70. Lexarza, J.J.M. Orchidianum Opusculum. In Novorum Vegetabilium Descriptiones Fasciculus II; La llave, P., Lexarza, J.J.M., Eds.; Apud Mertinum Riveram: Mexico City, Mexico, 1825. [Google Scholar]
  71. Ospina, M.H. Orchids and the Aztecs. An herbal documented the use of orchids in the Americas. Orchids 1997, 66, 1160–1163. [Google Scholar]
  72. Ossenbach, C. Orchids and orchidology in Central America. 500 years of history. Lankesteriana 2009, 9, 1–268. [Google Scholar] [CrossRef]
  73. Hossain, M.M. Therapeutic orchids: Traditional uses and recent advances—An overview. Fitoterapia 2011, 82, 102–140. [Google Scholar] [CrossRef] [PubMed]
  74. Ghai, D.; Verma, J.; Kaur, A.; Thakur, K.; Pawar, S.V.; Sembi, J.K. Bioprospection of orchids and appraisal of their therapeutic indications. In Bioprospecting of Plant Biodiversity for Industrial Molecules; Upadhyay, S.K., Singh, S.P., Eds.; Wiley: Hoboken, NJ, USA, 2021. [Google Scholar]
  75. Pomini, A.M.; Sahyun, S.A.; Oliveira, S.M.D.; Faria, R.T.D. Bioactive natural products from orchids native to the Americas-A review. Anais da Academia Brasileira de Ciências 2023, 95, e20211488. [Google Scholar] [CrossRef]
  76. Medrano-Guerrero, A.; Carranza, E.; Juárez-Vázquez, M.d.C.; Solano, E.; Ruiz-Padilla, A.J.; Ruiz-Noa, Y.; Deveze-Alvarez, M.A.; Brennan-Bourdon, L.M.; Alonso-Castro, A.J. Medicinal plants used in rural communities from the municipality of Dolores Hidalgo, Guanajuato (Central Mexico). Bol. Latinoam. Caribe Plantas Med. Aromat. 2023, 22, 524–536. [Google Scholar] [CrossRef]
  77. Instituto de Salud para el Bienestar (INSABI). Available online: https://www.gob.mx/insabi/articulos/dia-mundial-de-la-artritis-y-las-enfermedades-reumaticas-12-de-octubre (accessed on 16 May 2024).
  78. Basto-Abreu, A.; López-Olmedo, N.; Rojas-Martínez, R.; Aguilar-Salinas, C.A.; Moreno-Banda, G.L.; Carnalla, M.; Rivera-Dommarco, J.A.; Romero-Martínez, M.; Barquera, S.; Barrientos-Gutiérrez, T. Prevalencia de prediabetes y diabetes en México. Ensanut 2022. Salud Pública de México 2023, 65 (Suppl. S1), S163–S168. [Google Scholar]
  79. Dhanalakshmi, C.; Manivasagam, T.; Nataraj, J.; Justin Thenmozhi, A.; Essa, M.M. Neurosupportive role of vanillin, a natural phenolic compound, on rotenone induced neurotoxicity in SH-SY5Y neuroblastoma cells. Evid.-Based Complement. Altern. Med. 2015, 14, e1700172. [Google Scholar] [CrossRef]
  80. Eun-Ju, L.; Hyun-Jung, K.; Hyun-Joo, J.; Yun-Seon, S.; Chang-Jin, L.; Eun-Hee, P. Anti-angiogenic, anti-inflammatory and anti-nociceptive activities of vanillin in ICR mice. Biomol. Ther. 2008, 16, 132–136. [Google Scholar]
  81. Kwon, J.; Kim, J.; Park, S.; Khang, G.; Kang, P.M.; Lee, D. Inflammation-responsive antioxidant nanoparticles based on a polymeric prodrug of vanillin. Biomacromolecules 2013, 14, 1618–1626. [Google Scholar] [CrossRef]
  82. Niazi, J.; Kaur, N.; Sachdeva, R.K.; Bansal, Y.; Gupta, V. Anti-inflammatory and antinociceptive activity of vanillin. Drug Des. Dev. Ther. 2014, 5, 145. [Google Scholar] [CrossRef]
  83. Yáñez-Barrientos, E.; González-Ibarra, A.A.; Wrobel, K.; Wrobel, K.; Corrales-Escobosa, A.R.; Alonso-Castro, A.J.; Carranza-Álvarez, J.; Ponce-Hernández, A.; Isiordia-Espinoza, M.A.; Ortiz-Andrade, R.; et al. Antinociceptive effects of Laelia anceps Lindl. and Cyrtopodium macrobulbon (Lex.) GA Romero & Carnevali, and comparative evaluation of their metabolomic profiles. J. Ethnopharmacol. 2022, 291, 115172. [Google Scholar] [CrossRef]
  84. Enciso-Díaz, O.J.; Perea, I.; Castillo, P. Evaluación farmacológica preliminar de pseudobulbos y raíces de Stanhopea hernandezii. In Proceedings of the 1st International Tropical Orchids Congress, Xalapa, Veracruz, 6 October 2015. [Google Scholar]
  85. Pérez-Barrón, G.; Estrada-Soto, S.; Arias-Durán, L.; Cruz-Torres, K.C.; Ornelas-Mendoza, K.; Bernal-Fernández, G.; Perea-Arango, I.; Villalobos-Molina, R. Calcium channel blockade mediates the vasorelaxant activity of dichloromethane extract from roots of Oncidium cebolleta on isolated rat aorta. Biointerface Res. Appl. Chem. 2023, 13, 80. [Google Scholar] [CrossRef]
  86. Rasmussen, H.N. Recent developments in the study of orchid mycorrhiza. Plant Soil 2002, 244, 149–163. [Google Scholar] [CrossRef]
  87. Shyamala, B.N.; Naidu, M.M.; Sulochanamma, G.; Srinivas, P. Studies on the antioxidant activities of natural vanilla extract and its constituent compounds through in vitro models. J. Agric. Food Chem. 2007, 55, 7738–7743. [Google Scholar] [CrossRef]
  88. Hernández-Romero, Y.; Rojas, J.I.; Castillo, R.; Rojas, A.; Mata, R. Spasmolytic effects, mode of action, and structure-activity relationships of stilbenoids from Nidema boothii. J. Nat. Prod. 2004, 67, 160–167. [Google Scholar] [CrossRef]
  89. World Health Organization (WHO). Hypertension. Available online: https://www.who.int/news-room/fact-sheets/detail/hypertension (accessed on 12 July 2023).
  90. Sut, S.; Maggi, F.; Dall’Acqua, S. Bioactive secondary metabolites from orchids (Orchidaceae). Chem. Biodivers. 2017, 14, e1700172. [Google Scholar] [CrossRef]
  91. Salha, G.B.; Abderrabba, M.; Labidi, J. A status review of terpenes and their separation methods. Rev. Chem. Eng. 2021, 37, 433–447. [Google Scholar] [CrossRef]
  92. Huang, M.; Abel, C.; Sohrabi, R.; Petri, J.; Haupt, I.; Cosimano, J.; Gershenzon, J.; Tholl, D. Variation of herbivore-induced volatile terpenes among Arabidopsis ecotypes depends on allelic differences and subcellular targeting of two terpene synthases, TPS02 and TPS03. Plant Physiol. 2010, 153, 1293–1310. [Google Scholar] [CrossRef]
  93. Astani, A.; Reichling, J.; Schnitzler, P. Comparative study on the antiviral activity of selected monoterpenes derived from essential oils. Phytother. Res. 2010, 24, 673–679. [Google Scholar] [CrossRef] [PubMed]
  94. Waizel, H.S.; Waizel, B.J. Algunas plantas utilizadas en México para el tratamiento del asma. An. Otorrinolaringol. Mex. 2009, 54, 145–171. [Google Scholar]
  95. Taiz, L.; Zeiger, E. Secondary metabolites and plant defense. In Plant Physiology, 3rd ed.; Taiz, L., Zeiger, E., Eds.; Sinauer Associates: Sunderland, UK, 2002; pp. 283–308. [Google Scholar]
  96. Díaz-Bautista, M.; Francisco-Ambrosio, G.; Espinoza-Pérez, J.; Barrales-Cureño, H.J.; Reyes, C.; Herrera-Cabrera, B.; Soto-Hernandez, M. Morphological and phytochemical data of Vanilla species in Mexico. Data Brief 2018, 20, 1730–1738. [Google Scholar] [CrossRef] [PubMed]
  97. Marchiosi, R.; Dos Santos, W.D.; Constantin, R.P.; Barbosa de Lima, R.; Soares, A.R.; Finger-Teixeira, A.; Rodrigues Mota, T.; Matias de Oliveira, D.; Foletto-Felipe, M.P.; Abrahão, J.; et al. Biosynthesis and metabolic actions of simple phenolic acids in plants. Phytochem. Rev. 2020, 19, 865–906. [Google Scholar] [CrossRef]
  98. Vasas, A. Phenanthrenes from Orchidaceae and their biological activities. In Orchids Phytochemistry, Biology and Horticulture; Reference Series in Phytochemistry; Merillon, J.M., Kodja, H., Eds.; Springer: Berlin/Heidelberg, Germany, 2021; pp. 1–47. [Google Scholar] [CrossRef]
  99. Grajales-Hernández, D.A. Inducción de Lipasas/Feruloil Esterasas de Aspergillus ochraceus con Residuos de la Industria del Maíz para la Síntesis de Ésteres de Valor Biotecnológico. Master’s Thesis, Centro de Investigación y Asistencia en Tecnología y Diseño del Estado de Jalisco, Jalisco, Mexico, 2015. [Google Scholar]
  100. Mura-Mordones, F.; Olea-Azar, C.; Morales-Valenzuela, J. New insights into the antioxidant activity of hydroxycinnamic and hydroxybenzoic systems: Spectroscopic, electrochemistry, and cellular studies. Free Radic. Res. 2014, 48, 1473–1484. [Google Scholar] [CrossRef] [PubMed]
  101. Srinivasulu, C.; Ramgopal, M.; Ramanjaneyulu, G.; Anuradha, C.M.; Suresh Kumar, C. Syringic acid (SA)—A review of its occurrence, biosynthesis, pharmacological and industrial importance. Biomed. Pharmacother. 2018, 108, 547–557. [Google Scholar] [CrossRef]
  102. Kim, D.C.; Ku, S.K.; Bae, J.S. Anticoagulant activities of curcumin and its derivative. BMB Rep. 2012, 45, 221–226. [Google Scholar] [CrossRef]
  103. Shi, Z.H.; Li, N.G.; Tang, Y.P.; Li, W.; Yin, L.; Yang, J.P.; Tang, H.; Duan, J.A. Metabolism-based synthesis, biologic evaluation and SARs analysis of O-methylated analogs of quercetin as thrombin inhibitors. Eur. J. Med. Chem. 2012, 54, 210–222. [Google Scholar] [CrossRef]
  104. González-Castejón, M.; Rodríguez-Casado, A. Dietary phytochemicals and their potential effects on obesity: A review. Pharmacol. Res. 2011, 64, 438–455. [Google Scholar] [CrossRef] [PubMed]
  105. Wang, S.W.; Wang, Y.J.; Su, Y.J.; Zhou, W.W.; Yang, S.G.; Zhang, R.; Zhao, M.; Li, Y.N.; Zhang, Z.P.; Zhan, D.W.; et al. Rutin inhibits β-amyloid aggregation and cytotoxicity, attenuates oxidative stress, and decreases the production of nitric oxide and proinflammatory cytokines. Neurotoxicology 2012, 33, 482–490. [Google Scholar] [CrossRef] [PubMed]
  106. Kim, M.; Choi, S.; Lee, P.; Hur, J. Neochlorogenic acid inhibits lipopolysaccharideinduced activation and pro-inflammatory responses in BV2 microglial cells. Neurochem. Res. 2015, 40, 1792–1798. [Google Scholar] [CrossRef] [PubMed]
  107. Jiang, F.; Li, M.; Wang, H.; Ding, B.; Zhang, C.; Ding, Z.; Yu, X.; Lv, G. Coelonin, an anti-inflammation active component of Bletilla striata and its potential mechanism. Int. J. Mol. Sci. 2019, 20, 4422. [Google Scholar] [CrossRef] [PubMed]
  108. Raut, J.S.; Rajput, S.B.; Shinde, R.B.; Surwase, B.S.; Karuppayil, S.M. Vanillin inhibits growth, morphogenesis and biofilm formation by Candida albicans. J. Biol. Act. Prod. Nat. 2013, 3, 130–138. [Google Scholar] [CrossRef]
  109. Kim, I.S.; Choi, D.K.; Jung, H.J. Neuroprotective effects of vanillyl alcohol in Gastrodia elata Blume through suppression of oxidative stress and anti-apoptotic activity in toxin-induced dopaminergic MN9D cells. Molecules 2011, 16, 5349–5361. [Google Scholar] [CrossRef] [PubMed]
  110. Castillo-Pérez, L.J.; Maldonado-Miranda, J.J.; Alonso-Castro, Á.J.; Carranza-Álvarez, C. Effect of 6-benzylaminopurine and potassium nitrate on the in vitro micropropagation of Laelia anceps subsp. anceps (Orchidaceae). Biotecnia 2019, 22, 32–38. [Google Scholar] [CrossRef]
  111. Carranza-Álvarez, C.; Trinidad-García, K.L.; Reyes-Hernández, H.; Castillo-Pérez, L.J.; Fortanelli-Martínez, J. Efecto de extractos orgánicos naturales sobre la micropropagación in vitro de Vanilla planifolia Jacks. ex Andrews (Orchidaceae). Biotecnia 2021, 23, 5–12. [Google Scholar] [CrossRef]
  112. Castillo-Pérez, L.J.; Alonso-Castro, A.J.; Fortanelli-Martínez, J.; Carranza-Álvarez, C. Micropropagation of Catasetum integerrimum Hook (Orchidaceae) through seed germination and direct shoot regeneration from pseudobulbs and roots. In Vitro Cell. Dev. Biol. Plant 2022, 58, 279–289. [Google Scholar] [CrossRef]
  113. Castillo-Pérez, L.J.; Alonso-Castro, A.J.; Fortanelli-Martínez, J.; Carranza-Álvarez, C. Biotechnological approaches for conservation of medicinal plants. In Phytomedicine; Ahmad-Bhat, R., Rehman-Hakeem, K., Aslam-Dervash, M., Eds.; Academic Press: Cambridge, MA, USA, 2021; pp. 35–58. [Google Scholar] [CrossRef]
Pharmaceuticals 17 00907 g001
Figure 1. Number of orchids with medicinal potential used in every state in Mexico.
Figure 1. Number of orchids with medicinal potential used in every state in Mexico.
Pharmaceuticals 17 00907 g001
Pharmaceuticals 17 00907 g002
Figure 2. Genera of Mexican orchids with medicinal uses.
Figure 2. Genera of Mexican orchids with medicinal uses.
Pharmaceuticals 17 00907 g002
Pharmaceuticals 17 00907 g003aPharmaceuticals 17 00907 g003b
Figure 3. Mexican orchids with medicinal potential: (a) Calanthe calanthoides (A.Rich. & Galeotti) Hamer & Garay; (b) Catasetum integerrimum Hook.; (c) Cyrtopodium macrobulbon (Lex.) G.A.Romero & Carnevali; (d) Dichromanthus cinnabarinus (Lex.) Garay; (e) Epidendrum anisatum Lex.; (f) Laelia anceps Lindl.; (g) Laelia furfuracea Lindl.; (h) Laelia speciosa (Kunth) Schltr.; (i) Nidema boothii (Lindl.) Schltr.; (j) Pleurothallis cardiothallis Rchb.f.; (k) Prosthechea citrina (Lex.) Withner; (l) Prosthechea karwinskii (Mart.) Christenson; (m) Prosthechea michuacana (Lex.) W.E.Higgins; (n) Prosthechea vitellina (Lindl.) W.E.Higgins; (ñ) Trichocentrum ascendens (Lindl.) M.W.Chase & N.H.Williams; (o) Stanhopea tigrina Bateman ex Lindl.; (p) Vanilla planifolia Jacks. ex Andrews. Photographs by Rodolfo Solano, except (b) and (i) by Luis J. Castillo-Pérez, (f) by Candy Carranza-Álvarez, (o) by Javier Fortanelli and (p) by Alejandro Antonio-Calderon.
Figure 3. Mexican orchids with medicinal potential: (a) Calanthe calanthoides (A.Rich. & Galeotti) Hamer & Garay; (b) Catasetum integerrimum Hook.; (c) Cyrtopodium macrobulbon (Lex.) G.A.Romero & Carnevali; (d) Dichromanthus cinnabarinus (Lex.) Garay; (e) Epidendrum anisatum Lex.; (f) Laelia anceps Lindl.; (g) Laelia furfuracea Lindl.; (h) Laelia speciosa (Kunth) Schltr.; (i) Nidema boothii (Lindl.) Schltr.; (j) Pleurothallis cardiothallis Rchb.f.; (k) Prosthechea citrina (Lex.) Withner; (l) Prosthechea karwinskii (Mart.) Christenson; (m) Prosthechea michuacana (Lex.) W.E.Higgins; (n) Prosthechea vitellina (Lindl.) W.E.Higgins; (ñ) Trichocentrum ascendens (Lindl.) M.W.Chase & N.H.Williams; (o) Stanhopea tigrina Bateman ex Lindl.; (p) Vanilla planifolia Jacks. ex Andrews. Photographs by Rodolfo Solano, except (b) and (i) by Luis J. Castillo-Pérez, (f) by Candy Carranza-Álvarez, (o) by Javier Fortanelli and (p) by Alejandro Antonio-Calderon.
Pharmaceuticals 17 00907 g003aPharmaceuticals 17 00907 g003b
Pharmaceuticals 17 00907 g004
Figure 4. Frequency of medicinal orchids with pharmacological activities.
Figure 4. Frequency of medicinal orchids with pharmacological activities.
Pharmaceuticals 17 00907 g004
Pharmaceuticals 17 00907 g005
Figure 5. Chemical structures of compounds with promising spasmolytic activities.
Figure 5. Chemical structures of compounds with promising spasmolytic activities.
Pharmaceuticals 17 00907 g005
Table 1. Medicinal species of the Orchidaceae family in Mexico.
Table 1. Medicinal species of the Orchidaceae family in Mexico.
Species NameCommon NamePlant Part UsedPreparation MethodEthnopharmacological UsesState, Region, or EthnicityReferences
Arpophyllum spicatum Lex.TzauhxilotlPseudobulbs and stemDecoctionGastrointestinal disorders (dysentery)Nahuatl[9,10,11,12]
Bletia campanulata Lex.TzacuxochitlCormsInfusionGastrointestinal disorders (dysentery)Nahuatl[12,13]
Bletia coccinea Lex.TonalxochitlCormsInfusionGastrointestinal disorders (dysentery)Nahuatl[9,10,11]
Bletia purpurea (Lam.) A.DC.NMCormsInfusion; crushedGastrointestinal disorders (dysentery)Nahuatl; Tzetzal (Chiapas)[14]
Bletia reflexa Lindl.TzautliCormsInfusionGastrointestinal disorders (dysentery)Nahuatl[9,10,11]
Calanthe calanthoides (A.Rich. & Galeotti) Hamer & GarayNMCorms and flowersCrushed or powderedTo cicatrize wounds or burnsNM[11,12]
Camaridium densum (Lindl.) M.A.BlancoNMPseudobulbs and leavesInfusionGastrointestinal disorders (dysentery); treatment of painful complaints; relaxant agent.Catemaco, Veracruz[1,15,16,17]
Catasetum integerrimum Hook.Chinela; Cola de pato; Chi’i tku’uk; Trompa de puerco; Xøj cuxp tso’nabie; NabiePseudobulbsCrushed;
infusion		Diabetes; diarrhea; renal disorders; to cicatrize wounds or burns; inflamed blows; to treat “Nacidos” (small inflamed tumor or grain on the skin); viper bite; dermatological problemsZapoteca (Oaxaca); Mayans (Quintana Roo and Tabasco); Nahuatl (San Luis Potosí)[1,11,13,18,19,20,21,22]
Catasetum maculatum KunthCh’it cucFlowersCooked and groundedSores and tumorsMayans (Yucatan)[12]
Chysis laevis Lindl.NMPseudobulbs and rootsCrushed and boiled in alcohol or waterTo decrease feverNMPersonal communication
Cyrtopodium macrobulbon (Lex.) G.A.Romero & CarnevaliCaña or cañaveralPseudobulbsCrushed, roasted, and infusionTo cicatrize wounds or burns; inflamed blows; back affectation; painful urinary ailmentsAcapulco, Guerrero;
Tlaxiaco, Oaxaca; Tamasopo, San Luis Potosí; Chiapas		[14,23]
Deiregyne eriophora (B.L.Rob. & Greenm.) GarayCecetzi;
Margaretilla		NMNMAsthmaTlaquilpa, Veracruz[24]
Dichaea muricata (Sw.) Lindl.NMWhole plantWash preparedConjunctivitisNM[25]
Dichaea neglecta Schltr.Chhitë xkudzu belhë;
espinazo de culebra		BranchesNMScare or bite caused by snake and swing scareSantiago Camotlán and Totontepec Villa de Morelos, Oaxaca[26]
Dichromanthus cinnabarinus (Lex.) GarayCutzis (for all species of Dichromanthus genera)LeavesCrushed and mixed with monnina (Monina sp.) leafColdSan Juan Chamula, Chiapas[18]
Epidendrum anisatum Lex.NMStemsInfusionGastrointestinal disorders (such as dysentery)Purepechan[1]
Epidendrum rigidum Jacq.NMStemsInfusionHydrationQuintana Roo[27]
Epidendrum cnemidophorum Lindl.Ech’wamalLeavesInfusionDigestive disorders that produce flatulenceOxchuc, Chiapas[28]
Epidendrum radicans Pav. ex Lindl.Semperavil ak’; Kilon vet;
Tz’emani’; Krus tz’emani; Muk’tikil		Flowers and leavesMixed with Brugmansia leaves; mixed with Polygonum punctatum;
infusion; crushed		Dandruff and grains; cough; burns; whooping coughSan Juan Chamula, San Andrés Larraínzar and San Pablo Chalchihuitán, Chiapas[18]
Epidendrum chlorocorymbos SchltrSimpre vivaLeavesInfusionCholesterol lowering; ear pain; grains; sleep stimulationAtzalan, Veracruz[29]
Epidendrum verrucosum Sw.Jutz’epNMCrushedTo treat “nacidos”Oxchuc, Chiapas[18]
Habenaria floribunda Lindl.Clavo cochinilloLeavesInfusionVaginal hemorrhageSoteapan, Veracruz[29]
Isochilus latibracteatus A.Rich. & GaleottiArroz largoWhole plantNMAbdominal colic and gastrointestinal disordersSoteapan, Veracruz[12,29]
Isochilus major Cham. & Schltdl.NMLeavesCrushedInflamed blowsIxtaczoquitlan, Veracruz[12,29]
Isochilus sp.NMStemsInfusionGastrointestinal disordersAncient Mexican[1]
Laelia anceps Lindl.Flor de San Miguel; Flor de Todos Santos; Vara de San DiegoPseudobulbsNMTo treat pain and inflammationCoatepec, Veracruz; San Luis Potosí[30,31,32]
Laelia autumnalis (Lex.) Lindl.Camote de San Diego; Flor de las Animas; Flor de Encino; Flor de la Calavera; Flor de Todos Santos; Flor de Catarina; Lirio de San FranciscoPseudobulbs, leaves and flowersInfusion;
crushed and diluted in alcohol		Circulatory disorders; cough; hypertension; respiratory disorders; to heal the waist in postpartum; gastrointestinal disorders (such as dysentery)Zirahuen, Michoacán; Puente de Ixtla, Tepoztlan and Tetela del Volcán, Morelos[1,12,18,33,34,35,36,37]
Laelia furfuracea Lindl.Gihtsl;
Ita ndeka morada; Lirio morado; Lirio de San Francisco; Monja morada		FlowersInfusionCoughSan Pedro y San Pablo Teposcolula, Oaxaca[38]
Laelia speciosa (Kunth) Schltr.Chichiltictepetzacuxochitl (ancient Nahuatl, red and sticky flower of the hill)
Deanta; Flor de Corpus; For de mayo; Itzamahua		Pseudobulbs and flowersInfusionCough and inflamed blowsValle del Mezquital, Hidalgo[18,32]
Malaxis sp.JengibreCormsInfusionGastrointestinal disorders (such as dysentery)Tepehuanes (Chihuahua)[1]
Maxillariella tenuifolia (Lindl.) M.A.Blanco & CarnevaliKowa nokchaRootsCrushedGastrointestinal disorders (such as dysentery)Hueyapan de Ocampo and Soteapan, Veracruz[39,40]
Mormodes maculata var. unicolor (Hook.) L.O.WilliamsFlor de mayoPseudobulbsCrushedInflammation caused by sprain dislocationsZongolica, Veracruz[29]
Myrmecophila christinae Carnevali & Gómez-JuárezFlor de confesionario; cuerno; Homikim; Xonikni; X-yonixinPseudobulbsInfusionPregnancy pain and woundsMayans in Calakmul, Campeche[12,20]
Myrmecophila tibicinis (Bateman ex Lindl.) RolfeHom-ikimPseudobulbsInfusion or juicePregnancy pain to facilitate childbirthMayans (Yucatan)[12,14,18,41]
Nidema boothii (Lindl.) Schltr.NMWhole plantNMNot used as a traditional
or alternative remedy		Catemaco, Veracruz[27]
Oestlundia luteorosea (A.Rich. & Galeotti) W.E.HigginsTopixcamohtliPseudobulbsCrushed in alcoholInflamed blows and headacheZongolica, Veracruz[29]
Oncidium graminifolium (Lindl.) Lindl.Näjx pïj or tsäj pïjPseudobulbsInfusionRenal disordersSanta Maria Tlahuitoltepec, Oaxaca[42]
Oncidium sphacelatum Lindl.Flor de mayo; Chorizo con huevo; Anis nikte’LeavesWarmedPainMisantla, Veracruz[18]
Ornithocephalus inflexus Lindl.Puuts’mukuySapSpreadTo treat insect bitesMayans in Calakmul, Campeche[20]
Pleurothallis cardiothallis Rchb.f.Oo quia’ dsea ñuWhole plantInfusion;
chewed		Gastrointestinal disorders; female sterility; to conceive male childrenZapotec (Oaxaca); Populaca (Veracruz)[1]
Ponera striata Lindl.NMNMNMNMMayans in Calakmul, Campeche[20]
Prosthechea citrina (Lex.) WithnerCozticcoatzontecoxochitlPseudobulbsPseudobulbs cut in half used as poulticeWound healingJesús del Monte and Ichaqueo, Michoacán[12,14,37]
Prosthechea karwinskii (Mart.) ChristensonIta ndeca amarilla; Lirio Amarillo; Monja amarillaPseudobulbs, leaves and flowersInfusion;
poultice		Diabetes; bleeding; to heal wounds or burns; cough; inflamed blows; to prevent risk of abortionTlaxiaco and Villa Sola de Vega, Oaxaca[9,10,22,38,43,44,45]
Prosthechea michuacana (Lex.) W.E.HigginsAguanoso; Camote de agua; Näjx pïj o tsä jpïjPseudobulbsCrushed;
chewed;
infusion		Diabetes; to cicatrize wounds or burns; circulatory disorders; hangover; inflamed blows; renal disordersEjutla de Crespo, Santa Catarina Ixtepeji, Santa Maria Tlahuitoltepec and Tlaxiaco, Oaxaca[46,47,48,49,50,51,52]
Prosthechea panthera (Rchb.f.) W.E.HigginsJazminRootsTwo bundles of roots, boiledScabiesAmatenango del Valle, Chiapas[18]
Prosthechea pastoris (Lex.) Espejo & López-Ferr.TzacutliPseudobulbsInfusionGastrointestinal disorders (such as dysentery)Nahuatl[12,14]
Prosthechea sp.TzauhtliPseudobulbsInfusion;
chewed		Adhesive for poultices for bone fractures; bleeding; gastrointestinal disorders (such as diarrhea and dysentery)Purepechan[9,10]
Prosthechea vitellina (Lindl.) W.E.HigginsTzauxochitlPseudobulbsNMGastrointestinal disorders (such as dysentery)Nahuatl[10]
Rhyncholaelia digbyana (Lindl.) Schltr.Ch’it ku’uk, Piita, Xk’ubeenbaj nunup’leLeavesCrushed and placed in the woundTo cicatrize wounds and burnsMayans in Calakmul, Campeche[12,13,20,41]
Rhynchostele bictoniensis (Bateman) Soto Arenas & SalazarUch’al vo’; Camote de aguaPseudobulbs and rootsSqueezed and mixed with salt:
boiled		Baby cramps and headacheSan Juan Chamula, Chiapas[18]
Scaphyglottis fasciculata Hook.Parasita menudaNMInfusionAnti-inflammatory,
antinociceptive, and
relaxing activities		Catemaco, Veracruz[29]
Scaphyglottis livida (Lindl.) Schltr.ParasitaNMTopicallyTo eliminate parasites, relieve stomachache,
relax muscles; colic treatment; insect repellent; to prevent miscarriage		Los Tuxtlas (Veracruz)[15,17,53]
Sobralia macrantha Lindl.Atempanxochichocane; Cabolín; Lirio de San AntonioLeavesCrushed;
liquated in water with lemon and honey added		Cough; fever; inflamed blowsXocoyolo and Cuetzalan, Puebla; Chiconquiaco, Veracruz[41,54]
Specklinia sp. (Bateman ex Lindl.) F.BarrosNMNMNANMMayans in Calakmul, Campeche[20]
Stanhopea hernandezii (Kunth) Schltr.Coatzontecomaxochitl: Cabeza de víboraFlowersMixed with red corn and other herbs to make tortillasSunstroke and weaknessAncient Mexican[9,10,12,37]
Stanhopea oculata (Lodd.) Lindl.Tehuanxochitl; Flor de la bestiaPseudobulbsCrushed and boiledTo reduce pain of women in labor Zongolica, Veracruz[29]
Stanhopea tigrina Bateman ex Lindl.Cabeza de vibora; ToritosPseudobulbs, leaves, and rootsPowderedTo treat sunstroke, weakness, renal disorders, and mental disorders Huasteca veracruzana (Veracruz); Huasteca Potosina (San Luis Potosí)[12,55,56]
Trichocentrum ascendens (Lindl.) M.W.Chase & N.H.WilliamsCola de rata; cuerno de chivo; puknakché (Maya)Whole plantCrushedInflammation caused by splinter; “Limpia” (a ritual to prevent, diagnose, or cure a disease set); headaches; toothaches; stomachaches; kidney diseasesSoteapan, Veracruz;
Yucatán; Quintana Roo		[19,29,57]
Trichocentrum brachyphyllum (Lindl.) R.JiménezCola de iguana o cola de rata.LeavesDried and chewedTo treat artery hypertension; as a hallucinogen; to treat abdominal colicRaramuri (Chihuahua)[12,58,59,60,61]
Trichocentrum luridum (Lindl.) M.W.Chase & N.H.WilliamsOrejas de burroWhole plantNMTreatment of heart conditions and asthmaCampeche, Chiapas, Oaxaca, San Luís Potosí, Tabasco, Veracruz, Yucatán[12,62]
Vanilla mexicana Mill.Vainilla sin perfumeWhole plantEssential oilVermifugeNM[63]
Vanilla planifolia Jacks. ex AndrewsTlilxochitl; Xanat; VainillaFruits and flowersFlowers squeezed in water;
flowers powered and placed into a Magnolia flower;
flavoring chocolate or drink water;
mixed with mecaxochitl to provoke “regla” (menstruation);
aromatherapy;
infusion;
decoction		Fatigue; gastrointestinal disorders; bleeding, diuretic; to treat nervous problems; to lower fever; to accelerate birth child; to attract dead fetuses; to provoke menstruation; “Mal aire” (a condition caused by the penetration of a harmful mist into the body); to facilitate digestion; skin tumors; dermatological problems; to treat hysteria, impotence, and rheumatism; to increase the energy of muscular systemsMisantla, Veracruz; Huasteca Potosina (San Luis Potosí); Puebla[10,18,33]
NM: not mentioned.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Castillo-Pérez, L.J.; Ponce-Hernández, A.; Alonso-Castro, A.J.; Solano, R.; Fortanelli-Martínez, J.; Lagunez-Rivera, L.; Carranza-Álvarez, C. Medicinal Orchids of Mexico: A Review. Pharmaceuticals 2024, 17, 907. https://doi.org/10.3390/ph17070907

AMA Style

Castillo-Pérez LJ, Ponce-Hernández A, Alonso-Castro AJ, Solano R, Fortanelli-Martínez J, Lagunez-Rivera L, Carranza-Álvarez C. Medicinal Orchids of Mexico: A Review. Pharmaceuticals. 2024; 17(7):907. https://doi.org/10.3390/ph17070907

Chicago/Turabian Style

Castillo-Pérez, Luis J., Amauri Ponce-Hernández, Angel Josabad Alonso-Castro, Rodolfo Solano, Javier Fortanelli-Martínez, Luicita Lagunez-Rivera, and Candy Carranza-Álvarez. 2024. "Medicinal Orchids of Mexico: A Review" Pharmaceuticals 17, no. 7: 907. https://doi.org/10.3390/ph17070907

APA Style

Castillo-Pérez, L. J., Ponce-Hernández, A., Alonso-Castro, A. J., Solano, R., Fortanelli-Martínez, J., Lagunez-Rivera, L., & Carranza-Álvarez, C. (2024). Medicinal Orchids of Mexico: A Review. Pharmaceuticals, 17(7), 907. https://doi.org/10.3390/ph17070907

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop