Phytotherapies for COVID-19 in Latin America and the Caribbean (LAC): Implications for present and future pandemics

Danladi Chiroma Husaini (Department of Allied Health, Faculty of Health Sciences, University of Belize, Belmopan, Belize)
Orish Ebere Orisakwe (College of Health Sciences, University of Port Harcourt, Port Harcourt, Nigeria) (World Bank Africa Centre of Excellence in Public Health and Toxicological Research (PUTOR), Port Harcourt, Nigeria)
David Ditaba Mphuthi (Department of Health Sciences, University of South Africa, Muckleneuk Campus, Pretoria, South Africa)
Sani Maaji Garba (Faculty of Science, Usmanu Danfodiyo University, Sokoto, Nigeria)
Cecilia Nwadiuto Obasi (College of Health Sciences, University of Port Harcourt, Port Harcourt, Nigeria)
Innocent Ejiofor Nwachukwu (Allied Health Department, Medical Laboratory Program, University of Belize, Belmopan, Belize)

Arab Gulf Journal of Scientific Research

ISSN: 1985-9899

Article publication date: 10 January 2023

Issue publication date: 25 October 2023

1299

Abstract

Purpose

This review aims to provide synoptic documentation on acclaimed anecdotal plant-based remedies used by Latin America and the Caribbean (LAC) communities to manage COVID-19. The theoretical approaches that form the basis for using the anecdotally claimed phytotherapies were reviewed against current scientific evidence.

Design/methodology/approach

In this paper plant-based remedies for managing COVID-19 were searched on social and print media to identify testimonies of people from different communities in LAC countries. Information was extracted, evaluated and reviewed against current scientific evidence based on a literature search from databases such as Journal Storage (JSTOR), Excerpta Medica Database (EMBASE), SpringerLink, Scopus, ScienceDirect, PubMed, Google Scholar and Medline to explore the scientific basis for anecdotal claims.

Findings

A total of 23 medicinal plants belonging to 15 families were identified as phytotherapies used in managing COVID-19 in LAC communities.

Originality/value

The plant-based remedies contained valuable phytochemicals scientifically reported for their anti-inflammatory, antiviral, antioxidant and anticancer effects. Anecdotal information helps researchers investigate disease patterns, management and new drug discoveries. The identified acclaimed plant-based remedies are potential candidates for pharmacological evaluations for possible drug discovery for future pandemics.

Keywords

Citation

Husaini, D.C., Orisakwe, O.E., Mphuthi, D.D., Garba, S.M., Obasi, C.N. and Nwachukwu, I.E. (2023), "Phytotherapies for COVID-19 in Latin America and the Caribbean (LAC): Implications for present and future pandemics", Arab Gulf Journal of Scientific Research, Vol. 41 No. 4, pp. 591-609. https://doi.org/10.1108/AGJSR-08-2022-0144

Publisher

:

Emerald Publishing Limited

Copyright © 2022, Danladi Chiroma Husaini, Orish Ebere Orisakwe, David Ditaba Mphuthi, Sani Maaji Garba, Cecilia Nwadiuto Obasi and Innocent Ejiofor Nwachukwu

License

Published in Arab Gulf Journal of Scientific Research. Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode


1. Introduction

As of November 2022, COVID-19 has caused the death of over 6.5 million people globally, with Latin America and the Caribbean (LAC) having over 1 million deaths (WHO, 2022). The pandemic has severely affected the LAC societies, economies and health. Although currently, there is a high drive for the population to get vaccinated, many are still hesitant about taking the vaccines (United Nations, 2021; Marzo et al., 2022). Furthermore, despite the increase in the provision of quality information from both medical and scientific literature, the pandemic has continued to cause anxieties, fear, uncertainties and stigmatization due to the many published stories in social and traditional media (Wu & McGoogan, 2020). Notwithstanding the availability of vaccines and the mobilization by governments for their populations to get vaccinated, the variations and mutations of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) have continued to drive the search for pharmacological agents with the need for hand hygiene, physical distancing and other restrictions to curb the spread and infection rates of the virus still in place (Husaini & Abubakar, 2020).

The pandemic led many communities to seek palliative means to either prevent or alleviate the symptoms of the disease. In LAC, for instance, the fear of the disease led many populations to resort to self-care, self-help and self-medication (Matias, Dominski, & Marks, 2020). Many communities employed medicinal plants and other self-help remedies to prevent the infection or ameliorate symptoms (Orisakwe, Orish, & Nwanaforo, 2020; Lim, Teh, & Tan, 2021). In LAC and many other parts of the world, the use of medicinal plants to manage various diseases is deeply rooted in cultural, religious and traditional practices. Therefore, the uncertainties and fears of COVID-19 in many LAC populations prompted the drive to seek drastic anecdotal measures and solutions to manage the disease, with medicinal plants topping the list.

Perhaps there is no time in history where anecdotal information has spread globally like during the COVID-19 pandemic, especially with the advent of social media. Although vaccines have now been effectively produced to protect against most strains of COVID-19 viruses much of the anecdotal information provided the basis for symptomatic management of COVID-19 while serving as a starting point for scientific investigations (Attah et al., 2021). The ability of many medicinal plants to produce anti-viral, immunomodulatory and anti-inflammatory effects in a multimodal approach in the management of COVID-19 has been reported (Lim et al., 2021).

Presently, lack of documentation, potential acculturation and declining environmental and climatic degradation are causing a decline in indigenous knowledge of plants and their associated uses. The rich ecological rainforest, cultural diversity and the widely reported potential of medicinal plants used to manage various diseases in LAC have led to many communities exploring plant-based remedies for COVID-19. This review, therefore, provides synoptic documentation on acclaimed plant-based remedies used by LAC communities in the management of COVID-19. In addition, the theoretical approaches that form the basis for using the anecdotally claimed phytotherapies were presented while encouraging further research into the claims.

1.1 Review questions

  1. What indigenous phyto-remedies are used by LAC population to manage COVID-19 infection?

  2. Is there any scientific evidence to validate indigenous use of anecdotal remedies in the management of COVID-19?

2. Methodology

The methodology for this review was adopted and modified from 2 previous studies. In the first instance, the study methodology by Orisakwe et al. (2020) was adopted to identify anecdotal claims by residents in LAC. In this review stage, information on acclaimed remedies was sourced from social, print and broadcast media from November 2021 to March 2022. In addition, postings from local herbalists and traditional healers were included in the study, while the demographics of claimants were extracted where available and reported. Scientific published peer-reviewed research articles, hospitals and orthodox therapies were excluded from the first stage of the review. In the second instance, the identified anecdotal plant-based remedies were reviewed based on a literature search from databases such as JSTOR, EMBASE, SpringerLink, Scopus, ScienceDirect, PubMed, Google Scholar and Medline. The methodology in the second stage was a simplified and modified version of what was described by Attah et al. (2021).

3. Results

Anecdotally acclaimed plant-based home remedies for the management of COVID-19 were identified from testimonies of people from different communities in seven countries of LAC (Belize, Jamaica, Haiti, Bolivia, Brazil, Colombia and Peru) (Tables 1 and 2). Information on acclaimed remedies was provided by a medical practitioner, community leaders, herbalist, a trained respiratory therapist, voodoo leaders, vendors and indigenous community leaders. The herbs/plants are prepared by boiling, steeping or being taken fresh. The typical route of administration was oral, even though a few reports indicated inhalations with the proposed mechanism of action as a decongestant, immune boosting and purifying body systems. Twenty-three medicinal plants belonging to 15 families were identified as remedies used to manage COVID-19 (Table 3). Honey and vine skin were also identified as remedies for symptomatic management of COVID-19 in LAC.

4. Discussion

The world is facing the emergence of diverse and constantly mutating viruses in addition to complicated multidrug resistant bacteria. The plant kingdom constitutes a continuous source of pharmacologically active natural compounds to treat numerous human diseases and has continued to play an essential role in providing immediate health relief in LAC, particularly during sudden pandemics like COVID-19. Over the years, studies on plant-based therapies have led to the discovery and development of several drugs, while many phytochemicals have now been validated due to extensive scientific studies (Süntar, 2019). By early Chinese guidelines, traditional and complementary remedies have been recommended to control, prevent and treat coronavirus (Jin et al., 2020). Phytomedicines from a single plant may contain multiple pharmacological properties, creating many challenging but exciting phytochemical possibilities (Süntar, 2019). A paucity of information on confirmed antiviral actions of traditional remedies in LAC exists despite the region having a rich biodiversity. The anecdotal information provided by indigenous people might have served as immediate primary healthcare for COVID-19, and while vaccines are currently available, phytochemicals from plants provide a scaffold for discovering new drugs, hence the need for exploring anecdotal claims. The plant-based remedies mentioned by indigenous LAC residents for managing COVID-19 are reviewed against current scientific evidence and presented below.

4.1 Asteraceae

4.1.1 Taraxacum officinale (Dandelion)

Taraxacum officinale has traditionally been used to manage diarrhea, kidney disease, diabetes, fever, chronic skin disease, boils, spleen disorders, liver malfunction and as an anti-inflammatory agent (Schütz, Carle, & Schieber, 2006). Hydroxyphenylacetic acid is the most abundant phenolic compound in T. officinale. In addition, the plant is rich in a variety of vitamins and minerals (Bokelmann, 2022). The claim by the LAC communities that T. officinale could benefit persons with COVID-disease may have some substance, as reported in a few studies. For instance, T. officinale has been reported to have a protective effect on lung injury, a significant symptom of COVID-19. Liu, Xiong, Ping, Ju, and Zhang (2010) reported that T. officinale inhibits inflammatory cytokines Interleukin-6 (IL-6) and Tumor necrosis factor alpha (TNF-α) production. In animal studies, the plant increases superoxide dismutase activity while decreasing the lipopolysaccharide-induced myeloperoxidase (Liu et al., 2010). Furthermore, T. officinale has exhibited antiviral activities on HIV-1 virus, dengue virus-2, hepatitis C virus and influenza virus type A (Flores-Ocelotl et al., 2018). Inhibition of viral replication, reduction of viral nucleoprotein via inhibition of polymerase activity and decrease in reverse transcriptase activity were some of T. officinale's antiviral effects (Flores-Ocelotl et al., 2018). T. officinale has also been reported to have antioxidant and scavenger effects on free radicals, hydrogen peroxide, nitric oxide radicals and 2,2-diphenyl-1-picrylhydrazyl (Miłek, Marcinčáková, & Legáth, 2019). Recent studies have shown that T. Officinale blocks protein-protein interaction of COVID-19 spike to the human ACE2 receptor (Tran, Gigl, Le, Dawid, & Lamy, 2021). The antiviral, antioxidant and anti-inflammatory properties of T. officinale make the plant a potential phytotherapeutic agent with potential for drug development in use for pandemics.

4.1.2 Matricaria chamomilla (Chamomile)

Matricaria chamomilla used to treat various diseases has been published in animal and human studies. The low incidence of side effects and toxicity made the plant a worthwhile complementary medicine (Parham et al., 2020). The bioactive compounds in M. chamomilla included apigenin, phenolic compounds, terpenoids, flavonoids and matricin (Miraj & Alesaeidi, 2016). The plant inhibits the upregulation of H2O2-generated free radicals, may block peroxidation and protect against ethanol-induced hematological parameters disturbances and erythrocytes oxidative stress (Jabri et al., 2016). M. chamomilla, in combination with other medicinal plants, was reported to demonstrate the potential to interfere with COVID-19 propagation in Vero cells in a pilot study, making the claims for its use for COVID-19 to have some scientific backing (De Pellegrin et al., 2021).

4.1.3 Gnaphalium graveolens (Wira wira)

The genus of Gnaphalium is rich in caffeoylquinic acid derivatives, phytosterols, flavonoids, triterpenes, sesquiterpenes, anthraquinones, diterpenes and other biological compounds that give the plants their medicinal properties (Waibel, Achenbach, Torrenegra, Pedrozo, & Robles, 1992). G. graveolens as a bush remedy for COVID-19 has some scientific merits. Although not many studies have been done on G. graveolens, as a family, the genus of Gnaphalium has been reported to have anti-oxidant, anti-microbial, anti-inflammatory, anti-tussive, expectorant properties and strong scavenging activity as antioxidant (Rodríguez-Ramos & Navarrete, 2009; Zeng et al., 2011). Also, the plants can produce more potent relaxant activity than aminophylline and were proposed for obstructive pulmonary disease, chronic bronchitis and bronchial asthma (Rodríguez-Ramos & Navarrete, 2009). Finally, the anti-inflammatory effect of Gnaphalium was reported to be due to the combination of flavonol glycosides and caffeoylquinic acid derivatives, which G. graveolens possesses (Zeng et al., 2011).

4.2 Amaranthaceae

4.2.1 Chenopodium ambrosioides (Wormseed plant)

The World Health Organization has recognized C. ambrosioides as one species of plant commonly used in traditional medicine (Rios et al., 2017). In a recent review, Kasali, Tusiimire, Kadima, and Agaba (2021) summarized the traditional uses and phytochemical composition of C. ambrosioides (Table 3). The significant phytochemicals reported in C. ambrosioides are alkaloids, flavonoids, coumarins, glycosides, fatty acids, monoterpenes, lignans, sterols, phenolic acids and phenolic amides (Kasali et al., 2021). In addition, the anti-oxidant, anti-nociceptive and anti-inflammatory effects of C. ambrosioides have been confirmed (Calado et al., 2015). Although few studies explored the anti-viral activities of C. ambrosioides, the presence of phenols is worthy of note since phenols have been reported to have a broad spectrum of medicinal properties, anti-inflammatory and anti-oxidant activities and for the management of neurodegenerative, cardiovascular and diabetes mellitus (Costa et al., 2017). Daglia (2012) reported the anti-viral and anti-microbial potentials of C. ambrosioides. The use of C. ambrosioides to reduce fever in COVID-19 patients was reported in Morocco (Bary & Amraoui, 2020).

4.3 Amaryllidaceae

4.3.1 Allium cepa (Onion)

Scientific and animal studies on Allium cepa confirmed its pharmacological activities as anti-diabetic, immunological disorders, anti-oxidant, anti-allergic and respiratory disorders, anti-hypertensive and anti-inflammatory. A. cepa's active compounds and the ability to provide relief in bronchitis, coughs, common colds and asthma prompted the WHO to recommend its use (Beigoli et al., 2021). In addition, the anti-thrombotic, anti-asthmatic, anti-platelet, anti-bacterial, anti-toxic and anti-carcinogenic effects of A. cepa have been reported (Lebdah et al., 2022). The claims and utilization of A. cepa to manage COVID-19 related symptoms and signs by residents in LAC are therefore not without merit.

4.3.2 Allium sativum (Garlic)

Pre-clinical and clinical studies have reported the antiviral properties and effects of Allium sativum against a variety of viruses including the common cold and flu (Rehman, Saif, Hanif, & Riaz, 2019; Ming, Li, Li, Tang, & He, 2021). In a recent review, Rouf et al. (2020) narrated that garlic and its active organosulfur compounds possess substantial antiviral activity through enhancing human immune response, inhibition of reverse transcriptase, RNA polymerase, DNA synthesis, blocking viral entry into the host cells while downregulating the mitogen-activated protein signaling pathway and extracellular-signal-regulated kinase. Therefore, the various pharmacologic properties of A. sativum make the plant have great potential for drug development, especially for viral prophylaxis, including COVID-19 and futuristic pandemics.

4.4 Pinaceae

4.4.1 Pinus spp. (Pine Tree)

Folkloric evidence of the Pine spp. showed that the plants were used for asthma, hypertension, gastrointestinal tract disorders, hemorrhage, rheumatism and the prevention of other diseases (Lee, Park, et al., 2021). However, some scientific evidence recently reported the pharmacological effects of Pinus spp. to include anti-inflammatory, anti-diabetic, anti-cancer, anti-microbial and anti-oxidant activities, with α-Pinene, flavonoids, saponin, several phenolic compounds (Ha et al., 2020; Lee, Park, et al., 2021). The anti-viral effect of P. desiflora against human papillomavirus and influenza A virus has been reported, thereby validating local claims (Lee, Kang, Cheong, & Park, 2021).

4.5 Bromeliaceae

4.5.1 Ananas comosus (Pineapples)

The most significant sulfhydryl proteolytic enzyme found in Ananas comosus (Pineapples) is bromelain (Owoyele, Bakare, & Ologe, 2020; Hikisz & Bernasinska-Slomczewska, 2021). Due to the reported anti-coagulatory, anti-viral, cardioprotective and anti-inflammatory pharmacologic effects of bromelain, the pineapple plant extract was suggested as a potential complementary therapy for pre and post COVID-19 management (Owoyele et al., 2020; Hikisz & Bernasinska-Slomczewska, 2021). The inhibition of fibrin synthesis, the biosynthesis of kinins to prevent inflammation, and the conversion of prothrombin to thrombin make bromelain a compelling candidate to improve circulatory and cardiovascular functions by lessening coagulopathy, thereby improving circulation (Owoyele et al., 2020). Although the exact anti-viral mechanisms of action of bromelain are not fully understood, a recent review strongly suggests that the plant extract is beneficial in various forms of cancers, cardiovascular diseases, inflammation disorders, coagulation disorders and infectious diseases (Hikisz & Bernasinska-Slomczewska, 2021). The claim, therefore, for the use of A. comosus to manage COVID-19 by the indigenous people of LAC has some scientific backings.

4.6 Lauraceae

4.6.1 Persea Americana (Avocados)

Wu et al. (2019) reported the anti-viral effects of (2 R,4 R)-1,2,4-trihydroxyheptadec-16-yne, a natural product extracted from P. americana that suppresses the replication of dengue virus using animal models. In general, P. americana has been used in complementary medicine, and the phytoconstituents are reported to demonstrate anti-oxidant, anti-bacterial, anti-viral and hepatoprotective properties (Ajayi, Awala, Olalekan, & Alabi, 2017). The composition of bioactive compounds such as steroids, monoterpenoids, flavonoids, sesquiterpenoids, carotenoids, triterpenoids and long-chain fatty acid derivatives gives it significant potential for use in pre and post COVID-19 management; hence validating local claims.

4.7 Malvaceae

4.7.1 Gossypium (Cotton plant)

Many varieties of the Gossypium genus are available, with the commonly cultivated species being G. arboretum, G. barbadense, G. herbaceum and G. hirsutum. As part of their active phytoconstituents, cotton plants contain proteins, phlorotannins, tannins, terpenes, sesquiterpenes, monoterpenes, triterpenes, flavonoids, alkaloids, phenols, steroids, fatty and phenolic acids (Lima et al., 2021). Furthermore, Gossypium has been reported to have the potential to manage dysentery, diarrhea, genitourinary and respiratory tract infections, injuries, anti-microbial and oral candidiasis (Lima et al., 2021). The most-reported species used for medicinal purposes in LAC are G. barbadense, G. hirsutum and G. herbaceum, while the active ingredient in the plant's defense against herbivorous insects and pathogens is gossypol (Ling et al., 2016). The virucidal effects of gossypol were reported against the influenza virus where G. barbadense leaves extract demonstrated inhibition of viral adsorption and viral replication by the host cell (Ling et al., 2016; Lima et al., 2021). Although not many studies reported the antiviral activities of Gossypium spp, the indication by LAC indigenes is a testimony to its usefulness, at least for symptomatic management of viral activities, hence the need to further explore its usefulness as plants for future pandemics or post COVID-19 research.

4.7.2 Malva spp (Mallow)

The phytochemical composition of Malva spp includes flavonoids, polysaccharides, monoterpenes, tannins, Vitamin A, C and E, polyphenols, aromatic compounds and coumarins (Benso et al., 2021). Traditionally the plant has been used to manage inflammation, gastrointestinal tract disorders, rheumatism, bronchitis, cold, cough, skin problems and wound healing, while its anti-microbial, anti-inflammatory, anti-oxidant, anti-cancer, anti-nociceptive and hepatoprotective effects have also been reported (Paul, 2016). Furthermore, the effects of Malva spp on the influenza virus while inhibiting the reverse transcriptase enzyme in HIV (Anuradha, Muhtari, Lone, Tripathi, & Sanjeevi, 2018). Although limited studies are available from clinical trials, the traditional use, folkloric writings and data obtained from preclinical studies validate the medicinal benefits of M. sylvestris hence supporting acclaimed usage for COVID-19 while encouraging further clinical studies towards drug discovery.

4.8 Moringaceae

4.8.1 Moringa oleifera (Moringa)

Several active compounds have been reported in M. oleirefa. Bioactive compounds like phenolic acids, oleic acids, ascorbic acids, alkaloids, saponins, resins, tannins, glycosides, flavonoids, carbohydrates, vitamins, carotenoids, polyphenols, etc. (Feustel et al., 2017). Furthermore, the plant leaves, seeds, flowers and pods, have been used traditionally as an anti-diuretic, anti-diabetic, anti-hypertensive, anti-pyretic, malnutrition, anti-inflammatory and anti-oxidant activities. Furthermore, scientific evaluations of M. oleifera have shown the plant to be anti-inflammatory, anti-cancer, anti-fungal, anti-bacterial, anti-hypertensive and hepatoprotective (Biswas, Nandy, Mukherjee, Pandey, & Dey, 2020; Mphuthi & Husaini, 2022). Potent anti-viral activity of M. oleifera on New Castle Disease, Aphthovirus (Foot-and-mouth disease virus), Epstein Barr Virus, Hepatitis B Virus, Herpes Simplex Virus and Human Immunodeficiency Virus has been reported (Biswas et al., 2020). Immune boosting, inhibition of targeted viral protein or enzymes used for replication, inhibition of viral activation, decreased cytokine IL-6 and translated surface antigens (HBsAg) (Feustel et al., 2017; Biswas et al., 2020). M. oleifera has recently been suggested as a potential preventative and therapeutic agent against COVID-19, validating indigenous usage in LAC (Sen, Bhaumik, Debnath, & Debnath, 2021). Most of the secondary phytoconstituents of M. oleifera that displayed drug-likeness did not show predictable toxicity.

4.9 Myrtaceae

4.9.1 Eucalyptus spp (Eucalyptus)

Several species of Eucalyptus have been identified; however, E. globulus, E. smithii and E. polybractea have been primarily reported as sources of cosmetic, nutraceutical and pharmaceutical products (Salehi et al., 2019). The primary constituent of Eucalyptus oil is eucalyptol, with prominent bioactivities such as anti-inflammatory, anti-septic, anti-microbial and anti-oxidant effects (Elaissi et al., 2011). In addition to its use for colds, congestion and cough, Eucalyptus oil has been used to boost the immune and respiratory tract system, reduce inflammation, lower blood glucose, protect skin health, act as an antibacterial and anxiolytic (Nordqvist, 2017). Eucalyptus oil demonstrated significant antiviral activity against influenza virus and herpes simplex virus type 1 (Elaissi et al., 2011; Vimalanathan & Hudson, 2014). The acclaimed usage by indigenous LAC residents to relieve the symptoms of COVID-19, especially as an anti-inflammatory agent, immune booster and possibly reduce respiratory congestion while clearing the airways, is validated by scientific inquiry. Rational use of Eucalyptus oil can improve the general immunity of the body and especially the immune function of the respiratory tract in animal studies (Shao et al., 2020). Because most COVID-19 patients exhibit respiratory tract disorders due to hyper-inflammation associated with increased circulating cytokines, Eucalyptus oil might be a reasonable consideration for symptomatic relive and clearing of the airways (Asif, Saleem, Saadullah, Yaseen, & Al Zarzour, 2020).

4.9.2 Syzygium jambos (Jambu, water apple)

Plants from the Syzygium genus, including S. jambos, have traditionally been used to manage toothache, leprosy, syphilis, wounds and gastrointestinal tract disorders (Chua, Lim, Ling, Chye, & Koh, 2019). The presence of triterpenoids, sterols, tannins, flavonoids and polyphenols have been reported as part of the secondary metabolites found in S. jambos (Ochieng, Ben Bakrim, Bitchagno, Mahmoud, & Sobeh, 2022). In addition, the plant extracts have been reported to exhibit hepatoprotective, anti-cancer, analgesics, anti-inflammatory properties and a broad spectrum of anti-bacterial effects (Subbulakshmi, Satish, & Shabaraya, 2021). Furthermore, the anti-viral effects of S. jambos were reported where the leaf extracts demonstrated significant antiviral effects against different types of herpes simplex virus and the virus involved in vesicular stomatitis (Athikomkulchai, Lipipun, Leelawittayanont, Khanboon, & Ruangrungsi, 2008). The combined anti-inflammatory and anti-viral activities of S. jambos and its low toxicity make it a candidate for exploring its potential for use in COVID-19 and future pandemics. The reports support the use of the S. jambos plant by LAC residents in their bid to curb the symptoms of COVID-19.

4.10 Phytolaccaceae

4.10.1 Petiveria alliacea L (Mucuraca)

The traditional anecdotal claims have long sustained the use of P. alliacea in managing the influenza virus, while scientific reports suggest the plant has a significant effect on the hepatitis C virus (Lowe, Toyang, Roy, Watson, & Bryant, 2016). Flavonoids, dibenzyl trisulfide, essential oils, steroids, coumarins, tannins, alkaloids and polyphenols are bioactive compounds in P. alliacea (Luz et al., 2016). The virucidal effects of P. alliacea were linked directly to Dibenzyl trisulfide, which also showed evidence against HIV and as an anticancer agent, with inhibition of reverse transcriptase and inter-action with the mitogen-activated protein, extracellular-regulated kinases 1 and 2 proposed as the mechanism of action (Lowe et al., 2015, 2021). Evidence from scientific studies coupled with traditional anecdotal use of P. alliacea for various ailments gives credence to the use of the plant during the COVID-19 pandemic and hence the need for further studies to ascertain the molecular mechanisms responsible for this claim in LAC.

4.11 Piperaceae

4.11.1 Piper aduncum (Matico, spiked pepper, buddleja globose)

The pharmacological activities of extracts from P. aduncum have been reported to have anti-cancer, anti-tumor, anti-microbial, anti-parasitic, anti-inflammatory, insecticidal and the management of other diseases (Monzote, Scull, Cos, & Setzer, 2017). In a recent review, Taher et al. (2020) summarized the traditional uses of P. aduncum and indicated that the plant contains 23 essential oil components, benzoic acid derivatives, phenylpropanoid, flavonoids, chromenes, chalcones, sesquiterpenes and monoterpenes. Radice et al. (2018) reported the antiviral effects of dillapiole, a significant component of P. aduncum's essential oil, on the West Nile virus. The anti-viral effects of P. aduncum on poliovirus have also been reported (Lohézic-Le Dévéhat, Bakhtiar, Bézivin, Amoros, & Boustie, 2002). Although few studies reported the anti-viral effects of P. aduncum. The traditional use by LAC residents in the management of COVID-19 is not devoid of credence, hence the need to further explore the pharmacological properties of the plant's anti-viral effects for COVID-19 and future pandemics.

4.12 Poaceae

4.12.1 Cymbopogan citratus (Fever grass, lemongrass, yerbaluisa)

The Cymbopogan genus has been used in medicine globally as analgesics, anti-inflammatory, anti-pyretic, antiseptics and tranquilizers, having alkaloids, flavonoids and phenolic acids as some of the secondary metabolites that give the plants their bioactive abilities (Avoseh, Oyedeji, Rungqu, Nkeh-Chungag, & Oyedeji, 2015). Significant in vitro and in silico prospective anti-dengue activities with P. citratus were reported (Rosmalena et al., 2019), while essential oil from C. citratus reduced the activity of nonenveloped murine norovirus (Gilling, Kitajima, Torrey, & Bright, 2014). Furthermore, C. citratus has been evaluated for its antiviral activities against measles and herpes simplex virus 1 (Adibah, Nazlina, & Ahmad, 2010; Linton, Jerah, & Bin Ahmad, 2013), while recently, C. citratus was reported to demonstrate potential against human mastadenovirus serotype 5 (Chiamenti et al., 2019). The global distribution of Cymbopogan citratus, availability and safety makes the plant a potential anecdotal anti-COVID-19 candidate in LAC. Further investigations into the pharmacological anti-viral mechanism of action of Cymbopogan citratus should be conducted to provide specific validation for its use in future pandemics.

4.13 Rutaceae spp

4.13.1 Rutaceae spp

Apart from their economic importance as aromatic oils, timber and fruits, the citrus family (Rutaceae spp) is significant as the potential for medicines and medicinal substances. In a recent review, Coimbra, Ferreira, and Duarte (2020) summarized the bioactive composition and activities of the citrus family to include anti-parasitic, anti-viral, anti-oxidant, anti-fungal, anti-inflammatory, anti-microbial, with flavonoids, coumarins, phenolic acids, sterols and essential oils forming some of the major constituents of the plants. The antiviral effects of the citrus family were demonstrated against the hepatitis C virus where the extract of R. angustifolia inhibited the hepatitis C virus RNA replication and viral protein synthesis via chalepin and pseudane IX, the active ingredient identified in the extract (Wahyuni, Mahfud, Permatasari, Widyawaruyanti, & Fuad, 2019). The old traditional use of the citrus family, coupled with the availability of scientific data, made the plants targets for experimentation by LAC residents to alleviate the symptoms of COVID-19 infections, which ravages the world with no solution in sight.

4.14 Verbenaceae

4.14.1 Verbena officinalis (Vervain, Verbena)

A certified medical practitioner (Internist) in the country of Belize testified that Verbena officinalis was helpful in the symptomatic management of COVID-19, having used the extracts of the plant in the management of his COVID-19 infection (Channel5belize). Depression, anxiety, upper respiratory tract illnesses, gastrointestinal tract disturbances, insomnia, pain and aches were some of the purported traditional claims for V. officinalis (Ahmed, Ahmed Qasim, Ashraf, & Maab, 2017). V. officinalis extracts and metabolites have been reported to include analgesic, anti-cancer, neuroprotective, anti-inflammatory, anti-microbial and antioxidant activities, with essential oils, polyphenols, phenylpropanoid glycosides, sterols and flavonoids (Kubica, Szopa, Dominiak, Luczkiewicz, & Ekiert, 2020). Because of its wide margin of safety and antioxidant effects on the cells, a monograph of V. officinalis was included in the European and Chinese Pharmacopoeia (Rehecho et al., 2011). The inclusion of the plant in pharmacopeias is a substantiation of its biological efficacy after several scientific investigations confirming V. officinalis to demonstrate anti-oxidant, anti-fungal, neuroprotective, anti-bacterial and anti-inflammatory properties hence corroborating local claims for current use in the symptomatic management of COVID-19 (Kubica et al., 2020).

4.15 Zingiberaceae

4.15.1 Curcuma longa (Tumeric)

Recent reviews on curcumin, the active ingredient in C. longa, showed that the natural compound has sufficient in vitro activity against a wide range of viruses such as adenoviruses, dengue viruses, human cytomegalovirus, herpes simplex viruses, hepatitis B virus, human papillomavirus, coxsackievirus B3, human norovirus, human immunodeficiency virus, ebola virus, human T-lymphocyte virus, Rift Valley fever virus, influenza A virus, Chikungunya virus, respiratory syncytial virus, Japanese encephalitis virus, zika virus and coronavirus (SARS-CoV) among others (Ardebili et al., 2021). Interrupting viral replication via modulating host cell signaling pathways and blocking viral attachment and entry by abrogating the function of viral envelopes are some of the mechanisms of action of curcumin (Naseri et al., 2017). The experimental and clinical evidence on the pharmacological effects of C. longa on several viruses justifies the use of the plant by many residents in LAC.

4.15.2 Zingerber offinale (Ginger)

The residents of LAC mentioned ginger as one of the acclaimed bush remedies for COVID-19. The major phytochemicals found in ginger are gingerols, shogaols, phenolic acids and paradols, with the active compounds reported to have 4-hydroxy 2-methoxyphenyl moiety and demonstrating anti-oxidant, anti-inflammatory, anti-cancer and anti-platelet activities (Idris, Yasin, & Usman, 2019). The anti-oxidant property of garlic is due to the high concentration of phenolic compounds leading to scavenging free radicals (Daliri et al., 2019). Dorra, El-Berrawy, Sallam, and Mahmoud (2019) reported that ginger extracts inhibited the growth and development of the H5N1 virus in a dose-dependent manner with varying antiviral activity. Ginger's anti-viral, anti-oxidant and anti-inflammatory properties make the spice a potential source for drug discovery in future pandemics.

5. Conclusion

Medicinal plants have a long history of patronage because of ease of availability, low cost, better tolerance and wide acceptance of safety because they come from nature. Some anecdotal information from LAC was reviewed against the backdrop of scientific research evidence. Our review showed that the anecdotal claims from medicinal plants in COVID-19 comprise primary and secondary metabolites that produce immunomodulatory, anti-inflammatory, anti-oxidant and anti-viral anti-oxidant properties, validating local indigenous claims. The absence of studies on formulations and standardization poses challenges to the use of medicinal plants in the management of COVID-19. Further studies on their unique mechanism on COVID-19, safety, quality, adverse effects, interactions and dosing need to be conducted. The enormous rich rainforest and ethnopharmacopeia of LAC make the region a potential hub for natural-based pharmaceuticals and increased predispositions for new drug discoveries. Discovering the pharmacological properties of medicinal plants and mapping their transcriptomes and genomes to produce target drugs should be the central focus of modern research in LAC.

Anecdotal plant-based home remedies for COVID-19 in the Caribbean and Central America

Place claim was made city/countryDemographics of claimantAcclaimed remedy/plant partPreparation/recipe/doseAcclaimed mechanism of actionSource
Belize City, BelizeAn acclaimed renowned herbalist/healerVervain (Verbena officinalis)Leaves are boiled for 15–20 minutes and drank as teaDecongestant7newsbelize (2020)
The entire plant (root, stem and leaves)Lime can be added
Belize City, BelizeMedical Doctor (Internist)Vervain (Verbena officinalis)Not availableNot availableChannel5Belize (2021)
Scott’s Hall and Charles Town Maroon Community, JamaicaCommunity leadersDandelion, avocado, garlic and citrus fruits. Other herbsNot availableImmune boasterThomas (2021)
JamaicaHerbalistPine needles with fever grassNot availableNot availableHendricks (2020)
A Jamaican living in New York, USARespiratory therapistTea from turmeric, garlic and gingerNot availableNot availableMiami Times (2020)
Port-Au-Prince, HaitiVoodoo leadersTea from moringa, eucalyptus, ginger and honeyNot providedImmune boasterNationsNews (2020)

Anecdotal plant-based home remedies for COVID-19 in South America

Place claim was made city/countryDemographics of claimantAcclaimed remedy/plant partPreparation/recipe/doseAcclaimed mechanism of actionSource
BoliviaBloggerEucalyptus leaves, followed by chamomile, wira-wira, bee honey, ginger, matico leaves and propolis (a resin-like material made by bees)Herbal fusion taken as tea or inhaledRespiratory diseases and boosting the immune system
Also, disinfectant
Gutiérrez and Dewick (2021)
City of Belem, BrazilStreet VendorCotton leaves and wormseed leavesCotton seed and wormseed leaves are blended, mixed with honeyNot availableSharma (2020)
Amazon
Portel, southwest of Marajo island in Para state, Brazil
VillagersTea of JambuNot availableNot availableSarkar (2020)
Brazil Avocados and pineapplesSmoothies, juice, eat ripe avocadosNot availableLa Nación (2021)
Para state, BrazilKayapó indigenous people of Para stateVine skin (name not disclosed)The skin of the vine is boiled and drank as teaNot availableLandau (2021)
Bogota (the Clan Tigre of the Tikuna Yoi ethnic group), ColombiaPublic health assistant and herbalistGinger and garlic (purifiers)
Bitter plant, such as the mucuraca, the dandelion, the rue (antibiotics)
such as yerbaluisa, orange leaves, mallow, cotton leaves (inflammatory
Not availableBody systems purifier, anti-biotics
Anti-inflammatory
Jimenez and Trivino (2020)
Pucallpa, PeruIndigenous Shipibo communityBuddleja globosa plant (Matico) has green leaves and a tangerine-colored flower. Herbs, syrups of onion and gingerHerbs, steeped in boiling water and the vapor/steam was used for steam inhalation
Syrups of onion and ginger used to help clear congested airways
DecongestantABD and Armario (2020)

Family, scientific and local names for plants used for COVID-19 in Latin America and the Caribbean (LAC)

References

7newsbelize. (2020). Vervine, COVID blocker or folksy myth?. 7newsbelize.com. Available from: http://www.7newsbelize.com/sstory.php?nid=55668 (accessed 26 November 2021).

ABD, R., & Armario, C. (2020). Peru's indigenous turn to ancestral remedies to fight virus. Associate Press. Available from: https://apnews.com/article/virus-outbreak-pandemics-peru-9c1eefb60237e0354f3935613514ab35

Adibah, A. B., Nazlina, I., & Ahmad, I. B. (2010). Anti-HSV-1 activity of Cymbopogon nardus (L.) rendle fractions. Malaysian Applied Biology, 39(2), 1923.

Ahmed, D., Ahmed Qasim, K., Ashraf, C. M., & Maab, H. (2017). Verbena officinalis a herb with promising broad spectrum antimicrobial potential. Cogent Chemistry, 3(1), 1363342. doi: 10.1080/23312009.2017.1363342.

Ajayi, O., Awala, S., Olalekan, O., & Alabi, O. (2017). Evaluation of antimicrobial potency and phytochemical screening of Persea americana leaf extracts against selected bacterial and fungal isolates of clinical importance. Microbiology Research Journal International, 20(1), 111. doi: 10.9734/mrji/2017/24508.

Anuradha, J., Muhtari, K., Lone, H., Tripathi, S., & Sanjeevi, R. (2018). Potentials of herbs on the rescue of influenza prevention and Control. Journal of Chemistry and Chemical Sciences, 8(5), 898903. doi: 10.29055/jccs/658.

Ardebili, A., Pouriayevali, M. H., Aleshikh, S., Zahani, M., Ajorloo, M., …, & Izanloo, A. (2021). Antiviral therapeutic potential of curcumin: An update. Molecules (Basel, Switzerland), 26(22), 6994. doi:10.3390/molecules26226994.

Asif, M., Saleem, M., Saadullah, M., Yaseen, H. S., & Al Zarzour, R. (2020). Covid-19 and therapy with essential oils having antiviral, anti-inflammatory, and immunomodulatory properties. Inflammopharmacology, 28(5), 11531161. doi: 10.1007/s10787-020-00744-0.

Athikomkulchai, S., Lipipun, V., Leelawittayanont, T., Khanboon, A., & Ruangrungsi, N. (2008). Anti-herpes simplex virus activity of Syzygium jambos. Journal of Health Research, 22(1), 4951.

Attah, A. F., Fagbemi, A. A., Olubiyi, O., Dada-Adegbola, H., Oluwadotun, A., Elujoba, A., & Babalola, C. P. (2021). Therapeutic potentials of antiviral plants used in traditional African medicine with covid-19 in focus: A Nigerian perspective. Frontiers in Pharmacology, 12. doi: 10.3389/fphar.2021.596855.

Avoseh, O., Oyedeji, O., Rungqu, P., Nkeh-Chungag, B., & Oyedeji, A. (2015). Cymbopogon species; ethnopharmacology, phytochemistry and the pharmacological importance. Molecules (Basel, Switzerland), 20(5), 74387453. doi: 10.3390/molecules20057438.

Bary, K., & Amraoui, B. (2020). MOROCCAN traditional medicine for the prevention and relief of corona virus COVID-19 symptoms. Journal of Applied Science and Environmental Studies, 3(4), (2020), 199208. Available from: http://revues.imist.ma/index.php?journal=jases

Beigoli, S., Behrouz, S., Memarzia, A., Ghasemi, S. Z., Boskabady, M., …, & Marefati, N. (2021). Effects of allium cepa and its constituents on respiratory and allergic disorders: A comprehensive review of experimental and clinical evidence. Evidence-Based Complementary and Alternative Medicine, 2021, 122. doi:10.1155/2021/5554259.

Benso, B., Rosalen, P. L., Pasetto, S., Marquezin, M., Freitas-Blanco, V., & Murata, R. M. (2021). Malva sylvestris derivatives as inhibitors of HIV-1 BaL infection. Natural Product Research, 35(6), 10641069. doi: 10.1080/14786419.2019.1619720.

Biswas, D., Nandy, S., Mukherjee, A., Pandey, D. K., & Dey, A. (2020). Moringa oleifera lam. And derived phytochemicals as promising antiviral agents: A review. South African Journal of Botany, 129, 272282. doi: 10.1016/j.sajb.2019.07.049.

Bokelmann, J. M. (2022). Medicinal herbs in primary care: An evidence-guided reference for healthcare providers (pp. 303307). Elsevier. doi: 10.1016/b978-0-323-84676-9.00039-8.

Calado, G. P., Lopes, A. J., Costa Junior, L. M., Lima, F., Silva, L. A., …, & Pereira, W. S. (2015). Chenopodium ambrosioides L. Reduces synovial inflammation and pain in experimental Osteoarthritis. PLoS One, 10, e0141886. doi:10.1371/journal.pone.0141886.

Channel5Belize.com (2021). Dr. Cuellar on use of herbal medicine in covid treatment. Channel5Belize.com. Available from: https://edition.channel5belize.com/archives/224867 (accessed 29 November 2021).

Chiamenti, L., Silva, F. P., Schallemberger, K., Demoliner, M., Rigotto, C., & Fleck, J. D. (2019). Cytotoxicity and antiviral activity evaluation of Cymbopogon SPP hydroethanolic extracts. Brazilian Journal of Pharmaceutical Sciences, 55. doi: 10.1590/s2175-97902019000118063.

Chua, L. K., Lim, C. L., Ling, A.P.K., Chye, S. M., & Koh, R. Y. (2019). Anticancer potential of Syzygium species: A review. Plant Foods Hum. Nutr., 74(1), 1827. doi: 10.1007/s11130-018-0704-z.

Coimbra, A. T., Ferreira, S., & Duarte, A. P. (2020). Genus ruta: A natural source of high value products with biological and pharmacological properties. Journal of Ethnopharmacology, 260, 113076. doi: 10.1016/j.jep.2020.113076.

Costa, C., Tsatsakis, A., Mamoulakis, C., Teodoro, M., Briguglio, G., Caruso, E., …, & Fenga, C. (2017). Current evidence on the effect of dietary poly- phenols intake on chronic diseases. Food and Chemical Toxicology, 110, 286299.

Daglia, M. (2012). Polyphenols as antimicrobial agents. Current Opinion in Biotechnology, 23(2), 174181.

Daliri, E. B., Kim, S. H., Park, B. J., Kim, H. S., Kim, J. M., Kim, H. S., & Oh, D. H. (2019). Effects of different processing methods on the antioxidant and immune stimulating abilities of garlic. Food Science and Nutrition, 7(4), 12221229. doi: 10.1002/fsn3.942.

De Pellegrin, M. L., Rohrhofer, A., Schuster, P., Schmidt, B., Peterburs, P., & Gessner, A. (2021). The potential of herbal extracts to inhibit SARS-CoV-2: A pilot study. Clinical Phytoscience, 7(1), 29. doi: 10.1186/s40816-021-00264-6.

Dorra, N., El-Berrawy, M., Sallam, S., & Mahmoud, R. (2019). Evaluation of antiviral and antioxidant activity of selected herbal extracts. Journal of High Institute of Public Health, 49(1), 3640. doi: 10.21608/jhiph.2019.29464.

Elaissi, A., Salah, K. H., Mabrouk, S., Larbi, K. M., Chemli, R., & Harzallah-Skhiri, F. (2011). Antibacterial activity and chemical composition of 20 Eucalyptus species' essential oils. Food Chemistry, 129, 14271434.

Feustel, S., Ayón-Pérez, F., Sandoval-Rodriguez, A., Rodríguez-Echevarría, R., Contreras-Salinas, H., Armendáriz-Borunda, J., & Sánchez-Orozco, L. V. (2017). Protective effects of Moringa oleifera on HBV genotypes C and H transiently transfected huh7 cells. Journal of Immunology Research, 2017, 19. doi: 10.1155/2017/6063850.

Flores-Ocelotl, M. R., Rosas-Murrieta, N. H., Moreno, D. A., Valle- jo-Ruiz, V., Reyes-Leyva, J., Domínguez, F., & Santos-Lópezcor- responding, G. (2018). Taraxacum officinale and Urtica dioica ex- tracts inhibit dengue virus serotype 2 replication in vitro. BMC Complementary and Alternative Medicine, 18, 95.

Gilling, D. H., Kitajima, M., Torrey, J. R., & Bright, K. R. (2014). Mechanisms of antiviral action of plant antimicrobials against murine norovirus. Applied and Environmental Microbiology, 80(16), 48984910. doi: 10.1128/AEM.00402-14.

Gutiérrez, F., & Dewick, E. (2021). As the health system buckles from covid-19 pressure, Bolivians turn to herbal medicine. Global Voices. Available from: https://globalvoices.org/2020/07/08/as-the-health-system-buckles-from-covid-19-pressure-bolivians-turn-to-herbal-medicine/ (accessed 7 December 2021).

Ha, T., Lee, B. W., Nguyen, N. H., Cho, H. M., Venkatesan, T., Doan, T. P., …, & Oh, W. K. (2020). Antiviral activities of compounds isolated from Pinus densiflora (pine tree) against the influenza A virus. Biomolecules, 10(5), 711. doi:10.3390/biom10050711.

Hendricks, S. (2020). Herb man touts covid cure. Jamaica Observer. Available from: https://www.jamaicaobserver.com/front-page/herb-man-touts-jamaican-claims-plant-medicine-can-stand-up-to-deadly-disease_195246 (accessed 7 October 2021).

Hikisz, P., & Bernasinska-Slomczewska, J. (2021). Beneficial properties of bromelain. Nutrients, 13(12), 4313. doi: 10.3390/nu13124313.

Husaini, D. C., & Abubakar, Y. I. (2020). COVID-19: Belize's success story in containing community spread has suffered a setback. Asia-Pacific Journal of Public Health, 32(8), 536538. doi: 10.1177/1010539520962604.

Idris, N. A., Yasin, H. M., & Usman, A. (2019). Voltammetric and spectroscopic determination of polyphenols and antioxidants in ginger (Zingiber officinale Roscoe). Heliyon, 5(5). doi: 10.1016/j.heliyon.2019.e01717.

Jabri, M.-A., Sani, M., Rtibi, K., Marzouki, L., El-Benna, J., Sakly, M., & Sebai, H. (2016). Chamomile decoction extract inhibits human neutrophils ros production and attenuates alcohol-induced haematological parameters changes and erythrocytes oxidative stress in rat. Lipids in Health and Disease, 15(1). doi: 10.1186/s12944-016-0233-4.

Jimenez, D.C.C., & Trivino, M. P. (2020). Amazon indigenous woman fights virus with native plants. AA News Broadcasting System (HAS). Available from: https://www.aa.com.tr/en/americas/amazon-indigenous-woman-fights-virus-with-native-plants/1883566.

Jin, Y. H., Cai, L., Cheng, Z. S., Cheng, H., Deng, T., Fan, Y. P., …, & Ma, L. L. (2020). A rapid advice guideline for the diagnosis and treatment of 2019 novel coronavirus (2019-nCoV) infected pneumonia (standard version). Military Medical Research, 7(1), 4. doi:10.1186/s40779-020-0233-6.

Kasali, F. M., Tusiimire, J., Kadima, J. N., & Agaba, A. G. (2021). Ethnomedical uses, chemical constituents, and evidence-based pharmacological properties of chenopodium ambrosioides L.: Extensive overview. Future Journal of Pharmaceutical Sciences, 7(1). doi: 10.1186/s43094-021-00306-3.

Kubica, P., Szopa, A., Dominiak, J., Luczkiewicz, M., & Ekiert, H. (2020). Verbena officinalis (common vervain) – a review on the investigations of this medicinally important plant species. Planta Medica, 86(17), 12411257. doi: 10.1055/a-1232-5758.

La Nación. (2021). #Nocomacuento: Consumir Limón, Mango, aguacate, Ajo, Mandarina, piña y naranja no protege Del Covid-19. La Nación. Available from: https://www.nacion.com/no-coma-cuento/nocomacuento-consumir-limon-mango-aguacate/NBT2IKB6MBDINLDLFWXYQMZQLI/story/ (accessed 20 January 2022).

Landau, L. (2021). ‘You wake up well’: Amazon villagers take vine tea to treat Covid. Reuters. Available from: https://www.reuters.com/article/us-brazil-coronavirus-indigenous-treatme-idUSKBN29C1TS

Lebdah, M., Tantawy, L., Elgamal, A. M., Abdelaziz, A. M., Yehia, N., Alyamani, A. A., …, & Elsayed Mohamed, M. (2022). The natural antiviral and immune stimulant effects of allium cepa essential oil onion extract against virulent Newcastle Disease Virus. Saudi Journal of Biological Sciences, 29(2), 12391245. doi: 10.1016/j.sjbs.2021.09.033.

Lee, H.-J., Park, M., Choi, H. J., Nowakowska, A., Moon, C., Kwak, J. H., & Kim, Y. B. (2021a). Pine needle extract applicable to topical treatment for the prevention of human papillomavirus infection. Journal of Microbiology and Biotechnology, 31(1), 137143. doi: 10.4014/jmb.2010.10055.

Lee, J., Kang, H. K., Cheong, H., & Park, Y. (2021b). A Novel Antimicrobial Peptides From Pine Needles of Pinus densiflora Sieb. et Zucc. Against Foodborne Bacteria. Frontiers in Microbiology, 12, 662462. doi: 10.3389/fmicb.2021.662462.

Lim, X. Y., Teh, B. P., & Tan, T. Y. (2021). Medicinal plants in covid-19: Potential and limitations. Frontiers in Pharmacology, 12. doi: 10.3389/fphar.2021.611408.

Lima, L. F., Oliveira, J. O., Carneiro, J. N., Lima, C. N., Coutinho, H. D., & Morais-Braga, M. F. (2021). Ethnobotanical and antimicrobial activities of the Gossypium (cotton) genus: A review. Journal of Ethnopharmacology, 279, 114363. doi: 10.1016/j.jep.2021.114363.

Ling, Li, Zheng, Li, Wang, K., Liu, Y., Li, Y., & Wang, Q. (2016). Synthesis and antiviral, insecticidal, and fungicidal activities of gossypol derivatives containing alkylimine, oxime or hydrazine moiety. Bioorganic and Medicinal Chemistry, 24(3), 474483. doi: 10.1016/j.bmc.2015.08.015.

Linton, R. E. A., Jerah, S. L., & Bin Ahmad, I. (2013). The effect of combination of octadecanoic acid, methyl ester and ribavirin against measles virus. International Journal of Scientific and Technology Research, 2(10), 181184.

Liu, L., Xiong, H., Ping, J., Ju, Y., & Zhang, X. (2010). Taraxacum offici- nale protects against lipopolysaccharide-induced acute lung injury in mice. Journal of Ethnopharmacology, 130, 392397.

Lohézic-Le Dévéhat, F., Bakhtiar, A., Bézivin, C., Amoros, M., & Boustie, J. (2002). Antiviral and cytotoxic activities of some Indonesian plants. Fitoterapia, 73(5), 400405. doi: 10.1016/s0367-326x(02)00125-9.

Lowe, H., Toyang, N., Heredia, A., Ayeah, K., Watson, C., & Bryant, J. (2015). Petiveria alliacea L (Guinea hen weed) and its major metabolite dibenzyl trisulfide demonstrate HIV-1 reverse transcriptase inhibitory activity. European Journal of Medicinal Plants, 5(1), 8894. doi: 10.9734/ejmp/2015/12064.

Lowe, H., Toyang, N., Roy, S., Watson, C., & Bryant, J. (2016). Inhibition of the human hepatitis C virus by dibenzyl trisulfide from Petiveria Alliacea l (Guinea hen weed). British Microbiology Research Journal, 12(1), 16. doi: 10.9734/bmrj/2016/22120.

Lowe, H., Steele, B., Bryant, J., Fouad, E., Toyang, N., & Ngwa, W. (2021). Antiviral activity of Jamaican medicinal plants and isolated bioactive compounds. Molecules, 26(3), 607. doi: 10.3390/molecules26030607.

Luz, D. A., Pinheiro, A. M., Silva, M. L., Monteiro, M. C., Prediger, R. D., Ferraz Maia, C. S., & Fontes-Júnior, E. A. (2016). Ethnobotany, phytochemistry and neuropharmacological effects of Petiveria alliacea L. (phytolaccaceae): A review. Journal of Ethnopharmacology, 185, 182201. doi: 10.1016/j.jep.2016.02.053.

Marzo, R. R., Sami, W., Alam, M. Z., Acharya, S., Jermsittiparsert, K., Songwathana, K., …, & Yi, S. (2022). Hesitancy in COVID-19 vaccine uptake and its associated factors among the general adult population: A cross-sectional study in six southeast Asian countries. Tropical Medicine and Health, 50(1). doi:10.1186/s41182-021-00393-1.

Matias, T., Dominski, F. H., & Marks, D. F. (2020). Human needs in COVID-19 isolation. Journal of Health Psychology, 25(7), 871882. doi: 10.1177/1359105320925149.

Miami Times. (2020). Jamaican man beats covid-19 with his own remedy. The Miami Times. Available from: https://www.miamitimesonline.com/covid-19_hub/jamaican-man-beats-covid-19-with-his-own-remedy/article_842f0f14-8a26-11ea-acf6-6387d9bcf3f3.html (accessed 2 December 2021).

Miłek, M., Marcinčáková, D., & Legáth, J. (2019). Polyphenols con- tent, antioxidant activity, and cytotoxicity assessment of Taraxacum officinale extracts prepared through the Micelle-Mediated extraction method. Molecules, 24, 1025.

Ming, L., Li, Z., Li, X., Tang, L., & He, G. (2021). Antiviral activity of diallyl trisulfide against H9N2 avian influenza virus infection in vitro and in vivo. Virology Journal, 18(1). doi: 10.1186/s12985-021-01641-w.

Miraj, S., & Alesaeidi, S. (2016). A systematic review study of therapeutic effects of Matricaria recuitta chamomile (chamomile). Electronic Physician, 8(9), 30243031. doi: 10.19082/3024.

Monzote, L., Scull, R., Cos, P., & Setzer, W. (2017). Essential oil from Piper aduncum: Chemical analysis, antimicrobial assessment, and literature review. Medicines, 4(3), 49.

Mphuthi, D. D., & Husaini, D. C. (2022). Traditional medicinal plants used by hypertensive patients in Belize: A qualitative evaluation of beliefs and practices. Bulletin of the National Research Centre, 46, 107. doi: 10.1186/s42269-022-00789-x.

Naseri, S., Darroudi, M., Aryan, E., Gholoobi, A., Rahimi, H. R., Ketabi, K., …, & Teimourpour, R. (2017). The antiviral effects of curcumin nanomicelles on the attachment and entry of hepatitis C virus. Iranian Journal of Virology, 2017, 11, 2935.

NationsNews (2020). Voodoo leaders concoct covid-19 ‘cure’. NationNews Barbados Nationnewscom. Available from: https://www.nationnews.com/2020/05/25/voodoo-leaders-concoct-covid-19-cure/ (accessed 29 November 2021).

Nordqvist, J. (2017). Eucalyptus: What are the health benefits?. Medical News Today: MediLexicon.Intl. Available from: https://www.medicalnewstoday.com/articles/266580.php

Ochieng, M. A., Ben Bakrim, W., Bitchagno, G. T., Mahmoud, M. F., & Sobeh, M. (2022). Syzygium jambos L. Alston: An insight into its phytochemistry, traditional uses, and pharmacological properties. Frontiers in Pharmacology, 13. doi: 10.3389/fphar.2022.786712.

Orisakwe, O. E., Orish, C. N., & Nwanaforo, E. O. (2020). Coronavirus disease (COVID-19) and Africa: Acclaimed home remedies. Scientific African, 10. doi: 10.1016/j.sciaf.2020.e00620.

Owoyele, B. V., Bakare, A. O., & Ologe, M. O. (2020). Bromelain: A review on its potential as a therapy for the management of covid-19. Nigerian Journal of Physiological Sciences: Official Publication of the Physiological Society of Nigeria, 35(1), 1019.

Parham, S., Kharazi, A. Z., Bakhsheshi-Rad, H. R., Nur, H., Ismail, A. F., Sharif, S., …, & Berto, F. (2020). Antioxidant, antimicrobial and antiviral properties of herbal materials. Antioxidants, 9(12), 1309. doi:10.3390/antiox9121309.

Paul, D. (2016). A review on biological activities of common mallow (Malva sylvestris L.). Innovare Journal of Life Sciences, 4(4), 15. Available from: https://innovareacademics.in/journals/index.php/ijls/article/view/14809

Radice, M., Pietrantoni, A., Guerrini, A., Tacchini, M., Sacchetti, G., Chiurato, M., …, & Venturi, G. (2018). Inhibitory effect of ocotea quixos (Lam.) kosterm. and piper aduncum L. essential oils from Ecuador on West Nile virus infection. Plant Biosystems - An International Journal Dealing with All Aspects of Plant Biology, 153(3), 344351. doi:10.1080/11263504.2018.1478902.

Rehecho, S., Hidalgo, O., García-Iñiguez de Cirano, M., Navarro, I., Astiasarán, I., Ansorena, D., …, & Calvo, M. I. (2011). Chemical composition, mineral content and antioxidant activity of Verbena officinalis L. LWT-Food Science and Technology, 44, 875882.

Rehman, R., Saif, S., Hanif, M. A., Riaz, M. (2019). Medicinal plants of South Asia. Elsevier, B.V. Amsterdam. (Chapter 23) - Garlic.

Rios, C. E., Abreu, A. G., Braga Filho, J. A., Nascimento, J. R., Guerra, R. N., Amaral, F. M., …, & Nascimento, F. R. (2017). Chenopodium ambrosioides L. improves phagocytic activity and decreases bacterial growth and the systemic inflammatory response in sepsis induced by cecal ligation and puncture. Frontiers in Microbiology, 8. doi: 10.3389/fmicb.2017.00148.

Rodríguez-Ramos, F., & Navarrete, A. (2009). Solving the confusion of gnaphaliin structure: gnaphaliin A and gnaphaliin B identified as active principles of Gnaphalium liebmannii with tracheal smooth muscle relaxant properties. Journal of Natural Products, 72(6), 10611064. doi: 10.1021/np800746j.

Rosmalena, R., Elya, B., Dewi, B. E., Fithriyah, F., Desti, H., Angelina, M., …, & Seto, D. (2019). The antiviral effect of Indonesian medicinal plant extracts against dengue virus in vitro and in silico. Pathogens (Basel, Switzerland), 8(2), 85. doi: 10.3390/pathogens8020085.

Rouf, R., Uddin, S. J., Sarker, D. K., Islam, M. T., Ali, E. S., Shilpi, J. A. …, & Sarker, S. D. (2020). Antiviral potential of garlic (Allium sativum) and its organosulfur compounds: A systematic update of pre-clinical and clinical data. Trends in Food Science and Technology, 104, 219234. doi: 10.1016/j.tifs.2020.08.006.

Salehi, B., Sharifi-Rad, J., Quispe, C., Llaique, H., Villalobos, M., Smeriglio, A., …, & Martins, N. (2019). Insights into eucalyptus genus chemical constituents, biological activities and health-promoting effects. Trends in Food Science and Technology, 91, 609624. doi: 10.1016/j.tifs.2019.08.003.

Sarkar, S. (2020). Some Amazon villagers eschew drugs for Covid-19, take ‘toothache plant’ herbal tea. Reuters. Available from: https://www.hindustantimes.com/world-news/some-amazon-villagers-eschew-drugs-for-covid-19-take-toothache-plant-herbal-tea/story-xBmfxlZwSjMSbxVErr3CPM.html

Schütz, K., Carle, R., & Schieber, A. (2006). Taraxacum--a review on its phytochemical and pharmacological profile. Journal of Ethnopharmacology, 107, 313323.

Sen, D., Bhaumik, S., Debnath, P., & Debnath, S. (2021). Potentiality of moringa oleifera against SARS-COV-2: Identified by a rational computer aided drug design method. Journal of Biomolecular Structure and Dynamics, 40(16), 75177534. doi:10.1080/07391102.2021.1898475.

Shao, J., Yin, Z., Wang, Y., Yang, Y., Tang, Q., Zhang, M., …, & Lu, J. (2020). Effects of different doses of eucalyptus oil from eucalyptus globulus labill on respiratory tract immunity and immune function in healthy rats. Frontiers in Pharmacology, 11. doi: 10.3389/fphar.2020.01287.

Sharma, S. (2020). Aspirin in honey, raw garlic: Dubious covid-19 ‘cures’ spread in Brazil. Hindustan Times. Available from: https://www.hindustantimes.com/health/aspirin-in-honey-raw-garlic-dubious-covid-19-cures-spread-in-brazil/story-Lp22EdLI1aLFNrowfEr4GL.html (accessed 22 November 2021).

Süntar, I. (2019). Importance of ethnopharmacological studies in drug discovery: Role of medicinal plants. Phytochemistry Reviews, 19, 1199. doi: 10.1007/s11101-019-09629-9.

Subbulakshmi, K., Satish, S., & Shabaraya, A. R. (2021). Rose Apple fruit: A pharmacological review. World Journal Pharmacy and Pharmaceutical Science, 10, 842849. doi: 10.20959/wjpps20214-18707.

Taher, M., Amri, M. S., Susanti, D., Abdul Kudos, M. B., Md Nor, N. F., & Syukri, Y. (2020). Medicinal uses, phytochemistry and pharmacological properties of Piper Aduncum L. Sains Malaysiana, 49(8), 18291851. doi: 10.17576/jsm-2020-4908-07.

Thomas - Gleaner, C. (2021). Let herbal medicine be an option for covid-19, say proponents. News | Jamaica Gleaner. Available from: https://jamaica-gleaner.com/article/news/20210825/let-herbal-medicine-be-option-covid-19-say-proponents (accessed 7 October 2021).

Tran, H. T., Gigl, M., Le, N. P., Dawid, C., & Lamy, E. (2021). In vitro effect of taraxacum officinale leaf aqueous extract on the interaction between ACE2 cell surface receptor and SARS-COV-2 spike protein D614 and four mutants. Pharmaceuticals, 14(10), 1055. doi: 10.3390/ph14101055.

United Nations. (2021). Promoting covid-19 vaccine uptake and addressing vaccine hesitancy in Barbados and the Eastern Caribbean in Barbados and the Eastern Caribbean, United Nations. Available from: https://easterncaribbean.un.org/index.php/en/159081-promoting-covid-19-vaccine-uptake-and-addressing-vaccine-hesitancy-barbados-and-eastern (accessed 22 April 2022).

Vimalanathan, S., & Hudson, J. (2014). Anti-influenza virus activity of essential oils and vapors. American Journal of Essential Oils and Natural Products, 2, 4753.

Wahyuni, T. S., Mahfud, H., Permatasari, A. A., Widyawaruyanti, A., & Fuad, A. (2019). Synergistic anti-hepatitis C virus activity of Ruta angustifolia extract with NS3 protein inhibitor. Journal of Basic and Clinical Physiology and Pharmacology, 30(6). doi: 10.1515/jbcpp-2019-0348.

Waibel, R., Achenbach, H., Torrenegra, R., Pedrozo, J., & Robles, J. (1992). Diterpenes from Gnaphalium pellitum and gnaphalium graveolens. Phytochemistry, 31(7), 24152418. doi: 10.1016/0031-9422(92)83289-b.

WHO. (2022). WHO coronavirus (COVID-19) dashboard. World Health Organization. Available from: https://covid19.who.int/ (accessed 20 November 2022).

Wu, Z., & McGoogan, J. M. (2020). Characteristics of and important lessons from the coronavirus disease 2019 (covid-19) outbreak in China. JAMA, 323(13), 1239. doi: 10.1001/jama.2020.2648.

Wu, Y.-H., Tseng, C.-K., Wu, H.-C., Wei, C.-K., Lin, C.-K., Chen, I.-S., …, & Lee, J.-C. (2019). Avocado (Persea americana) fruit extract (2R,4R)-1,2,4-trihydroxyheptadec-16-yne inhibits dengue virus replication via upregulation of NF-ΚB–dependent induction of antiviral interferon responses. Scientific Reports, 9(1). doi: 10.1038/s41598-018-36714-4.

Zeng, W. C., Zhu, R. X., Jia, L. R., Gao, H., Zheng, Y., & Sun, Q. (2011). Chemical composition, antimicrobial and antioxidant activities of essential oil from Gnaphlium affine. Food and Chemical Toxicology: An International Journal Published for the British Industrial Biological Research Association, 49(6), 13221328. doi: 10.1016/j.fct.2011.03.014.

Acknowledgements

Ethics approval: Not applicable.

Funding: This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Authors contribution: DCH: Conception, database search, result synthesis, drafting the work, critical and final revision. OEO: Conception, supervising, drafting the work, critical and final revision. DDM: Conception, drafting the work, critical and final revision. SMG: Database search, result synthesis, drafting the work, critical and final revision. CNO: Drafting the work, critical and final revision. IEN: Drafting the work, critical and final revision. All authors approved of the version to be published.

Competing interest: Authors declare no competing interest.

Corresponding author

Danladi Chiroma Husaini can be contacted at: danhusaini@yahoo.com

Related articles