Next Article in Journal
Poly(ε-caprolactone)-Based Graft Copolymers: Synthesis Methods and Applications in the Biomedical Field: A Review
Next Article in Special Issue
Phenolic Profile, EPR Determination, and Antiproliferative Activity against Human Cancer Cell Lines of Anthyllis vulneraria Extracts
Previous Article in Journal
Diffuse Reflectance Spectroscopy for Black Carbon Screening of Agricultural Soils under Industrial Anthropopressure
Previous Article in Special Issue
Anxiolytic-like Effect of Quercetin Possibly through GABA Receptor Interaction Pathway: In Vivo and In Silico Studies
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Molecules
Volume 27
Issue 21
10.3390/molecules27217340
molecules-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

Bioactive Compounds, Pharmacological Actions, and Pharmacokinetics of Genus Acacia

by
Gaber El-Saber Batiha
1,*,†,
Nosheen Akhtar
2,*,†,
Abdulrahman A. Alsayegh
3,
Wafaa Fouzi Abusudah
4,
Najlaa Hamed Almohmadi
4,
Hazem M. Shaheen
1,
Thakur Gurjeet Singh
5 and
Michel De Waard
6,7,8
1
Department of Pharmacology and Therapeutics, Faculty of Veterinary Medicine, Damanhour University, Damanhour 22511, Egypt
2
Department of Biological Sciences, National University of Medical Sciences, Islamabad 46000, Pakistan
3
Clinical Nutrition Department, Applied Medical Sciences College, Jazan University, Jazan 82817, Saudi Arabia
4
Clinical Nutrition Department, College of Applied Medical Sciences, Umm Al-Qura University, Makkah 24381, Saudi Arabia
5
Chitkara College of Pharmacy, Chitkara University, Punjab 140401, India
6
Smartox Biotechnology, 6 rue des Platanes, 38120 Saint-Egrève, France
7
L’institut du Thorax, INSERM, CNRS, Université de Nantes, 44007 Nantes, France
8
LabEx «Ion Channels, Science & Therapeutics», Université de Nice Sophia-Antipolis, 06560 Valbonne, France
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Molecules 2022, 27(21), 7340; https://doi.org/10.3390/molecules27217340
Submission received: 19 August 2022 / Revised: 18 October 2022 / Accepted: 19 October 2022 / Published: 28 October 2022
(This article belongs to the Special Issue Advances on Natural Products: Isolation, Identification and Biological Activity)
Versions Notes

Abstract

:
Plants are a promising source of bioactive compounds that can be used to tackle many emerging diseases both infectious and non-infectious. Among different plants, Acacia is a very large genus and exhibits a diverse array of bioactive agents with remarkable pharmacological properties against different diseases. Acacia, a herb found all over the world, contains approximately more than 1200 species of the Fabaceae family. In the present review, we have collected detailed information on biochemical as well as pharmacological properties. The data were retrieved using different databases, such as Elsevier, PubMed, Science Direct, Google Scholar, and Scopus, and an extensive literature survey was carried out. Studies have shown that Acacia possesses several secondary metabolites, including amines, cyanogenic glycosides, flavonoids, alkaloids, seed oils, cyclitols, fluoroacetate, gums, non-protein amino acids, diterpenes, fatty acids, terpenes, hydrolyzable tannins, and condensed tannins. These compounds exhibit a wide range of pharmaceutical applications such as anti-inflammatory, antioxidant, antidiarrheal, antidiabetic, anticancer, antiviral, liver protective effects, and so on. Thus, the literature shows the tremendous phytochemical impact of the genus Acacia in medicine. Overall, we recommend that more research should be conducted on the medicinal value and isolation and purification of the effective therapeutic agents from Acacia species for the treatment of various ailments.

1. Introduction

With more than 1200 species, the genus Acacia is the second largest in the Leguminosae (Fabaceae) family. The genus is distributed throughout warm tropical and temperate regions of the world, with the greatest number of species (about 957) in Australia and a significant number (around 185) in America, Africa (144 species), and Asia (89 species). [1]. Many pharmacological molecules have been isolated from diverse species of Acacia. The root, leaves, pods, and bark of Acacia hold the uppermost quantity of tannin and phenolic compounds, such as gallic acid, dicatechin, quercetin, robidandiol, β-amyrin, hentriacontane, betulin, sitosterol, kaempferol-3 chlorogenic acid, and glucoside isoquercetin [2]. A. nilotica (L.) Willd. Ex Del., which is recognized as a medicinal tree, belongs to the family Mimosaceae and has been identified as being abundant in phenolic substances involving gallic acid, condensed tannin, and also phlobatannin, epigallocatechin-7-gallate, and (+)-catechin, and has been used for the treatment of amoeboid dysentery, viral-induced colds, bronchitis, bacterial-induced diarrhea, bleeding piles leukoderma, and fungal diseases [3]. The flowers and leaves of this perennial tree are also used as animal fodder. It has been shown previously in the Genetic Toxicology Laboratory that A. nilotica plants had cytotoxic and antimutagenic activities [4]. Acacia extracts were documented for their cytotoxicity effects, antioxidant activities [5], and antimalarial effects [6]. In another study, isorhamnetin 3-o-neohesperidoside was identified from the leaves of A. laeta and was reported to protect the cells against oxidative stress through the inhibition of the enzyme xanthine oxidase. Moreover, it is documented to scavenge a superoxide anion with an inhibition capability against Staphylococcus aureus, Klebsiella pneumonia, Klebsiella oxytoca, and strains [7]. Similarly, the number of other secondary bioactive metabolites identified from several Acacia species has been reported for their pharmacological potential [8]. Our aim is to provide a comprehensive review of the chemical components and pharmaceutical aspects of medicinally active Acacia species. Table 1 summarizes the significant activities of different species of Acacia. We have used different databases, including Science Direct (http://www.sciencedirect.com, accessed on 30 May 2022), PubMed (http://www.ncbi.nlm.nih.gov/pubmed, accessed on 25 May 2022)), and Google Scholar (http://scholar.google.com, accessed on 30 May 2022)).

2. Chemical Components Isolated from Acacia

Acacia is a varied genus including a variety of bioactive components such as alkaloids [33], flavonoids [8], terpenoids [34], phenolic compounds, and tannins [35,36], which are accountable for various pharmacological and biological properties such as antibacterial, anti-inflammatory, antihypertensive, antiplatelet, hypoglycaemic, anti-atherosclerotic, analgesic, and anticancer, owing to their higher free radical scavenging and antioxidant properties [37]. The phytochemical analysis of the A. nilotica leaf extracts revealed that it contains volatile oil, saponins, hydrolysable tannin, flavonoids, tannins, triterpenoid, phenol, alkaloids which are actual important compounds when regarding the pharmacologically bioactive phytochemicals in the plant [38]. Members inside the genus A. sensu lato were documented to enclose cyclitols, cyanogenic glycosides, amines, essential oils, diterpenes, simple alkaloids, fatty acids of the fluoroacetate, seed oils, triterpenes, amino acids, saponins, phytosterols, gums, flavonoids, and hydrolyzable reduced tannins as well. Deboshree Biswas and M.G Roymon reported that the bioactive principles found in methanolic bark and leaf extracts of A. arabica were investigated using an HPLC/MS/MS. Oleic acid (C18H34O2), Ferulic acid (C10H10O4), Myristic acid (C14H28O2), Palmitic acid (C16H32O2), Quercetine 3-O- (4′-O-acetyl)-rhamnopyranoside (C28H30O16), p-Coumaroyl-glucoside (C15H19O7), p-Coumaroylquinic acid (C16H18O8), and Steroidal sapogenin were the most common chemicals found in leaf and bark extracts. Caffeic acid phenethyl ester (CAPE) (C17H16O4), Methyl 3,4,5 tri hydroxyl benzoate, and Epi catecine-3-gallate (C22H18O10), were also found in the leaf extracts (C8H8O5). 3,4,5-trihydroxybenzoate was one component isolated from a bark extract (C7H6O5). Overall, this genus (and other mimosoid legumes) looks to be deficient in acetylenes, coumarins, phenylpropanoids, anthraquinones, naphthoquinones, lignans, glucosinolates, stilbenes, and uncommon fatty acids. However, only a small number of species have been specifically examined for these substances; thus, undoubtedly, the phytochemicals of only a small portion of Acacia species have been examined yet. Various phytocompounds from different Acacia species are shown in Table 1.

2.1. Alkaloids and Amines

In most of the taxa comprising the genus A. sensu lato, both relatively simple alkaloids and amines are present. They are particularly plentiful in the seeds from the subgenus Aculeiferumsection monacanthea of the Neotropical species, and also the species of Africa, including A. kraussiana, A. schweinfurthii, A. caesia, A. brevispica, and A. pentagona. Moreover, many of the non-protein amino acids that are present in other plants are missing and habitually have N-methyltyramine [39]. Amines are also found in the vegetative parts of these plants in a majority [39]. Once sheep eat the fodder of the species of subgenus guajillo, Aculeiferumis A. berlandieri, from North America over prolonged periods, N-methyl-β-phenethylamine (PEA) produces hind-limb ataxia [40]; this compound may also decrease the fertility of male Angora goats [33]. N-Methyl-β-PEA (1) co-exist with β-PEA, N-methyltyramine in the vegetative material of guajillo [40], and three additional amines (hordenine, tyramine, and N-methyltyramine) [33]. Nonetheless, additional sensitive investigation using GC/MS showed the existence of minor quantities of almost 33 other alkaloids and amines, including mescaline, methylamphetamine, amphetamine, mimosine methyl esters, isoquinoline alkaloids, nicotine, and nornicotine [33]. A. roemeriana and A. greggii have both been shown to contain N-Methyl—PEA; however, it is not limited to that subgenus. This component also occurs in A. angustissima of series Filicinae, A. rigidula, A. constricta, and A. schottii. Tyramine is established in A. angustissima, A. roemeriana, and A. greggii [40]. Β-PEA and the associated amines have been correspondingly described in certain Australian species of subgenus Phyllodineae involving A. cultriformis, A. hakeoides, A. harpophylla, A. floribunda, A. kettlewelliae, A. adunca, A. linifolia, A. lunata, A. podalyriaefolia, A. longifolia, A. pravissima, A. suaveolens, and A. prominens [41]. N-methyltryptamine likewise N, N-Dimethyltryptamine, and other N-methylated tryptamines are present in A. maidenii, A. simplicifolia, and A. phlebophylla bark [42]. Inside the root bark of A. spirorbis and leaves of A. harpophylla, hordenine exists, while N-α-cinnamoylhistamine is present in A. polystacha, A. argentea, leaves, and A. spirorbis fresh fruit bark [41].

2.2. Cyanogenic Glycosides

Several Acacia species possess substances of cyanogenic glycoside nature and are able to deliver hydrogen cyanide once the plant tissue is attacked. For this to happen, the β-glycosidases and the glycosides must be together. Of the identified cyanogenic species, plants have been defined as either devoid of both the enzyme and the substrate, possessing both of them, or having either one of them. Animals may be poisoned by the latter variety. Cyanogens have been discovered in Acacia plants in over 70 species [43], including 45 of the subgenus Phyllodineae and 25 of the subgenus Acacia. A small number of taxa in the subgenus Aculeiferum have been shown to contain cyanide. Cyanogens of the Acacia subgenus are a group of aliphatic components originated from leucine, isoleucine, valine, and, in particular, linamarin, proacipetalin, lotaustralin, epiproacipetaline, proacaciberin, heterodendrin, and 3-hydroxyheterodendrin [44]. Australian species (Almost 96%) in the subgenus Phyllodineae have been explored in a survey. The results showed that 45 species were found to be positive for cyanogenicity, and most of them lie in the Juliflorae group [45]. In these, the cyanogenic glycosides include prunasin (6) and sambunigrin (7). However, two species, i.e., A. pulchella var. reflexa and A. exilis, of the Phyllodineae subgenus have been shown to contain heterodendrin, an aliphatic cyanogen [46]. Generally speaking, cyanogenic species in the Phyllodineae subgenus lack the enzymes required to hydrolyze the compounds rapidly. Though the cyanogenic species of Acacia are widely distributed in Australia, few reports of poisoning livestock attributed to Acacia species exist [45]. The African species A. hereroensis and A. caffra of the subgenus Aculeiferum also encompasses the aromatic cyanogens, sambunigrin, cyanogens, and prunasin. In addition, herbarium specimens of A. welwitschia, A. klugii, and A. chariessa were weakly positive for the release of hydrogen cyanide following the Feigl–Anger test.

2.3. Hydrocarbons

To date, 13 hydrocarbons (111123), mostly isolated from A. modesta and A. nilotica species, have been reported in the genus Acacia. The presence of various compounds in the chloroform extract of A. nilotica leaves was revealed by mass spectroscopy and gas chromatography analysis, such as palmitic acid, linolenic acid, lariciresinol, myristic acid, stearic acid, 2-methylresorcinol acetate, 1,3,4 eugenol, megastigmatrienone, neophytadiene, δ-5-avenasterol,3,4,7-trimethylquercetin, and arachidonic acid [47]. In addition, a benzene extract of the stem bark of A. modesta contains betulin, α-amyrin, γ–sitosterol, and octacosanol. The plant’s heartwood extracts in pet. ether (60–80°) and alcoholic extracts yielded γ–sitosterol and pinitol, respectively. The extract of leaves in pet. ether (60–80°) yielded hentriacontane, octacosane, hentriacontanol, and octacosanol [48].

2.4. Fatty Acids

The seed oils derived from the separates of A. sensu lato vary slightly in their biochemical content. Linoleic (LA) and oleic (OL) acids prevail in the oil of seeds of many species, even though a few comprise moderately high proportions of linolenic acids. Most oils have stearic and palmitic acids in the residual portion, and most species possess 3–10% oil inside their seeds. The fatty acids of the seed oil from species of subgenus comprise: A. farnesiana (linolenic acid; 54%, LA; 43% and OL; 13%); A. caven (linoleic acid (LA): 54%); A. giraffae (oil; 3.5%, with stearic acid, palmitic acid, palmitoleic, and n (41.5%)) [8]; A. macrothyrsa (21% OL acid; 50% LA acid (LA)); A. lenticularis (80% linolenic acid); A. modesta (27% OL; 26% LA); A. leucophloea (32% OL; 38% LA); A. nilotica (29% OL acid; 44.5% LA); A. seyal (36% OL acid; 38% LA); A. planifrons (34% OL; 23% LA); A. sieberiana (31% OL; 44% LA); A. arabica (42% OL; 36% LA), and A. tortilis (19% OL, 72% linolenic acid, and 60% LA); [49]. The A. lenticularis, A. farnesiana, A. tortilis, and A. nilotica seeds possessed coronaric acid (cis-9,10-epoxyoctadec-cis-12-enoic) (9) [50]. A. giraffae contains stearic, palmitic, palmitoleic, OL, and arichidic acid (29%) in their seed pod oils [51]. The acids from the seed oils of subgenus Aculeiferum include: A. mellifera (22% LA; 42% OL acid); A. catechu (29% OL; 41% LA) [52]; A. polyacantha (26% OL acid, 41% LA); A. senegal (10% OL acid, 43% LA, and 36% stearic acid); A. suma (77% linolenic acid); and A. sinuata (30% OL; 36.8% LA), A. schweinfurthii (23% OL acid, 36% LA). Coronaric acid (9) is present in A. pennata seeds, while vernolic acid (cis-12,13-epoxyoctadec-cis-9-enoic) (10) is found in the seeds of A. mellifera, A. catechu, and A. sinuata [49]. The seed oil of A. willardiana has 18% OL acid and 37% LA [53]. Aboriginal people used the seeds of Australian wattle species (subgenus Phyllodineae) as sources of oils and protein [54]. Those vital for these species for ‘bush tucker’ in Australia are A. murrayana and A. victoriae (20% protein, 18% saturated fatty acids, 18% OL, 5% oil, and 62% LA) [49]. From the 20 other species of this subgenus, Aboriginal people use the oil content of18, enclosed from triglycerides (3 to 22%) in which either OL or LA preponderates [49]. The composition of oil from other members of subgenus Phyllodineae is A. dealbata (10% oil with 31% OL and 40% LA), A. auriculiformis (10% OL and 67% LA), A. mearnsii (8% oil with 17% OL and 68% LA), and A. decurrens (8%) [55]. The seed oil from A. cyclops (dry material (10%) of the seeds) was extremely unsaturated, while the funicle oil (40.6%) involved ordinarily saturated fatty acids [56]. Coronaric acid (9) is a part of A. cochlearis seeds, while A. auriculiformis contains vernolic acid (10) [55]. The Faidherbia albida seed oils remained comparable to those of common Acacia species. They comprised 23% OL acids and 51% LA, and coronaric acid (9) is also present in the seeds of this species [55].

2.5. Gums

Gum arabic, also known as gum Acacia, is seen as the main exudate extracted, with desired properties, generally from a particular African species, such as A. senegal (Aculeiferum). This gum is produced artificially in Sudan by injuring trees and gathering gum tears [56]. Approximately 250 g/tree/year is the average yield, and the whole annual production is close to 60,000 tons [57]. This component is hydro-soluble up to 50% by weight, resulting in a transparent mucilaginous solution with a low viscosity. Gums are produced in response to injury, stress, bacteria, insects, or fungal attacks on the plant as dispersible complex carbohydrates. [58]. Gums are usually released from damaged sites into fissures and fractures in the bark or appear as uneven masses or “tears” on the surface of branches or trunks. Even though the configurations of naturally occurring vegetal gums differ widely, several containing gum arabic have backbones of d-galactopyranose units linked 1 → 3, and many contain four sugars: l-rhamnose, d-glucuronic acid and l-arabinose, and d-galactose. They comprise the cations Mg2+, Ca2+, and K+ [56]. Gums exhibiting subgenus Acacia comprise A. arabica, A. nebrownii, A. adansonii, A. calcigera, A. giraffae, A. drepanolobium, A. nubica, A. chundra, A. farnesiana, A. ehrenbergiana, A. gerrardii, A. hebeclada, A. heteracantha, A. hockii, A. kirkii, A. leucophloea, A. nilotica, A. karoo, A. rigidula, A. reficiens, A. sieberiana, A. seyal, A. xanthophloea, and A. tortilis [59]. Subgenus Aculeiferum comprise: A. catechu, A. cheiranthifolia, A. goetziisubsp.goetzii, A. berlandieri, A. campylacantha, A. erubescens, A. fleckii, A. leucospira, A. laeta, A. Senegal, and A. mellifera [60]. Several species of Acacia subgenus Phyllodineae are able to produce large amounts of gums [61]. Amongst the species formerly used as commercial gums, Australian black wattle (A. dealbata, A. decurrens, A. pycnantha, A. homalophylla, or A. sentis,) belong, and the gum of an unnamed wattle species too [62]. In the early 1900s, A. rivalis gum provided the foundation for a commercial gum manufacturing industry in South Australia [63]. Nevertheless, a large number of these Australian commercial gums are known to have poor quality; strong in taste, were dark reddish brown vis à vis the color was more likely to alter in gels than in mucilage with water. Gums grown east of the Great Dividing Range are mostly not soluble in water; however, the ones with dry inner are likely to be more water-soluble [64]. In other new investigations, the chemical and physical characteristics of many wattle gums have been studied [59]. Though the initial investigations showed that gums from the species of the Phyllodineae subgenus were described with a low rhamnose percentage, low acidity, high galactose/arabinose ratio, and low intrinsic viscosity, advanced studies have shown much more dissimilarity in several parameters than those firstly observed [59]. The characteristics of common gums from the Acacia species are shown in Table 2.

2.6. Non-Protein Amino Acids

Non-proteinous amino acids are usually found in leaves and seeds throughout the species of the subfamily Mimosoideae [74]. Nearly 100 Acacia species have been investigated, and the majority of them had non-protein amino acids. [39]. These components can be hazardous to non-adapted animals as well as humans who consume them. N-acetyldjenkolic acid (11) is consistently present in members of subgenus Acacia. It was first isolated in A farnesiana [75]. Utmost enclosed α-amino-β-oxalylaminopropionic acid (12) (a neurolathyrogen) and free α,β-diaminopropionic acid [39]. N-4-oxalyl-2,4-diaminobutyric acid (13), 2,4-diaminobutyric acid, and 2-amino-6-N-oxalylureidopropionic acid (oxalylalbizziine) (14) are also present in the seeds of these species [76]. Several possess 2,4-cis-4,5-trans-dihydroxypipecolic acid (15). Nonetheless, most of the amino acids stated above are missing Neotropical species seeds of the subgenus Aculeiferum Monacanthea, and in African species A. caesia, A. brevispica, A. kraussiana, A. schweinfurthii, and A. pentagona. However, they have amines such as N-methyltyramine [39]. Despite the fact that A. coulteri seeds include all of the characteristics of the subgenus Aculeiferum sensu stricto, this species belongs to a group that has been proven to be distinct from other members of this subgenus using molecular techniques [77]. A. coulteri do not have N-acetyldjenkolic acid in their seeds. The seeds of A. millefolia and A. willardiana, species related to A. coulteri, enclose S-[β-carboxyisopropyl]-l-cysteine and willardiine (16) (17) [78]. Willardiine is rarely present in additional mimosoid legumes [78]. The seeds of A. angustissima (may be A boliviana, series Filicinae) cover the non-protein amino acids 2,4-diaminobutyric acid, 2-amino-4-acetylaminobutyric acid, and 2-amino-6N-oxalylureidopropionic acid (oxalylalbizziine) (14) [76]. Inside the seeds of A.lemmonii (a segregate of A. angustissima) willardiine is also found (16) [78]. This series’ amino acid pattern is distinct from that of the other A. sensu lato groups [76]. The combination of S-carboxyethylcysteine, S-[-carboxyisopropyl]-l-cysteine (17), albizziine (18), and amino-acetylaminopropionic acid (19) are found in over 60 species of the Phyllodineae subgenus.) [39]. Pipecolic acid (20), as well as hydroxypipecolic acid (21), are present in the leaves of A. mearnsii (as considerably as 1% dry weight) [79]. Hydroxypipecolic acid (21) is also present in the heartwood of A. maidenii [80]. Furthermore, the non-protein amino acid content of F. albida seeds, traditionally thought to belong to the Acacia genus, is comparable to that of subgenus Aculeiferum sensu stricto. The essential oils obtained from the A. farnesiana flowers (sweet Acacia or cassie ancienne) have been extensively used in the production of perfumes [81]. This species is cultivated in several tropical and subtropical countries for this reason and represents a significant harvest in southern France [82]. The volatile compounds were formerly isolated through enfleurage, which is the solvent extraction commonly applied [82]. Three compounds, trans-3-methyldec-4-enoic acid, cis-3-methyldec-3- en-1-oic acid, and cis-3-methyldec-3-en-1-ol, play a striking role in the aroma of cassie oil [81]. Cassie blossom, absolute of A. farnesiana flowers, encloses geranial (2.8%), methyl salicylate (47.5%), geraniol (9.8%), anisaldehyde (17.3%), geranyl acetate (3.3%), α-ionone (0.4%), 3-methyldec-3-en-1-ol (1.9%), benzaldehyde (6%), 3-methyldec-4-en-1-ol (0.5%), (β-ionone (0.7%), Z)-3-nonen-1-ol (0.7%), myrcene (0.5%), linalool (0.4%), and a quantity of other compounds [83]. A. caven flowers are also utilized in fragrances. However, the fragrance is appraised to be less desirable compared to A. farnesiana [84]. The composition of essential oils derived from the flowers of A. rigidula (subgenus Acacia) as well as A. berlandieri (subgenus Aculeiferum) was studied too. The major components from the essential oil identified in A. rigidula were: jasmone, cis3-hexenyl benzoate, p-anisaldehyde, citronellyl acetate, methyl 2,6-dihydroxybenzoate, and kaur-16-ene. Those identified in A. berlandieri were: 1-octanol, benzyl benzoate, linalool oxide B, and eugenol [83]. The essential oils of A. floribunda (subgenus Phyllodineae) and A. dealbata were removed using petroleum ether to yield concrete [84].

2.7. Terpenoids

Two types of cassane diterpenes (22;23) were identified in the A. jaquemontii roots [85]. The exudates and resinous leaves of A. rossei (subgenus Phyllodineae) in Western Australia have been shown to contain labdane diterpenes (24;25) [86]. The pods of A. sinuata (syn. A. concinna) (subgenus Aculeiferum) have been found to contain acacic acid lactone, machaerinic acid, and sapogenin B. Acacidiol, a nortriterpene, was also documented from the same source [87]. This was a novel 21-hydroxy ester molecule derived from monoterpenes. Furthermore, saponins were identified from this specie as well [87]. A genin, a triterpene ester, acacigenin B (29), was previously isolated from the same source [87]. The phytosterols -spinasterol (30) and stigmast-7-enol have been identified in a variety of Phyllodineae species, including A. auriculiformis, A. meansii, A. maidenii, A. melanoxylon, A. sparsiflora, and A. obtusifolia [88]. A phytosterol, α-spinasterol (30), and a triterpenoid trisaccharide, Acaciaside (31), have been described from A. auriculiformis [88]. Three triterpene glycosides were extracted from the leaves of A. myrtifolia: myrtifoliosides A, B, and C [89]. Many saponic (triterpene) glycosides derived from A. victoriae have recently been studied for their ability to induce apoptosis and reduce tumor cell growth [90]. The compounds termed Avicins (for example, Compound 34, avicin D) inhibit tumor cell growth by disrupting mitochondrial activity [90]. In both entire carcinogenesis and initiation/promotion model systems, these drugs reduced papilloma formation in mice by 70% [91].

2.8. Flavonoids

Numerous flavone glycosides and flavonol, flavan-3, 4-diols, flavan-3-ols andaglycones, are present in the heartwood, leaves, and bark of Acacia species. In these flavonoids, the 5-hydroxy group is usually absent, which identifies the Fabaceae family. Commonly, the barks have considerable complex flavonoid mixes compared to the heartwoods [92]. The flavonoid content of the heartwoods and barks of the 61 native Australian Acacia species were examined by paper chromatography and broadly divided into four groups based on the variations in the phenolic hydroxyl pattern (3′,4′,7-trihydroxy; 4′,7-dihydroxy; 3′,4′,7,8-tetrahydroxy, or 4′,7,8-trihydroxy) [92]. The red-brown heartwood of A. giraffae holds (+)-mollisacacidin [(+)-7, 3, 4-trihydroxy-2, 3-trans-3, 4-trans-diol or earlier (+)-leucofisetinidin], which is connected to proanthocyanidins (PACs) [93]. Additionally, from this specie, an array of isomeric mollisacacidin byproducts have been described [94]. The heartwoods of A. nilotica subsp. kraussiana and A. karroo, both African species of this subgenus, contain a 7,3,4-substitution pattern. A. luederitzii vars. luederitzii and A. reficiens subsp. reficiens, and retinens have both 7,4-substitution and 7,3,4 pattern [95]. The flavonoids were extracted from the heartwoods of the subgenus Aculeiferum, e.g., A. nigrescens, rostrata, and A. senegal vars. Leiorachis exhibit a 7,8,34-substitution, while those of A. galpinii, A. burkei, and A. erubescens have a a 7,8,4-substitution pattern, and those in A. welwitschii have a pattern of 7,3,4 [95]. The Indian species of wood, A. catechu, encloses flavonoids with 5,7,3,4-hydroxylation, epicatechin, and catechin [80]. A 7,3,4-trihydroxyflavan-3,4-diol and many additional components with the above-mentioned pattern of substitution have been identified in the A. angustissima (Acacia series Filicinae) leaves [96]. The members of the Phyllodineae subgenus have a wide range of flavonoid types in their bark and leaves. The flavan-3-ols (+)-catechin (45) and (+)-gallocatechin (47) are common in the woods and barks of 61 Australian species of the subgenus Phyllodineae, but (-)-epicatechin (46) and (-)-epigallocatechin (47) are not common and often only occur in little quantities. The (+)-epicatechin and (+)-epigallocatechin gallate esters are uncommon, but they are abundant in some species. [92]. Flavonoids containing 7-hydroxy A-ring substituents are found in the Brunioideae, Uninerves sect. Racemosae, and Botryocephalae families of flavonoids. 3-Methoxyflavones are common in Australian heartwood. [80]. 8-O-methylflavan-3, 4-diols are found in A. saxatilis and A. cultriformis, while 3-O-methylflavan-3, 4-diols are found in A. saxatilis and A. mearnsii [80]. These components have been recognized since they are involved in a number of other members of Australian species [95].

2.9. Tannins

Some Acacia species, including those in the subgenera of Aculeiferum and Acacia, as well as those in the series Filicinae and other mimosoid legumes, contain hydrolyzable tannins [44]. Using the potassium iodate method for gallotannins, the leaves of various species and, to a lesser extent, their bark were found to contain between 1 and 8% hydrolyzable tannins [35]. The chemical 1,3-di-O-galloyl-4,6-hexahydroxydiphenoyl-glucopyranose has been found in the leaves of A. raddiana [97].
Condensed tannins, also referred to as proanthocyanidins (PACs), are the most noticeable secondary metabolites in the majority of Acacia species. Tannins are a vital part of various foods and provide great benefits in animal diets. The number of condensed tannins in the bark and leaves of American Acacia subgroups (subgenera Acacia and Aculeiferum sensu stricto, the series of Filicinae, and the species associated with A. coulteri) typically range from 1 to 8% (rare samples have reached 20%); typically, the wood samples have 1% or fewer tannins [35]. Mimosa (Acacia mearnsii) bark extracts are the major industrial sources of PACs [98,99]. PACs with 7,3,4- and 5,7,3,4-phenolic substitution configurations are found in the African species red-brown dark heartwood, i.e., A. giraffae of the Acacia subgenus. The above-mentioned PACs habitually have a (4β → 8)-linkage with a (+)-catechin unit. A. luederitzii also contains this type of tannin, but the species is dominated by (+)-guibourtinidol-(46)-(+) fisetinidol (55), (+)-guibourtinidol-(46)-, and (+)-(46)-epifisetinidols [100]. This source’s compounds usually have a 5-oxygenated ‘lower’ flavan-3-ol unit, such as (+)-catechin (45), (+)-epicatechin (46), or (+)-afzelechin (47). The bark of many Kenyan Acacia species has a moderately higher content of tannin: A. mearnsii (28.8%) (Subgenus Phyllodineae), A. Senegal (25.1%) (Subgenus Aculeiferum), A. hockii (24.1%), A. mellifera 19.3%, A. kirkii (16.1%), A. nilotica ssp. indica (11.6%), A. xanthophloea (17.0%) (subgenus Acacia), A. nilotica ssp. subulata (13.1%), A. seyal var. fistula (13.3%), 9.3% in A. polyacantha ssp. Campylacantha, and A. sieberiana, 4.7% [101]. In the heartwood of A. luederitzii, (46)- and (48)-Proguibourtinidin carboxylic acids (3,7,4-trihydroxy functionality) of 2,3-trans-3,4-trans-2,3-cis and 2,3-trans-3,4-trans-2,3-trans-configuration (such as 56), epicatechin or (+)-catechin as constituent units, and their related dimeric homologs, exist [102]. Certain condensed tannins from the Acacia subgenus Aculeiferum species were also investigated. Gallocatechin-(4 → 8)-epicatechin is present in A. suma bark [103]. Meanwhile, A. galpinii’s dark-brown heartwood is nearly tannin-free and contains teracacidins, a whole range of 7,8,4-trisubstituted flavonoids and melacacidin (7,8,3,4-tetrahydroxyflavan-3,4-diol), which is in common with many Australian species [93]. Several similar agents exist in the closely associated species of A. burkei [93]. The wood of A. galpinii contains -2,3-cis-3,4-trans-, -2,3-trans-3,4-cis-, and -2,3-trans-3,4-cis-Teracacidin, which are associated with melacacidin [-7,8,3,4-tetrahydroxy-2,3-cis-flavan-3,4-cis-dio. Remarkably, no tannins, except for proteracacinidin-type oligomers, exist in this species [93]. Their synthesis might result from the monomeric flavan-3,4-diol precursors’ pyrogallol A-ring losing its nucleophilicity, allowing alternate centers to take part in the formation of the interflavanyl bonding process [104]. These agents are complemented by flavonol, dihydroflavonol, flavanone, proteracacinidin dimers, and chalcone analogs [105]. Profisetinidins having a 2,3-cis comparative structure are uncommon and limited to certain proteracacididins from A. caffra and A. galpinii and a promelacacinidin from A. melanoxylon (subgenus Phyllodineae) [104]. A. mearnsii, (earlier known as A. mollissima or A. decurrens var. mollis), was previously the source of prosperous industries in Australia [106]. Nowadays, A. mearnsii represents the base of the industrial production of tannin p in Brazil and South Africa. Often 20–40% tannins occur in the bark of this specie, and the bark extracts contain approximately 70% PACs (up to 3000 MW) [107]. Because of its importance, extensive r investigations have been undertaken for the tannins of this species compared to others. The PACs contain essentially bi-, tri-, and tetrameric profisetinidins [fisetinidol- (4 → 8)- and -(4 → 6)-catechin profisetinidins], and an equivalent sequence of prorobinetinidins [107]. With 3,4,7-trihydroxyflavan-3-ol extender components, these profisetinidins are highly significant condensed tannins of trade, materializing the main elements of both quebracho (Schinopsis spp., Anacardiaceae) and wattle (A. mearnsii) tannins. The stereochemistry of naturally existing oligomers is usually 2,3-trans, with absolute configurations of 2S, 3R or 2R, 3S. Many other Australian wattle species have PACs with a (4β→8)-linkage and a (+)-catechin terminal unit. [93]. The PAC dimers are recurrent in Australian species with 7,3,4-trihydroxy subunits [(+)-mollisacacidin group]. Tannins are infrequently found in species of the 7,8,4-trihydroxy [teracacidin group], whereas tannins associated with the 7,8,3,4-tetrahydroxyflavonoids appear to form as oxidation products after isolation.

3. Pharmacological Activities

Many studies on the pharmacological properties of Acacia species have been conducted as a result of their widespread use in disease care. Secondary metabolites from the Acacia species have a variety of biological actions, including antibacterial, antifungal, antioxidant, anticancer, antiparasitic, antidiabetic, immunomodulatory, and cytotoxic properties (Table 1).

3.1. Anti-Hypertensive and Anti-Spasmodic Activity

A methanol (MeOH) extract from A. nilotica pods inhibited the rate and force of spontaneous shrinkages in the atria of paired guinea pigs. The activity of the pod extract is thought to be promoted by the calcium channel barrier since it suppressed K-induced contractions in rabbits. The extract’s potential was investigated using phentolamine and atropine. Although phentolamine inhibited nor-vasoconstrictor epinephrine’s action, the pretreatment of the extract with animal models had no influence on the NE effect, ruling out the role of adrenoceptor blocking. [9]. A methanol extract from the bark of Acacia leucophloea was investigated for potential spasmolytic effects on a rabbit jejunum preparation that spontaneously contracted due to its historical use as a gastrointestinal medication. The findings indicated that the spontaneous contractions were inhibited, pointing to a spasmolytic activity of Acacia leucophloea [108].

3.2. Anticancer and Anti-Mutagenic Properties

Plant-derived drugs have demonstrated the greatest impact in the antitumor field, with drugs such as vinblastine, vincristine, taxol, and camptothecin improving chemotherapy for some cancers [109]. A realistic and promising strategic approach to cancer prevention is the continuous search for new anticancer compounds in plant medicines and traditional foods [110]. Therefore, the quest for anticancer molecules in plant biodiversity continues, and Acacia species have not yet escaped this wave of research into natural anticancer molecules. A. modesta has a variety of pharmacological properties, including anticancer. In a study, the anticancer activity of the liver cancer cell line HepG2 was evaluated. In A. modesta plant extracts, HPLC analysis revealed the presence of phytochemicals, such as steroids, alkaloids, phenols, flavonoids, saponins, tannins, anthraquinone, and amino acids. The A. nilotica extract and its components exhibited antimutagenic/antiproliferative effects. The key agents are believed to be flowers and gums. In the investigation of [111], the anticancer potential of the gum (aqueous (Aq.) extract), leaves, and flowers were accessed on papillomagenesis, induced by 7,12-dimethylbenz(a) anthracene (DMBA). The total chromosomal was reduced in mice fed with an Aq. extract via oral gavage, in addition to the significant decrease in the occurrence of micronuclei to combat Dalton’s ascetic lymphoma (DAL); the mice models were pretreated with an A. nilotica extract with 10 mg/kg.b.w (14 successive days). The extract significantly reduced tumor expansion compared to the control group. The histopathological effects of the pre-treatment completed with the A. nilotica extract against acetaminophen-induced liver injury in rats showed that the injuries produced by acetaminophen were considerably reduced by owing to its ability to decrease the oxidative stress of acetaminophen-induced hepatocellular impairment [112]. The MeOH had a dose of 5 mg/plate, and the methanol extract from the bark reduced the UV-induced mutagenicity in E. coli WP-2. This decrease could be due to an enzymatic action that reversed pyrimidine dimmer synthesis. [113]. Furthermore, catechin-rich A. catechu extracts demonstrated anticancer activity against the human breast adenocarcinoma cell line (MCF-7) by inhibiting the expression of the transcription factors NF-B, p53, and AP-1, as well as nitric oxide levels [114]. The anticancer activities of A. catechu have already been well summarized previously [115]. Other species with anticancer properties are shown in Table 1.

3.3. Analgesic and Anti-Pyretic Activity

Several pathological diseases are triggered by inflammation and pain. The synthetic drugs used to treat these conditions have extremely toxic side effects. Global efforts are underway to introduce novel medicinal plants in order to develop effective, affordable, and safe drugs. Afsar and his colleagues investigated the anti-inflammatory, antipyretic, and analgesic activity of A. hydaspica methanol extract and its active fraction. The findings suggest that the existence of bioactive chemicals in A. hydaspica may be responsible for the pharmacological activities, validating the indigenous value of A. hydaspica towards inflammatory illnesses [12]. The analgesic effects of A. nilotica were evaluated in addition to the acetic-acid-mediated discomfort in rats (with 150 and 300 mg/kg b.w. as dose levels). The effective activity was displayed comparably to a standard drug, acetylsalicylate [116]. The hot-plate method was used to evaluate the analgesic effect compared to 1 mL of aspirin (100 mg/Kg) as a positive control. Organic acids, polysaccharides, and flavonoids were reported to be the inducers of the extract activity [117]. In an additional study, the analgesic and antipyretic effects were evaluated using brewer’s yeast (15%) with hot-plate methodology using Wistar Albino rats). The dose of the extract was 400 mg/kg b.w. and the results showed a reduction in the temperature of the rectum from 39.0070.25 °C to 37.7070.15 °C after administration (23 h) [118]. Furthermore, in another study, the analgesic, antipyretic activity, and anti-inflammatory potential of the methanolic extract obtained from A. cyanophylla were evaluated [119]. By using the hot-plate method, the analgesic activity showed a maximal activity of 36.98%, and similar patterns were seen for antipyretic activity.

3.4. Anti-Inflammatory

Many studies have proposed the anti-inflammatory activities of different species of Acacia. Eldeen and his coworkers [120] investigated the anti-inflammatory properties of acassane diterpene niloticane extracted from an ethyl acetate bark extract of Acacia nilotica subsp. Kraussiana. The results showed that in the cyclooxygenase test, niloticane possessed activity with IC50 values of 28 and 210 microM against COX-1 and COX-2, respectively. Moreover, the anti-inflammatory potential of using TPA-induced ear edema in mice was presented by the bioactive compounds obtained from aerial portions of Acacia nilotica [121]. The outcomes of the inhibitory activities of the pretreatment undertaken with A. nilotica extract (Aq.) on yeast-induced pyrexia and carrageenan-induced paw edema in rats (with a dosage of 100 mg/Kg b.w.) exhibited a reduction in the edema of the paw (20%), relatively less than that shown by 1 mL aq. aspirin solution (47%) [117]. Aq. pod extracts (50 and 100 mg/kg b.w.) were investigated in rats for carrageenan-induced edema, and the cotton pellet-induced granuloma models and the results showed a maximum inhibition of 64.41 percent and 25.62 percent, respectively [122]. Other groups of researchers investigated the anti-inflammatory properties of extracts from the heartwood of A. confuse. They found that A. confusa heartwood extracts or derived phytocompounds have a high potential for preventing diseases induced by the increased production of reactive oxygen species, including inflammatory diseases [13]. In an additional study, A. tortilis, an Algerian Sahara plant, was evaluated for its phenolic composition and biological activities. The biological activity of the A. tortilis extract was noteworthy, and the phenolic compounds discovered were proposed to be a useful starting point for the creation of cytotoxic and anti-inflammatory medicines [14]. Previous research has also shown that the pharmaceutical properties of A. hydaspica might be attributed to its indigenous value against inflammatory diseases [12]. The extracts of Acacia modesta also showed potent anti-inflammatory, antipyretic, analgesic, antidepressant, and anticoagulant activities, which conclude that the bark of A. modesta has significant therapeutic potential [123].

3.5. Anti-Microbial Activity

The species of Acacia have broad-spectrum antibacterial properties against a variety of diseases. A. ataxacantha is a pharmacological species widely used in the traditional medicine of the Benin Republic to treat infectious disorders. Three chemicals (13) were isolated and identified from the bark of A. ataxacantha using chromatographic and spectroscopic techniques. Three triterpenoids were isolated during a phytochemical analysis of A. ataxacantha (Fabaceae) (lupeol (1), betulinic acid (2), and betulinic acid-3-trans-caffeate (3). Compound 3 had a higher MIC value of 12.5 g/mL against Staphylococcus epidermidis and Candida albicans. The overall findings of this investigation showed that compound 3 isolated from A. ataxacantha has antimicrobial activity towards Gram-positive and Gram-negative bacteria and yeast, particularly Candida albicans [16]. A. plicosepalus yielded a novel flavanocoumarin, loranthin (1), as well as catechin (2), quercetin (3), rutin (4), gallic acid (5), and methyl gallate (6). Loranthin has the unusual flavanocoumarin skeleton, which connects the flavan and coumarin moieties via C-7/C-8 of both moieties. Loranthin’s antibacterial activity was tested against many pathogens, and it was found to have a substantial impact against Staphylococcus aureus [18]. The other Acacia, i.e., A. farnesiana, has been shown to exhibit antibacterial activity against Vibrio cholerae. By using nuclear magnetic resonance (NMR) methods ((1) H NMR and (13) C NMR), the active component was extracted from A. farnesiana and identified as methyl gallate. Methyl gallate degraded cell membrane integrity, resulting in a reduction in cytoplasmic pH (pHin, from 73 to 30) and membrane hyperpolarization, and the treated cells no longer generated ATP [19]. Cavazos and his coworkers evaluated the antibacterial and antioxidant activity of the extracts of A. berlandieri and A rigidula leaves (acetone, methanol, and acetic acid) [23]. A. rigidula leaf extracts exhibited antibacterial activity against Pseudomonas alcalifaciens, Pseudomonas aeruginosa, Y. enterocolitica, E. coli, S. aureus, and E. faecalis, while A. berlandieri displayed minimal inhibitory effects against P. alcalifaciens, P. aeruginosa, and Y. enterocolitica; thus, highlighting the significance of the species as a antimicrobial agent. The microbial inhibition of A. nilotica (leaf extract) on E. coli was proposed to be associated with the antibacterial activity, with a minimum inhibitory concentration of 70 mg/mL. This demonstrated the plant’s potential for treating Campylobacter-related microbial infections. [38]. The susceptibility of Campylobacter to the extract is of great interest seeing the common antibiotic resistance phenomena of the organism [38]. The aqueous extracts of A. catechu also exhibited an antimicrobial effect against Staphylococcus aureus, Pseudomonas aeruginosa, Proteus mirabilis, E coli, and Klebsiella pneumonia with a diameter of zone of inhibition (ZoI) of 17.66 ± 1.52, 16.66 ± 1.15, 14.0 ± 2.0, 8.33 ± 0.57, and 8.0 ± 0.0 mm, respectively [124]. Many other studies proposed the potent antimicrobial activity of A. catechu [125,126,127]. Thus, the data suggest that A. catechu, which is abundant in bioactive secondary metabolites, may be a promising source of compounds for the development of new antimicrobial drugs.

3.6. Antioxidant Activity

Acacia species contain a high concentration of polyphenolic chemicals, which have significant antioxidant capabilities and help to reduce the risk and treatment of oxidative stress-related disorders, such as cardiovascular, neurological, and cancer. Several publications have extensively studied the antioxidant activity of Acacia species in vitro, utilizing radicals such as 2,2-diphenyl-1-picrylhydrazyl (DPPH) and 2,2’-azino-bis[3-ethylbenzothiazoline-6-sulphonic acid] (ABTS) [128]. A. hydaspica is a natural shrub that has a variety of medicinal characteristics. Afsar et al. evaluated A. hydaspica polyphenol-rich ethyl acetate extract against cisplatin (CP)-induced lung-damaged rats. The results showed that because of its inherent antioxidant capacity and polyphenolic components, A. hydaspica extract might serve as a possible adjuvant that reduced CP-induced lung damage [17]. Lotfi Ghribia and his coworkers investigated the anti-acetycholinesterase and antioxidant potential activity of compounds and extracts from A. cyanophylla. In the DPPH test, the ethanolic extract of the flowers exhibited the highest antioxidant effect (67.26 µg/mL). The isolated compound, Isosalipurposide 1, also showed a significant antiradical power [21]. Next, five Acacia heartwood methanolic extracts, including A. mangium, A. auriculiformis, A. crassicarpa, A. leucophloea, and A. deccurens, were tested for antioxidant activity using three different in vitro assays. The A. crassicarpa extracts exhibited the highest antioxidant activity, which was accompanied by high phenolic and hydrolyzable tannin concentrations [22].
Many countries around the world, including Pakistan, consider soil salinity to be a severe environmental issue. A. stenophylla and A. albida were studied in a hydroponic experiment to investigate distinct mechanisms of salinity resistance. According to the findings of this study, A. stenophylla is more salinity-tolerant than A. albida because it maintains better ionic balance and stronger antioxidant enzyme activities, resulting in increased biomass production [129]. Additionally, the flower extracts of A. dealbata were investigated during three stages of flowering. The results indicated that the hydroethanolic extracts performed well for all of these biological activities, including antioxidant activity, and the results varied according to the maturity status of the flowers, with the early stage being the most active, which can be attributed to the chalcones content [25]. These first results suggested that A. dealbata could be a good source of natural antioxidants, which may be used to stabilize free radicals that induce oxidative stress.
In another study, during the MeOH extract fractionation of the A. nilotica extract, the AN-2 fraction was isolated and recognized using spectroscopic methods, i.e., mass spectroscopy and NMR, to be a derivative of coumarin (umbelliferone). The anti-oxidative properties in vitro, comprising the deoxyribose, DPPH, reducing power, lipid peroxidation, and chelating power assays, were performed. The results showed that the anti-oxidative activity of umbelliferone was dependent on the concentration, almost 100 μg/mL, and leveled off later with no more activity enhancement. This shows the first document for the antioxidant activity exhibited by umbelliferone isolated from A. nilotica [38]. In the study, the two extraction techniques were evaluated for radical scavenging power. The results showed that the consecutive extraction was efficient in concentrating the bioactive agents in the extract when compared with the maceration. The investigation indicated that the extract of ethanol has high quantities of flavonoid and phenolic compounds and had effective and significant antioxidant potential. The antioxidant activity of the extract (ethanolic) may be attributed to its ability to donate electrons or hydrogen, as well as its direct radical scavenging abilities [130]. Similarly, different studies reported the antioxidant potential of A. catechu. Aryal et al. found that both ethanol and methanol extracts of A. catechu barks exhibit antioxidant potential, assessed by DPPH radical scavenging assay [131]. Additionally, DPPH radical and ABTS radical scavenging assays, ferric reducing power assays, super-oxide radical scavenging assays, and lipid peroxidation with an IC50 of 48.65–54.44 mg of equivalents/g powder demonstrated the antioxidant capacity of methanol and aqueous extracts of A. catechu [132].

3.7. Anti-Filarial and Antidiabetic Activity

Diabetes is one of the world’s five main causes of death. Many herbal medications have been advocated for the treatment of diabetes in addition to the currently available therapeutic options [128]. Previously, authors have documented Acaciaside (both A and B), glucuronic, and methylglucuronic acid, rhamnose, galactose, and arabinose isolated from many parts of A. auriculiformis (Fabaceae) [133]. Acaciaside A and B, which was isolated from the funicles, displayed anti-filarial property both in vitro and in vivo vis à vis bovine filarial parasite Setaria cervi [134,135]. The A. auriculiformis ethanolic extract was found to be effective against microfilaria and tested on dogs infected with Dirofilaria immitis [28]. Acaciaside A also has anti-cestocidal activity [136]. It is also documented to possess anti-plasmodial activity [137]. The A. nilotica ssp. Indica was found to display hypoglycemic properties and the blood sugar levels dropped by almost 25.05% in normal rats nourished for one week; however, it did not exhibit significant hypoglycemic activity in alloxanised diabetic rats. The hypoglycaemic property of the legumes was owing to the indirect or direct stimulation of the β–cells of islets of Langerhans to release more insulin [138]. The other study suggests that a hydroethanolic leaf extract of A. auriculiformis possesses good antioxidant and enzyme inhibitory potential, which, in turn, might be responsible for its antidiabetic effects [29]. Similarly, A. catechu extracts showed an antidiabetic activity towards porcine pancreatic α-amylase, [139] with an IC50 of 49.9 μg/mL. Ethyl acetate, dichloromethane, aqueous fractions, and a crude methanolic extract of the bark of A. catechu showed the inhibitory activity of α-glucosidase and α-amylase, with IC50 ranges of 9–115 g/mL, in another investigation [131]. Kumar et al. studied the antidiabetic potential of an aqueous extract of A. tortilis polysaccharide from gum exudates and its role in the comorbidities associated with diabetes in STZ-nicotinamide-induced diabetic rats [140]. The administration of 500 and 1000 mg/kg doses of the extract showed a significant reduction in fasting blood glucose level compared to diabetic control after 7 days, thus, revealing the potential of A. tortilis for the treatment of T2DM and its comorbidities. Furthermore, chloroform extracts of A. arabica bark significantly decreased the elevated serum glucose levels in alloxan-induced diabetic albino rats [141].

3.8. Antiviral and Nematicidal Activity

The crude extract of the plant’s leaves presented antiviral effects against the Turnip mosaic virus in vitro. The reduction was found in a number of lesions on the host’s C. album (80.2%) and Chenopodium amaranticolor (93.77%), and the lesions decreased once the extract was present on the leaves of the host. The potato virus was repressed by the bark extract [142]. The nematicidal activity was observed by the Aq. leaf extract of the plant and A. senegal as well against Meloidogyne incogenita by the inhibition of its hatching [143]. DNA viruses, viruses belonging to Herpesviridae, Poxviridae, and Papillomaviridae were targeted using V. nilotica, and resulted in anti-bovine herpes virus and direct virucidal activity against goatpox virus. The meta-analysis inferred that V. nilotica could be a promising source of anti-hepatitis C virus drug leads with the ability to prevent its long-term sequelae while promoting immune competence [144]. Additionally, another study aimed to assess the cytotoxic and antiviral activity of an aqueous leaf extract of A. catechu against the new castle disease virus (NDV) on human peripheral blood mononuclear cells (PBMC). Variable doses of the aqueous leaf extract of A. catechu (0.5–30 mg/mL, 50 L; diluted in phosphate-buffered saline, PBS) were tested, and the results showed that at higher concentrations, the aqueous leaf extract of A. catechu suppressed NDV proliferation and also decreased CD14 monocyte surface marker with or without NDV [31].

4. Pharmaceutical Preparation That Have Acacia its Main Molecules

The prospective, placebo, randomized, and positively controlled test was intended to assess the clinical properties of an existing gel enclosing A. arabica for decreasing gingival inflammation and plaque in gingivitis patients. Ninety individuals diagnosed with chronic general gingivitis were included, and then they were arbitrarily distributed (into three groups): Group I, constituted the placebo; Group II, gumtone; Group III, chlorhexidine (1%). A clinical assessment was carried out using the plaque index at baseline and the gingival index of Loe and Silness. Gumtone gel presented substantial clinical enhancement against the index of plaque and gingival scores in comparison to Group I, with a placebo-containing gel. The enhancement was similar to 1% chlorhexidine (gel). Dissimilar to chlorhexidine gel, the gumtone gel was not related to unpleasant taste or the discoloration of teeth [145,146].

4.1. Auromere’s Ayurvedic Formula, Name of Brand: Auromere Ayurvedic, Item: 327045-172138

This combines the ordinary teeth whitening fiber, PEELU, which exhibits invigorating and astringent characteristics of NEEM, as well as other roots, barks, flowers, and plants that were valued by Ayurvedic Professionals for centuries for their distinct and combined efficacy in maintaining superior hygiene. Polishes and cleans teeth to their whitest, refreshes and soothes sensitive gums, and purifies the breath and mouth naturally. Ingredients: Pomegranate Rind Glycerin (from vegetable oil), Fine Chalk (a gentle cleanser), Water, Bishop’s Weed (flower extract), Carageenan (seaweed), Silica, Peelu (salvadora persica), Indian Almond, Sodium Lauryl Sulphate (coconut oil (india)), Sarsaparilla, Rose Apple, silica, Indian Licorice Root, Neem (azadirachta), Clove, Common Jujube, Bark of Barleria Prinoitis (vajradanti), Persian Walnut, Asian Oak, Bedda Nut, Sappan Wood, Zanthoxylum alatum (tejbal), Catechu, Prickly Ash, A. arabica Bark (babul), Bengal Madder, Cinnamon, Mayweed, Medlar Bark, carageenan (from seaweed), cellulose gum (from plants), sodium lauryl sulphate (from the Indian coconut oil), Spearmint Oil, Cinnamon Bark Oil, Eucalyptus Oil, Peppermint Oil, Menthol, Anethole, and Thymol.

4.2. Glyconutrient Powder, Name of Brand: Now Foods, Item: 355483-186295

Immunity maintenance supports intercellular interactions, which are offered through the glyconutrient blend and eight sugar immune enhancers. Glyconutrient Blend is a branded blend of ingredients. It contains eight immune-boosting glyconutrients derived from the whole coffee bean, as well as other natural ingredients. These nutrients are known as vital components for cellular network signaling, as well as playing particular functions in immune responses. ImmunEnhancer™ (a polysaccharide) is derived from a Larch known as Arabinogalactan. The basis of good health is built upon a strong responsive immune system. Arabinogalactan’s effects on NK Cells have been shown i to maintain a healthy immune system in scientific investigations.

4.3. Powder of Organic Acacia Fiber, Name of Brand: Now Foods, Item: 415 723-206319

Organic Acacia Fiber Powder is a dietary fiber made from the gum of the Acacia tree; it is pure, natural, and soluble. Research has indicated that soluble fiber in the diet can aid in improving bowel regularity. The powder also exhibits tremendous prebiotic potential, as it is able to support healthy intestinal flora. Since it reduces fermentation and decreases bloating and gas problems, Acacia powder is well tolerated. This powder can be taken on a daily basis and does not contain any gastrointestinal irritant stimulants [147]. To date, scientists are looking for new alternatives and ways to increase the value of the various products derived from A. nilotica. The by-products of the species A. nilotica have been explored for their full use in diverse fields. The multipurpose value of A. nilotica as a source of fodder, fence posts, fuel, wood, shade, gums, and tannin has provoked the researchers with further directions for investigation. The gum obtained from the trunk has already been part of the cosmetic, textile dyeing, printing, food, and pharmaceutical industries [148]. The leaves have also been used to remove hazardous synthetic colors and heavy metals from wastewater as bio-adsorbents. It can also be used as a bio-indicator to monitor pollution from heavy metals, copper, and cobalt.

5. Herb–Drug Interaction

To date, research based on drug–herbal interactions has generally been limited to case reports and limited systematic reviews. Meanwhile, for the treatment of several medical conditions, supplements of herbal drugs are used around the world. These are used in combination with drugs or used alone [149]. In some cases, the combined use of herbs and drugs may alter the pharmacokinetic profile of drugs [150]. The simultaneous usage of herbal medicines may increase, oppose, or stimulate the activity of drugs. Clinically, the lack of efficacy might be the consequence of these interactions, as well as toxic reactions, and unexpected side effects. Thus, healthcare professionals should remain vigilant for the potential interactions between herbal medicines and prescribed drugs, especially when drugs with a narrow therapeutic index are used. The data show that the Acacia gum obtained from A. rabi, reduced the absorption of drugs, such as amoxicillin [151]. The findings indicate that the coexistence of amoxicillin and gum rabic in the upper gastrointestinal tract resulted in a pharmacokinetic interaction that significantly decreased the absorption of amoxicillin. The other study proposed that black catechu can significantly alter theophylline pharmacokinetics in vivo, possibly due to the inhibition of CYP1A and P-glycoprotein activity; thus, precaution should be exercised when administering black catechu with CYP1A substrate [152].

6. Conclusions

Ethnopharmacology is the field that involves the detailed study of plants to identify new medications and the development of advanced drugs. Genus Acacia includes a group of plants with promising pharmacological properties. This review summarizes the presence of phytoconstituents in different Acacia species with diverse and potent pharmacological properties, including anti-inflammatory, analgesic, antioxidant, antimutagenic, antiproteolytic, antiviral, nematicidal activity, and so on. Mainly, polyphenols are responsible for the antioxidant potential of different extracts and the said pharmacological potential. The use of Acacia extracts and their active agents in different herbal formulations further demonstrated the medicinal value of this genus. Due to the promising therapeutic role of different species of Acacia, further studies should be carried out in order to develop multifunctional drugs and describe their bioavailability, pharmacokinetics, physiological pathways, and importance to human health in sufficient detail.

Author Contributions

G.E.-S.B. Conceptualization and original draft preparation; N.A. Data collection; writing—review and editing; A.A.A. review; W.F.A. editing; N.H.A. review; H.M.S. original draft preparation; T.G.S.; writing, M.D.W. funding acquisition. All authors have read and agreed to the published version of the manuscript.

Funding

M.D.W. thanks the French Agence Nationale de la Recherche and the Région Pays de la Loire for financial support on COVID-19 research (ANR Flash COVID-19 call-name: CoV2-E-TARGET-grant number: 2020 07132).

Data Availability Statement

Data presented in this study are available on reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Maslin, B.; Orchard, A.; West, J. Nomenclatural and Classification History of Acacia (Leguminosae: Mimosoideae), and the Implications of Generic Subdivision; Department of Conservation & Land Management: Kensington, WA, USA, 2003. [Google Scholar]
  2. Sanchez, C.; Nigen, M.; Tamayo, V.M.; Doco, T.; Williams, P.; Amine, C.; Renard, D. Acacia gum: History of the future. Food Hydrocoll. 2018, 78, 140–160. [Google Scholar] [CrossRef]
  3. Bhargava, A.; Srivastava, A.; Kumbhare, V. Antifungal activity of polyphenolic complex of Acacia nilotica bark. Indian For. 1998, 124, 292–298. [Google Scholar]
  4. Kosalec, I.; Pepeljnjak, S.; Kuštrak, D. Antifungal activity of fluid extract and essential oil from anise fruits (Pimpinella anisum L., Apiaceae). Acta Pharm. 2005, 55, 377–385. [Google Scholar]
  5. Sadiq, M.B.; Tharaphan, P.; Chotivanich, K.; Tarning, J.; Anal, A.K. In vitro antioxidant and antimalarial activities of leaves, pods and bark extracts of Acacia nilotica (L.) Del. BMC Complement. Alter. Med. 2017, 17, 372. [Google Scholar] [CrossRef] [Green Version]
  6. Abdel-Farid, I.; Sheded, M.; Mohamed, E. Metabolomic profiling and antioxidant activity of some Acacia species. Saudi J. Biol. Sci. 2014, 21, 400–408. [Google Scholar] [CrossRef] [Green Version]
  7. Alajmi, M.F.; Alam, P.; Alqasoumi, S.I.; Siddiqui, N.A.; Basudan, O.A.; Hussain, A.; Husain, F.M.; Khan, A.A. Comparative anticancer and antimicrobial activity of aerial parts of Acacia salicina, Acacia laeta, Acacia hamulosa and Acacia tortilis grown in Saudi Arabia. Saudi Pharm. J. 2017, 25, 1248–1252. [Google Scholar] [CrossRef] [PubMed]
  8. Seigler, D.S. Phytochemistry of Acacia—sensu lato. Biochem. Syst. Ecol. 2003, 31, 845–873. [Google Scholar] [CrossRef]
  9. Gilani, A.; Shaheen, F.; Zaman, M.; Janbaz, K.; Shah, B.; Akhtar, M. Studies on antihypertensive and antispasmodic activities of methanol extract of Acacia nilotica pods. Phytother. Res. Int. J. Devoted Pharmacol. Toxicol. Eval. Nat. Product Deriva. 1999, 13, 665–669. [Google Scholar] [CrossRef]
  10. Das, N.; Chatterjee, P. Evaluation of Antimicrobial Potentiality of 50% Aqueous Ethanoloic Leaf Extract of Clitoria ternatea L. Asian J. Pharm. Clin. Research. Innovare Acad. 2014, 7 (Suppl. S1), 80–82. [Google Scholar]
  11. Abid, F.; Saleem, M.; Leghari, T.; Rafi, I.; Maqbool, T.; Fatima, F.; Arshad, A.M.; Khurshid, S.; Naz, S.; Hadi, F.; et al. Evaluation of in vitro anticancer potential of pharmacological ethanolic plant extracts Acacia modesta and Opuntia monocantha against liver cancer cells. Braz. J. Biol. 2022, 84, e252526. [Google Scholar] [CrossRef] [PubMed]
  12. Afsar, T.; Khan, M.R.; Razak, S.; Ullah, S.; Mirza, B. Antipyretic, anti-inflammatory and analgesic activity of Acacia hydaspica R. Parker and its phytochemical analysis. BMC Complement. Altern. Med. 2015, 15, 136. [Google Scholar] [CrossRef] [Green Version]
  13. Wu, J.-H.; Tung, Y.-T.; Chien, S.-C.; Wang, S.-Y.; Kuo, Y.-H.; Shyur, L.-F.; Chang, S.-T. Effect of Phytocompounds from the Heartwood of Acacia confusa on Inflammatory Mediator Production. J. Agric. Food Chem. 2008, 56, 1567–1573. [Google Scholar] [CrossRef]
  14. Ziani, B.E.; Carocho, M.; Abreu, R.M.; Bachari, K.; Alves, M.J.; Calhelha, R.C.; Talhi, O.; Barros, L.; Ferreira, I.C. Phenolic profiling, biological activities and in silico studies of Acacia tortilis (Forssk.) Hayne ssp. raddiana extracts. Food Biosci. 2020, 36, 100616. [Google Scholar] [CrossRef]
  15. Mutai, C.; Rukunga, G.; Vagias, C.; Roussis, V. In vivo screening of antimalarial activity of Acacia mellifera (Benth)(Leguminosae) on Plasmodium berghei in mice. Afr. J. Tradit. Complement. Alter. Med. 2008, 5, 46–50. [Google Scholar] [CrossRef] [Green Version]
  16. Amoussa, A.M.O.; Lagnika, L.; Bourjot, M.; Vonthron-Senecheau, C.; Sanni, A. Triterpenoids from Acacia ataxacantha DC: Antimicrobial and antioxidant activities. BMC Complement. Altern. Med. 2016, 16, 284. [Google Scholar] [CrossRef] [Green Version]
  17. Afsar, T.; Razak, S.; Almajwal, A.; Khan, M.R. Acacia hydaspica R. Parker ameliorates cisplatin induced oxidative stress, DNA damage and morphological alterations in rat pulmonary tissue. Complement. Altern. Med. 2018, 18, 49. [Google Scholar] [CrossRef] [Green Version]
  18. Badr, J.M.; Shaala, L.A.; Youssef, D.T. Loranthin: A new polyhydroxylated flavanocoumarin from Plicosepalus acacia with significant free radical scavenging and antimicrobial activity. Phytochem. Lett. 2013, 6, 113–117. [Google Scholar] [CrossRef]
  19. Sánchez, E.; Heredia, N.; Mdel, R.C.; García, S. Isolation, characterization and mode of antimicrobial action against Vibrio cholerae of methyl gallate isolated from Acacia farnesiana. J. Appl. Microbiol. 2013, 115, 1307–1316. [Google Scholar] [CrossRef]
  20. Deboshree, B.; Roymon, M. LC/TOF/ESI/MS based detection of bioactive compounds present in leaf and bark extract of Acacia arabica. Recent Res. Sci. Technol. 2013, 5, 37–40. [Google Scholar]
  21. Ghribia, L.; Ghouilaa, H.; Omrib, A.; Besbesb, M.; Janneta, H.B. Antioxidant and anti–acetylcholinesterase activities of extracts and secondary metabolites from Acacia cyanophylla. Asian Pac. J. Trop. Biomed. 2014, 4, S417–S423. [Google Scholar] [CrossRef] [Green Version]
  22. Prayogo, Y.H.; Syafii, W.; Sari, R.K.; Batubara, I. Pharmacological Activity and Phytochemical Profile of Acacia Heartwood Extracts. Sci. Pharm. 2021, 89, 37. [Google Scholar] [CrossRef]
  23. Cavazos, P.; Gonzalez, D.; Lanorio, J.; Ynalvez, R. Secondary metabolites, antibacterial and antioxidant properties of the leaf extracts of Acacia rigidula benth. and Acacia berlandieri benth. SN Appl. Sci. 2021, 3, 522. [Google Scholar] [CrossRef]
  24. Karoune, S.; Falleh, H.; Kechebar, M.S.A.; Halis, Y.; Mkadmini, K.; Belhamra, M.; Rahmoune, C.; Ksouri, R. Evaluation of antioxidant activities of the edible and medicinal Acacia albida organs related to phenolic compounds. Nat. Product Res. 2015, 29, 452–454. [Google Scholar] [CrossRef] [PubMed]
  25. Paula, V.; Pedro, S.I.; Campos, M.G.; Delgado, T.; Estevinho, L.M.; Anjos, O. Special Bioactivities of Phenolics from Acacia dealbata L. with Potential for Dementia, Diabetes and Antimicrobial Treatments. Appl. Sci. 2022, 12, 1022. [Google Scholar] [CrossRef]
  26. Gedara, S.R.; Galala, A.A. New cytotoxic spirostane saponin and biflavonoid glycoside from the leaves of Acacia saligna (Labill.) H.L. Wendl. Nat. Prod. Res. 2014, 28, 324–329. [Google Scholar] [CrossRef] [PubMed]
  27. Nyila, M.A.; Leonard, C.M.; Hussein, A.A.; Lall, N. Activity of South African medicinal plants against Listeria monocytogenes biofilms, and isolation of active compounds from Acacia karroo. South Afr. J. Botany 2012, 78, 220–227. [Google Scholar] [CrossRef] [Green Version]
  28. Chakraborty, T.; Sinhababu, S.; Sukul, N. Antifilarial Effect of a Plant Acacia auriculiformis on Canine Dirofilariasis. Trop. Med. 1995, 37, 35–37. [Google Scholar]
  29. Sharma, D.; Verma, S.; Kumar, S.; Singh, J.; Kumar, R.; Jangra, A.; Kumar, D. Hydroethanolic leaf extract of Acacia auriculiformis exhibited antidiabetic and antioxidant activities. Egypt. J. Basic Appl. Sci. 2022, 9, 372–382. [Google Scholar] [CrossRef]
  30. Feregrino-Perez, A.; Pacheco, I.; Hernández, M.; Munguia-Fragozo, P.; Mendoza-Diaz, S.; Ocampo-Velázquez, R.; Rico-García, E.; Guevara-Gonzalez, R. Antioxidant and antimutagenic activities of Acacia pennatula pods. J. Sci. Ind. Res. 2011, 70, 859–864. [Google Scholar]
  31. Gupta, A.; Chaphalkar, S.R. Cytotoxic and anti-viral activity of Acacia catechu on human peripheral blood mononuclear cells. Indones. J. Pharm. 2016, 27, 111. [Google Scholar] [CrossRef]
  32. Mattana, C.M.; Satorres, S.E.; Escobar, F.; Sabini, C.; Sabini, L.; Fusco, M.; Alcaráz, L.E. Antibacterial and cytotoxic activities of Acacia aroma extracts. Emir. J. Food Agric. 2012, 24, 308–313. [Google Scholar]
  33. Clement, B.A.; Goff, C.M.; Forbes, T.D.A. Toxic amines and alkaloids from Acacia berlandieri. Phytochemistry 1997, 46, 249–254. [Google Scholar] [CrossRef]
  34. Haridas, V.; Higuchi, M.; Jayatilake, G.S.; Bailey, D.; Mujoo, K.; Blake, M.E.; Arntzen, C.J.; Gutterman, J.U. Avicins: Triterpenoid saponins from Acacia victoriae (Bentham) induce apoptosis by mitochondrial perturbation. Proc. Natl. Acad. Sci. USA 2001, 98, 5821–5826. [Google Scholar] [CrossRef] [Green Version]
  35. Readel, K.; Seigler, D.; Hwang, K.; Keesy, J.; Seilheimer, S. Tannins from mimosoid legumes of Texas and Mexico. Econ. Botany 2001, 55, 212–222. [Google Scholar] [CrossRef]
  36. Singh, B.N.; Singh, B.; Singh, R.; Prakash, D.; Sarma, B.; Singh, H. Antioxidant and anti-quorum sensing activities of green pod of Acacia nilotica L. Food Chem. Toxicol. 2009, 47, 778–786. [Google Scholar] [CrossRef]
  37. Singh, R.; Singh, S.; Kumar, S.; Arora, S. Evaluation of antioxidant potential of ethyl acetate extract/fractions of Acacia auriculiformis A. Cunn. Food Chem. Toxicol. 2007, 45, 1216–1223. [Google Scholar] [CrossRef]
  38. Singh, R.; Singh, B.; Singh, S.; Kumar, N.; Kumar, S.; Arora, S. Umbelliferone–an antioxidant isolated from Acacia nilotica (L.) Willd. Ex. Del. Food Chem. 2010, 120, 825–830. [Google Scholar] [CrossRef]
  39. Evans, C.S.; Bell, E.A. Non-protein amino acids of Acacia species and their effect on the feeding of the acridids Anacridium melanorhodon and Locusta migratoria. Phytochemistry 1979, 18, 1807–1810. [Google Scholar] [CrossRef]
  40. Forbes, T.; Pemberton, I.; Smith, G.; Hensarling, C. Seasonal variation of two phenolic amines in Acacia berlandieri. J. Arid Environ. 1995, 30, 403–415. [Google Scholar] [CrossRef]
  41. Fitzgerald, J. Alkaloids of the Australian Leguminosae. III. The occurrence of phenylethylamine derivatives in Acacia species. Aust. J. Chem. 1964, 17, 160–162. [Google Scholar] [CrossRef] [Green Version]
  42. Fitzgerald, J.; Sioumis, A. Alkaloids of the Australian Leguminosae. V. The occurrence of methylated tryptamines in Acacia maidenii F. Muell. Aust. J. Chem. 1965, 18, 433–434. [Google Scholar] [CrossRef] [Green Version]
  43. Ebinger, J.E.; Seigler, D.S.; Clarke, H.D. Taxonomic revision of South American species of the genus Acacia subgenus Acacia (Fabaceae: Mimosoideae). Syst. Botany 2000, 25, 588–617. [Google Scholar] [CrossRef]
  44. Seigler, D.; Hernandez, J.F. Comparative tanning ability of extracts from four North American species of Acacia. J. Am. Leather Chem. Assoc. 1989, 84, 315–328. [Google Scholar]
  45. Maslin, B.R.; Conn, E.E.; Dunn, J.E. Cyanogenic Australian Species of Acacia: A Preliminary Account of Their Toxicity Potential; Australian Centre for International Agricultural Research: Canberra, Australia, 1987; pp. 107–111. [Google Scholar]
  46. Seigler, D.; Maslin, B.; Conn, E. Cyanogenesis in the Leguminosae. Adv. Legume Biol. Monogr. Syst. Bot. Missouri Bot. Garden 1989, 29, 645–672. [Google Scholar]
  47. Bai, S.; Seasotiya, L.; Malik, A.; Bharti, P.; Dalal, S. GC-MS analysis of chloroform extract of Acacia nilotica L. leaves. J. Pharmacogn. Phytochem. 2014, 2, 79–82. [Google Scholar]
  48. Josm, K.; Tholia, M.; Sharma, T. Chemical examination of Acacia modesta. Planta Medica 1975, 27, 281–283. [Google Scholar] [CrossRef]
  49. Brown, A.; Cherikoff, V.; Roberts, D. Fatty acid composition of seeds from the Australian Acacia species. Lipids 1987, 22, 490–494. [Google Scholar] [CrossRef]
  50. Abdel-Raouf, A.M.; Mansour, S.R. Improving soil physical properties and its effect on Acacia tortilis seedlings growth under field conditions. Asian J. Plant Sci. 2003, 2, 861–868. [Google Scholar]
  51. Harrison, G.; Hawke, F. Studies of the Fats from Indigenous South African Plants. III:∆-9, 12-Hexadecadienoic Acid: Its Constitution and Occurrence in the Seed Fat and Seed Pod Fat of Acacia giraffae (Kameeldoorn). J. South Afr. Chem. Inst. 1952, 5, 23–30. [Google Scholar]
  52. Grindley, D. Investigation of the seed oils of some Sudan Mimosaceae. J. Soc. Chem. Ind. 1945, 64, 152. [Google Scholar]
  53. Earle, F.; Melvin, E.; Mason, L.; van Etten, C.; Wolff, I.; Jones, Q. Search for new industrial oils. I. Selected oils from 24 plant families. J. Am. Oil Chem. Soc. 1959, 36, 304–307. [Google Scholar] [CrossRef]
  54. Maslin, B.R.; Dunn, J.E.; Conn, E.E. Cyanogenesis in Australian species of Acacia. Phytochemistry 1988, 27, 421–428. [Google Scholar] [CrossRef]
  55. Vikrant, V.; Kumar, S.U.; Kumar, S.A.; Suparna, S.; Brijendra, S.; Prashant, G.; Rahul, S. A review on Acacia nilotica Linn. and its ethnobotany, phytochemical and pharmacological profile. Int. J. Pharm. Res. Dev. 2012, 4, 251. [Google Scholar]
  56. Seigler, D.S. Economic potential from Western Australian Acacia species: Secondary plant products. Conserv. Sci. West. Aust. 2002, 4, 109–116. [Google Scholar]
  57. Bemiller, J.N.; Whistler, R.L.; Barkalow, D.G.; Chen, C.-C. Aloe, chia, flaxseed, okra, psyllium seed, quince seed, and tamarind gums. In Industrial Gums; Elsevier: Amsterdam, The Netherlands, 1993; pp. 227–256. [Google Scholar]
  58. Evert, R.F. Esau’s Plant Anatomy: Meristems, Cells, and Tissues of the Plant Body: Their Structure, Function, and Development; John Wiley & Sons: New York, NY, USA, 2006. [Google Scholar]
  59. Anderson, D.; Farquhar, J.; McNab, C. The gum exudates from some Acacia subspecies of the series Botryocephalae. Phytochemistry 1984, 23, 579–580. [Google Scholar] [CrossRef]
  60. Anderson, D.; Weiping, W. Acacia gum exudates from Somalia and Tanzania: The Acacia senegal complex. Biochem. Syst. Ecol. 1990, 18, 413–418. [Google Scholar] [CrossRef]
  61. Brockwell, J.; Searle, S.D.; Jeavons, A.C.; Waayers, M. Nitrogen fixation in acacias: An untapped resource for sustainable plantations, farm forestry and land reclamation; Monograph No. 115; Australian Centre for International Agricultural Research: Bruce, ACT, Australia, 2005; 132p. [Google Scholar]
  62. Guinko, S. Etude Surle role des Acacia dans Le development rural au Burkin Faso et au Niger. Ouagaduogu (Mimeo) 1991, 1, 6–10. [Google Scholar]
  63. Whibley, D.J.; Symon, D.E. Acacias of South Australia, Flora and Fauna of South Australia Handbooks Committee; The University of Michigan: St. Ann Arbor, MI, USA, 1992. [Google Scholar]
  64. Mohammadifar, M.A.; Musavi, S.M.; Kiumarsi, A.; Williams, P.A. Solution properties of targacanthin (water-soluble part of gum tragacanth exudate from Astragalus gossypinus). Int. J. Biol. Macromol. 2006, 38, 31–39. [Google Scholar] [CrossRef]
  65. Karamallah, K. Gum Arabic–Quality and Quantity Assured. In Gums and Stabilisers for the Food Industry 10; Elsevier: Amsterdam, The Netherlands, 2000; pp. 37–52. [Google Scholar]
  66. Al-Assaf, S.; Phillips, G.O.; Amar, V. Gum ghatti. Handbook of Hydrocolloids; Elsevier: Amsterdam, The Netherlands, 2021; pp. 653–672. [Google Scholar]
  67. Anderson, D.; McDougall, F. The composition of the proteinaceous gums exuded by Acacia gerrardii and Acacia goetzii subsp. goetzii. Food Hydrocoll. 1987, 1, 327–331. [Google Scholar] [CrossRef]
  68. Daoub, R.M.; Elmubarak, A.H.; Misran, M.; Hassan, E.A.; Osman, M.E. Characterization and functional properties of some natural Acacia gums. J. Saudi Soc. Agric. Sci. 2018, 17, 241–249. [Google Scholar] [CrossRef] [Green Version]
  69. Younes, A. Physicochemical Studies on Some Acacia Gum Sand Their Fractions. Ph.D. Thesis, Chemistry Department, Faculty of Science, Sudan University, Khartoum, Sudan, 2009. [Google Scholar]
  70. Satti, A.A.E. Characterization and Toxicological Study of Acacia nilotica var. nilotica Gum from Sudan. Ph.D. Thesis, Sudan University of Science and Technology, Khartoum, Sudan, 2011. [Google Scholar]
  71. Ibrahim, O.B.; Osman, M.E.; Hassan, E.A. Characterization and simple fractionation of Acacia Senegal. J. Chem. Acta 2013, 2, 11–17. [Google Scholar]
  72. Anderson, D.M.W.; Bell, P.C. The composition and properties of gum exudates from subspecies of Acacia tortilis. Phytochemistry 1974, 13, 1875–1877. [Google Scholar] [CrossRef]
  73. Sharma, A.; Bhushette, P.R.; Annapure, U.S. Physicochemical and rheological properties of Acacia catechu exudate gum. Carbohydr. Polym. Technol. Appl. 2021, 2, 100127. [Google Scholar] [CrossRef]
  74. Krauss, G.-J.; Reinbothe, H. Die freien aminosäuren in samen von mimosaceae. Phytochemistry 1973, 12, 125–142. [Google Scholar] [CrossRef]
  75. Gmelin, R.; Kjaer, A.; Larsen, P.O. N-acetyl-l-djenkolic acid, a novel amino acid isolated from Acacia farnesiana willd. Phytochemistry 1962, 1, 233–236. [Google Scholar] [CrossRef]
  76. Evans, C.S.; Clardy, J.; Hughes, P.F.; Bell, E.A. 2-Amino-4-acetylaminobutyric acid, 2, 4-diaminobutyric acid and 2-amino-6N-oxalylureidopropionic acid (oxalylalbizziine) in seeds of Acacia angustissima. Phytochemistry 1985, 24, 2273–2275. [Google Scholar] [CrossRef]
  77. Murphy, D.J. A review of the classification of Acacia (Leguminosae, Mimosoideae). Muelleria 2008, 26, 10–26. [Google Scholar] [CrossRef]
  78. Gmelin, R. Mimosaceen-Aminosauren. 7. Isolierung von Willardiin (3-(1-uracyl)-L-alanin) aus den samen von Acacia millefolia, Acacia lemmoni und mimosa asperata, munksgaard INT publ LTD 35 norre Sogade, Po BOX 2148, DK-1016 copenhagen. Acta Chem. Scand. 1961, 15, 1188. [Google Scholar] [CrossRef]
  79. Saayman, H.; Roux, D. The origins of tannins and flavonoids in black-wattle barks and heartwoods, and their associatednon-tannin’components. Biochem. J. 1965, 97, 794. [Google Scholar] [CrossRef] [Green Version]
  80. Clark-Lewis, J.; Porter, L. Phytochemical survey of the heartwood flavonoids of Acacia species from arid zones of Australia. Aust. J. Chem. 1972, 25, 1943–1955. [Google Scholar] [CrossRef]
  81. Demole, E.; Enggist, P.; Stoll, M. Sur les constituants odorants de l’essence absolue de Cassie (Acacia farnesiana Willd.). Helvetica Chim. Acta 1969, 52, 24–32. [Google Scholar] [CrossRef]
  82. Oyen, L.; Dung, N.X. Plant Resources of South-East Asia no. 19: Essential-Oil Plants; Backhuys Publishers: Leiden, The Netherlands, 1999. [Google Scholar]
  83. Flath, R.A.; Mon, T.R.; Lorenz, G.; Whitten, C.J.; Mackley, J.W. Volatile components of Acacia sp. blossoms. J. Agric. Food Chem. 1983, 31, 1167–1170. [Google Scholar] [CrossRef]
  84. Guenther, E. The Essential Oils; D. Van Nostrand Company: New York, NY, USA, 1952; Volume 6. [Google Scholar]
  85. Joshi, K.; Bansal, R.; Sharma, T.; Murray, R.; Forbes, I.; Cameron, A.; Maltz, A. Two novel cassane diterpenoids from Acacia jacquemontii. Tetrahedron 1979, 35, 1449–1453. [Google Scholar] [CrossRef]
  86. Forster, P.G.; Ghisalberti, E.L.; Jefferies, P.R. Labdane diterpenes from an Acacia species. Phytochemistry 1985, 24, 2991–2993. [Google Scholar] [CrossRef]
  87. Anjaneyulu, A.; Bapuji, M.; Row, L.R.; Sree, A. Structure of acacigenin-B, a novel triterpene ester isolated from Acacia concinna. Phytochemistry 1979, 18, 463–466. [Google Scholar] [CrossRef]
  88. Mahato, S.B.; Pal, B.C.; Price, K.R. Structure of Acaciaside, a triterpenoid trisaccharide from Acacia auriculiformis. Phytochemistry 1989, 28, 207–210. [Google Scholar] [CrossRef]
  89. Eade, R.; McDonald, F.; Simes, J. Extractives of Australian timbers. XIV. Triterpene glycosides of Acacia myrtifolia. Aust. J. Chem. 1973, 26, 839–844. [Google Scholar] [CrossRef]
  90. Haridas, V.; Arntzen, C.J.; Gutterman, J.U. Avicins, a family of triterpenoid saponins from Acacia victoriae (Bentham), inhibit activation of nuclear factor-κB by inhibiting both its nuclear localization and ability to bind DNA. Proc. Natl. Acad. Sci. USA 2001, 98, 11557–11562. [Google Scholar] [CrossRef] [Green Version]
  91. Hanausek, M.; Ganesh, P.; Walaszek, Z.; Arntzen, C.J.; Slaga, T.J.; Gutterman, J.U. Avicins, a family of triterpenoid saponins from Acacia victoriae (Bentham), suppress H-ras mutations and aneuploidy in a murine skin carcinogenesis model. Proc. Natl. Acad. Sci. USA 2001, 98, 11551–11556. [Google Scholar] [CrossRef] [Green Version]
  92. Tindale, M.D.; Roux, D. A phytochemical survey of the Australian species of Acacia. Phytochemistry 1969, 8, 1713–1727. [Google Scholar] [CrossRef]
  93. Malan, E.; Roux, D.G. Flavonoids and tannins of Acacia species. Phytochemistry 1975, 14, 1835–1841. [Google Scholar] [CrossRef]
  94. Drewes, S.; Ilsley, A. Isomeric leucofisetinidins from Acacia mearnsii. Phytochemistry 1969, 8, 1039–1042. [Google Scholar] [CrossRef]
  95. Tindale, M.D.; Roux, D.G. Phytochemical studies on the heart woods and barks of African and Australian species of Acacia. Boissiera 1975, 24, 299–305. [Google Scholar]
  96. Hammer, R.H.; Cole, J.R. Phytochemical investigation of Acacia angustissima. J. Pharm. Sci. 1965, 54, 235–239. [Google Scholar] [CrossRef]
  97. El-Mousallamy, A.; Barakat, H.; Souleman, A.; Awadallah, S. Polyphenols of Acacia raddiana. Phytochemistry 1991, 30, 3767–3768. [Google Scholar] [CrossRef]
  98. Van Heerden, F.R.; Brandt, E.V.; Ferreira, D.; Roux, D.G. Metabolites from the purple heartwoods of the mimosoideae. Part 4. Acacia fasciculifera F. Muell ex. Benth: Fasciculiferin, fasciculiferol, and the synthesis of 7-aryl-and 7-flavanyl-peltogynoids. J. Chem. Soc. Perkin Transact. 1981, 1, 2483–2490. [Google Scholar]
  99. Noreljaleel, A.E.M.; Wilhelm, A. Analysis of Commercial Proanthocyanidins. Part 6: Sulfitation of Flavan-3-Ols Catechin and Epicatechin, and Procyanidin B-3. Molecules 2020, 25, 4980. [Google Scholar] [CrossRef]
  100. Malan, J.C.; Steynberg, P.J.; Steynberg, J.P.; Young, D.A.; Bezuidenhoudt, B.B.; Ferreira, D. Oligomeric flavanoids. part 14. Proguibourtinidins based on (-)-fisetinidol and (+)-epifisetinidol units. Tetrahedron 1990, 46, 2883–2890. [Google Scholar] [CrossRef]
  101. Mugedo, J.Z.; Waterman, P.G. Sources of tannin: Alternatives to wattle (Acacia mearnsii) among indigenous Kenyan species. Econ. Botany 1992, 46, 55–63. [Google Scholar] [CrossRef]
  102. Ferreira, D.; Preez, I.C.d.; Wijnmaalen, J.C.; Roux, D.G. Biflavanoid proguibourtinidin carboxylic acids and their biflavanoid homologues from Acacia luederitzii. Phytochemistry 1985, 24, 2415–2422. [Google Scholar] [CrossRef]
  103. Gandhi, P. A new proanthocyanidin from the stem bark of Acacia suma. Experientia 1977, 33, 1272. [Google Scholar] [CrossRef]
  104. Ferreira, D.; van Rensburg, H.; Malan, E.; Coetzee, J.; Nel, R.J. Recent advances in the chemistry of proanthocyanidins. In Phytochemicals in Human Health Protection, Nutrition, and Plant Defense; Springer: Berlin/Heidelberg, Germany, 1999; pp. 255–288. [Google Scholar]
  105. Malan, E. A (4β→ 5)-linked proteracacinidin dimer from the heartwood of Acacia caffra. Phytochemistry 1995, 40, 1519–1521. [Google Scholar] [CrossRef]
  106. Searle, S. The Rise and Demise of the Black Wattle Bark Industry in Australia; Division of Forestry and Forest Products, CSIRO: Clayton, Australia, 1991. [Google Scholar]
  107. Young, D.A.; Ferreira, D.; Roux, D.G. Stereochemistry and dynamic behavior of some synthetic angular profisetinidin tetraflavanoid derivatives. J. Polym. Sci. Part A Polym. Chem. 1986, 24, 835–849. [Google Scholar] [CrossRef]
  108. Imran, I.; Hussain, L.; Zia-Ul-Haq, M.; Janbaz, K.H.; Gilani, A.H.; de Feo, V. Gastrointestial and respiratory activities of Acacia leucophloea. J. Ethnopharmacol. 2011, 138, 676–682. [Google Scholar] [CrossRef]
  109. Rai, S.; Prasad, M.S.; Singh, K. Evaluation of the Antifungal Activity of the Potent Fraction of Hexane Extract Obtained from the bark of Acacia nilotica. IJSR 2014, 3, 730–738. [Google Scholar]
  110. Newman, D.J.; Cragg, G.M.; Snader, K.M. Natural products as sources of new drugs over the period 1981–2002. J. Nat. Prod. 2003, 66, 1022–1037. [Google Scholar] [CrossRef]
  111. Meena, P.D.; Kaushik, P.; Shukla, S.; Soni, A.K.; Kumar, M.; Kumar, A. Anticancer and antimutagenic properties of Acacia nilotica (Linn.) on 7, 12-dimethylbenz (a) anthracene-induced skin papillomagenesis in Swiss albino mice. Asian Pac. J. Cancer Prev. 2006, 7, 627–632. [Google Scholar]
  112. Kannan, N.; Sakthivel, K.M.; Guruvayoorappan, C. Protective effect of Acacia nilotica (L.) against acetaminophen-induced hepatocellular damage in wistar rats. Adv. Pharmacol. Sci. 2013, 2013, 987692. [Google Scholar] [CrossRef] [Green Version]
  113. Jain, A.; Shimoi, K.; Nakamura, Y.; Tomita, I.; Kada, T. Preliminary study on the desmutagenic and antimutagenic effect of some natural products. Current Sci. 1987, 56, 1266–1269. [Google Scholar]
  114. Monga, J.; Chauhan, C.S.; Sharma, M. Human breast adenocarcinoma cytotoxicity and modulation of 7, 12-dimethylbenz [a] anthracene-induced mammary carcinoma in Balb/c mice by Acacia catechu (Lf) Wild heartwood. Integr. Cancer Ther. 2013, 12, 347–362. [Google Scholar] [CrossRef] [Green Version]
  115. Adhikari, B.; Aryal, B.; Bhattarai, B.R. A Comprehensive Review on the Chemical Composition and Pharmacological Activities of Acacia catechu (Lf) Willd. J. Chem. 2021, 2021, 2575598. [Google Scholar] [CrossRef]
  116. Sharma, M.; Gupta, A.; Mukherji, A. Invasive Acacia nilotica a problematic weed is a source of potent methyl gallate. Int. J. Sci. Res. 2014, 3, 1193–1195. [Google Scholar]
  117. Dafallah, A.A.; Al-Mustafa, Z. Investigation of the anti-inflammatory activity of Acacia nilotica and Hibiscus sabdariffa. Am. J. Chin. Med. 1996, 24, 263–269. [Google Scholar] [CrossRef]
  118. Alli, L.A.; Nafiu, M.O.; Adesokan, A.A.; Akanji, M.A.; Tijani, A.Y.; Salawu, Q. Antipyretic and analgesic activities of aqueous extract of Acacia nilotica root. Biokemistri 2014, 26, 55–62. [Google Scholar]
  119. Iqbal, A.; Din, S.U.; Bakht, J.; Khan, I.U. Evaluation of Acacia cyanophylla for their analgesic, anti-pyretic and anti-inflammatory potentials. Pak. J. Pharm. Sci. 2022, 35, 835–840. [Google Scholar]
  120. Eldeen, I.; van Heerden, F.; van Staden, J. In vitro biological activities of niloticane, a new bioactive cassane diterpene from the bark of Acacia nilotica subsp. kraussiana. J. Ethnopharmacol. 2010, 128, 555–560. [Google Scholar] [CrossRef]
  121. Chaubal, R.; Mujumdar, A.; Puranik, V.G.; Deshpande, V.; Deshpande, N. Isolation and X-ray study of an anti-inflammatory active androstene steroid from Acacia nilotica. Planta Medica 2003, 69, 287–288. [Google Scholar] [CrossRef]
  122. Sokeng, S.; Koubé, J.; Dongmo, F.; Sonnhaffouo, S.; Nkono, B.; Taïwé, G.; Cherrah, Y.; Kamtchouing, P. Acute and chronic anti-inflammatory effects of the aqueous extract of Acacia nilotica (L.) Del.(Fabaceae) pods. Acad. J. Med. Plants 2013, 1, 1–5. [Google Scholar]
  123. Latif, S.; Ismail, H.; Khan, M.R.; Rahim, A.A.; Mehboob, R.; Dilshad, E.; Sajid, M.; Haider, S.I.; Anwaar, S.; Majeed, M.N. Pharmacological evaluation of Acacia modesta bark for antipyretic, anti-inflammatory, analgesic, antidepressant and anticoagulant activities in Sprague Dawley rats. Pak. J. Pharm. Sci. 2020, 33, 1015–1023. [Google Scholar]
  124. Dashtdar, M.; Dashtdar, M.R.; Dashtdar, B.; Khan, S.A. In-vitro, anti-bacterial activities of aqueous extracts of Acacia catechu (LF) Willd, Castanea sativa, Ephedra sinica stapf and shilajita mumiyo against Gram positive and Gram negative bacteria. J. Pharmacopunct. 2013, 16, 15. [Google Scholar] [CrossRef]
  125. Patel, J.D.; Kumar, V.; Bhatt, S.A. Antimicrobial screening and phytochemical analysis of the resin part of Acacia catechu. Pharm. Biol. 2009, 47, 34–37. [Google Scholar] [CrossRef]
  126. Joshi, S.; Subedi, Y.P.; Paudel, S.K. Antibacterial and antifungal activity of heartwood of Acacia catechu of Nepal. J. Nepal Chem. Soc. 2011, 27, 94–99. [Google Scholar] [CrossRef] [Green Version]
  127. Joshi, S.G.; Shettar, L.G.; Agnihotri, P.S.; Acharya, A.; Thakur, S.L. Solanum xanthocarpum and Acacia catechu Willd-an ayurvedic soothe: A randomized clinical trial. J. Ayurvedic Herb. Med. 2021, 7, 1–4. [Google Scholar] [CrossRef]
  128. Amoussa, A.M.O.; Sanni, A.; Lagnika, L. Chemical diversity and pharmacological properties of genus Acacia. Asian J. Appl. Sci. 2020, 13, 40–59. [Google Scholar]
  129. Abbas, G.; Saqib, M.; Akhtar, J.; Murtaza, G. Physiological and biochemical characterization of Acacia stenophylla and Acacia albida exposed to salinity under hydroponic conditions. Can. J. For. Res. 2017, 47, 1293–1301. [Google Scholar] [CrossRef] [Green Version]
  130. Kalaivani, T.; Mathew, L. Free radical scavenging activity from leaves of Acacia nilotica (L.) Wild. ex Delile, an Indian medicinal tree. Food Chem. Toxicol. 2010, 48, 298–305. [Google Scholar] [CrossRef]
  131. Aryal, B.; Niraula, P.; Khadayat, K.; Adhikari, B.; Chhetri, D.K.; Sapkota, B.K.; Bhattarai, B.R.; Aryal, N.; Parajuli, N. Antidiabetic, antimicrobial, and molecular profiling of selected medicinal plants. Evid.-Based Complement. Altern. Med. 2021, 2021, 5510099. [Google Scholar] [CrossRef]
  132. Patil, A.; Modak, M. Comparative evaluation of oxidative stress modulating and DNA protective activities of aqueous and methanolic extracts of Acacia catechu. Medicines 2017, 4, 65. [Google Scholar] [CrossRef]
  133. Anderson, D. Chemotaxonomic Aspects of the Chemistry of Acacia Gum Exudates. Kew Bull. 1978, 32, 529–536. [Google Scholar] [CrossRef]
  134. Ghosh, M.; Babu, S.; Sukul, N.; Mahato, S. Antifilarial effect of two triterpenoid saponins isolated from Acacia auriculiformis. Indian J. Exp. Biol. 1993, 31, 604–606. [Google Scholar]
  135. Behera, D.R.; Bhatnagar, S. In-vitro and in silico efficacy of isolated alkaloid compounds from Rauvolfia tetraphylla L. against bovine filarial parasite Setaria cervi: A drug discovery approach. J. Parasit. Dis. 2019, 43, 103–112. [Google Scholar] [CrossRef]
  136. Ghosh, N.; Babu, S.S.; Sukul, N.; Ito, A. Cestocidal activity of Acacia auriculiformis. J. Helminthol. 1996, 70, 171–172. [Google Scholar] [CrossRef]
  137. Okokon, J.; Jackson, O.; Opara, K.; Emmanuel, E. In vivo antimalarial activity of ethanolic leaf extract of Acacia auriculiformis. Int. J. Drug. Dev. Res. 2010, 2, 482–487. [Google Scholar]
  138. Singh, K.; Chandra, V.; Barthwal, K. Letter to the editor: Hypoglycaemic activity of Acacia arabica, Acacia benthami and Acacia modesta leguminous seed diets in normal young albino rats. Indian J. Physiol. Pharmacol. 1975, 19, 167. [Google Scholar]
  139. Khadayat, K.; Marasini, B.P.; Gautam, H.; Ghaju, S.; Parajuli, N. Evaluation of the alpha-amylase inhibitory activity of Nepalese medicinal plants used in the treatment of diabetes mellitus. Clin. Phytosci. 2020, 6, 1–8. [Google Scholar] [CrossRef]
  140. Kumar Bhateja, P.; Singh, R. Antidiabetic activity of Acacia tortilis (Forsk.) Hayne ssp. raddiana polysaccharide on streptozotocin-nicotinamide induced diabetic rats. BioMed. Res. Int. 2014, 2014, 572013. [Google Scholar] [CrossRef] [Green Version]
  141. Patil, R.N.; Patil, R.Y.; Ahirwar, B.; Ahirwar, D. Evaluation of antidiabetic and related actions of some Indian medicinal plants in diabetic rats. Asian Pac. J. Trop. Med. 2011, 4, 20–23. [Google Scholar] [CrossRef] [Green Version]
  142. Pandey, B.; Mohan, J. Inhibition of turnip mosaic virus by plant extracts. Indian Phytopathol. 1986, 39, 489–491. [Google Scholar]
  143. Sharma, W.; Trivedi, P. Nemeticial and nematostatic response of aqueous extract of certain plants of semi-arid niche. Curr. Nematol. 1995, 6, 43–53. [Google Scholar]
  144. Ahovègbé, L.Y.J.; Ogwang, P.E.; Peter, E.L.; Mtewa, A.G.; Kasali, F.M.; Tolo, C.U.; Gbenoudon, J.; Weisheit, A.; Pakoyo, K.F. Therapeutic potentials of Vachellia nilotica (L.) extracts in Hepatitis C infection: A review. Sci. Afr. 2021, 13, e00918. [Google Scholar] [CrossRef]
  145. Pradeep, A.; Happy, D.; Garg, G. Short-term clinical effects of commercially available gel containing Acacia arabica: A randomized controlled clinical trial. Aust. Dental J. 2010, 55, 65–69. [Google Scholar] [CrossRef]
  146. Rajvaidhya, S.; Nagori, B.; Singh, G.; Dubey, B.; Desai, P.; Jain, S. A review on Acacia arabica—An Indian medicinal plant. Int. J. Pharm. Sci. Res. 2012, 3, 1995. [Google Scholar]
  147. Rawi, M.H.; Abdullah, A.; Ismail, A.; Sarbini, S.R. Manipulation of Gut Microbiota Using Acacia gum Polysaccharide. ACS Omega 2021, 6, 17782–17797. [Google Scholar] [CrossRef]
  148. Rather, L.J.; Mohammad, F. Acacia nilotica (L.): A review of its traditional uses, phytochemistry, and pharmacology. Sustain. Chem. Pharm. 2015, 2, 12–30. [Google Scholar] [CrossRef]
  149. Sun, X.; Zhang, Y.; Zhou, Y.; Lian, X.; Yan, L.; Pan, T.; Jin, T.; Xie, H.; Liang, Z.; Qiu, W.; et al. NPCDR: Natural product-based drug combination and its disease-specific molecular regulation. Nucleic Acids Res. 2022, 50, 1324–1333. [Google Scholar] [CrossRef]
  150. Izzo, A.A. Interactions between Herbs and Conventional Drugs: Overview of the Clinical Data. Med. Princ. Pract. 2012, 21, 404–428. [Google Scholar] [CrossRef]
  151. Eltayeb, I.B.; Awad, A.I.; Elderbi, M.A.; Shadad, S.A. Effect of gum arabic on the absorption of a single oral dose of amoxicillin in healthy Sudanese volunteers. J. Antimicrob. Chemother. 2004, 54, 577–578. [Google Scholar]
  152. Al-Mohizea, A.M.; Raish, M.; Ahad, A.; Al-Jenoobi, F.I.; Alam, M.A. Pharmacokinetic interaction of Acacia catechu with CYP1A substrate theophylline in rabbits. J. Tradit. Chin. Med. 2015, 35, 588–593. [Google Scholar] [CrossRef]
Table
Table 1. Biochemical components and pharmacological properties of different species of genus Acacia.
Table 1. Biochemical components and pharmacological properties of different species of genus Acacia.
Acacia
Species		Plant Part UsedExtraction SolventsPhytochemicalsPharmaceutical
Action		Reference
Acacia niloticaPods/LeavesMethanol,
Ethanol		PhentolamineAntihypertensive, Antispasmodic, Antimicrobial[9,10]
Acacia modestaWhole plantEthanolSteroids, Tannins, Phenols, Alkaloids, Saponins, Flavonoids, Anthraquinone Anticancer[11]
Acacia hydaspicaBark/twigs/leavesMethanolPolyphenolic Antipyretic,
Anti-inflammatory, Analgesic 		[12]
Acacia confusaHeartwoodEthanolFlavonoids (i.e., 7,3′,4′-trihydroxy-3-methoxyflavone)
Melanoxetin (3,7,8,3′,4′-pentahydroxyflavone)		Anti-inflammatory[13]
Acacia tortilisLeavesEthanolflavan-3-ols galloylCytotoxic,
Anti-inflammatory		[14]
Acacia arabicaLeavesEthanolFlavonoids,
Terpenoids,
Tannins		Abortifacient[15]
Acacia melliferaStem barkMethanol3-(Z)-trans coumaroylbetulin, 3-(E)-cis coumaroylbetulinAntimalarial[15]
Acacia ataxacanthaStem barkHexane, Dichloromethane,
Ethyl acetate Methanol		betulinic acid,
betulinic acid-3-trans-caffeate		Antimicrobial, Antioxidant [16]
AcaciahydaspicaAerial partsMethanolpolyphenol Antioxidant[17]
Acacia plicosepalusWhole plantMethanolloranthin,
quercetin		Antimicrobial [18]
Acacia farnesianaBarksHexane, Chlorofom, Methanolmethyl gallateAntimicrobial [19]
Acacia arabicaLeaves/barkMethanolquercetine 3-O- (4′-O-acetyl)-rhamnopyranosideAntioxidant[20]
Acacia cyanophyllaFlowersEthyl acetatenaringeninAntioxidant[21]
Acacia crassicarpaHeartwoodMethanolquercetin,
5,7,2′,5′-Tetrahydroxyflavone		Antioxidant[22]
Acacia rigidulaLeavesAcetone, Methanol, Acetic acidditerpenes,
tannins		Antimicrobial,
Antioxidant		[23]
AcaciaalbidaLeaves/barkEthanolpolyphenol Antioxidant [24]
Acacia dealbataFlowersEthanolacetylcholinesteraseAntioxidant[25]
Acacia salignaLeaves--myricetin-3-O-α-l-rhamnoside,
quercetin-3-O-α-l-rhamnoside		Antioxidant,
Cytotoxic		[26]
Acacia karroLeavesEthyl acetate,
Chloroform		β-sitosterol,
epigallocatechin		Antilisterial[27]
AcaciaauriculiformisWhole plant/LeavesEthanol,
Hydroethanolic Extract		saponins,
2,4-dinitrophenyl salicylic acid		Antifilarial,
Antidiabetic		[28,29]
Acacia pennatulaPodsMethanol4-nitro-O-phenylenediamineAntioxidant, Antimutagenic[30]
AcaciacatechuLeavesAqueous, Cytotoxic,
Antiviral		[31]
Acacia aromaLeavesEthanol5-diphenyl tetrazolium bromideAntibacterial, Cytotoxic[32]
Table
Table 2. Analytical data of the gum exudates from Acacia trees.
Table 2. Analytical data of the gum exudates from Acacia trees.
Acacia SpeciesMoisture Content (%)Ash
Content (%)		Nitrogen Content (%)Total
Protein (%)		pHMolecular Weight ×106Viscosity
cm3 g−1		Sp. Rot Acid
Equivalent Weight		Glucouronic Acid%References
Acacia nilotica var.
tomentosa		5.800.040.100.624.48--+80.16--[65]
Acacia nilotica---4.7--35+21-21[66]
A. nilotica-2.480.02--2.29.5+108°18909[67]
Acacia senegal var. senegal-3.320.372.4--15.4−31.51153.816.8[68]
Acacia seyal var. seyal-2.430.140.95--11.6+611185.816.4[68]
Acacia senegal var. senegal-4.890.352.34.78-18.9−30162011.89[69]
Acacia seyal var. seyal-4.470.221.45.16-15.5+52118016.34[69]
Acacia nilotica var.
nilotica		10.811.910.020.165.15-10.19+99.171908.3710.18[70]
Acacia senegal var. senegal13.493.270.352.31--14.61−32116115.2[71]
Acacia senegal var. senegal9.763.400.332.164.940.24-−31.75--[68]
Acacia seyal var. seyal9.562.500.634.164.532.01-+48.25--[68]
Acacia mellifera8.353.130.241.614.842.95-+56.00--[68]
Acacia tortilis var. raddiana8.492.051.5510.344.452.06-+86.75--[72]
Acacia catechu13.903.4-04.84.59- −28.17 [73]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Batiha, G.E.-S.; Akhtar, N.; Alsayegh, A.A.; Abusudah, W.F.; Almohmadi, N.H.; Shaheen, H.M.; Singh, T.G.; De Waard, M. Bioactive Compounds, Pharmacological Actions, and Pharmacokinetics of Genus Acacia. Molecules 2022, 27, 7340. https://doi.org/10.3390/molecules27217340

AMA Style

Batiha GE-S, Akhtar N, Alsayegh AA, Abusudah WF, Almohmadi NH, Shaheen HM, Singh TG, De Waard M. Bioactive Compounds, Pharmacological Actions, and Pharmacokinetics of Genus Acacia. Molecules. 2022; 27(21):7340. https://doi.org/10.3390/molecules27217340

Chicago/Turabian Style

Batiha, Gaber El-Saber, Nosheen Akhtar, Abdulrahman A. Alsayegh, Wafaa Fouzi Abusudah, Najlaa Hamed Almohmadi, Hazem M. Shaheen, Thakur Gurjeet Singh, and Michel De Waard. 2022. "Bioactive Compounds, Pharmacological Actions, and Pharmacokinetics of Genus Acacia" Molecules 27, no. 21: 7340. https://doi.org/10.3390/molecules27217340

Article Metrics

Back to TopTop