7. Health benefits conferred by the constituents of Areca nut. Part-IV (Catechins)

 

Catechin is another very important phenolic substance present in areca nut in substantial quantity. Its concentration can range anywhere between 7-25 mg per gram of dry areca nut. The areca nuts of 6-7 months’ maturity were found to contain 24 mg of catechin, compared to the ripened areca nuts of  9-10 months’ maturity (8.51 mg/g) as per one Indonesian report. Interestingly, areca nuts harvested at 5 months maturity in China (Hainan province) for the production of Bing lang had only 7.2 mg per gram of dried areca nut, which is lesser than the matured areca nut.

Catechins are flavanols, which are also called proanthocyanidins or flavan-3-ols. Tea, wine and chocolates are some of the most prominent dietary suppliers of catechins to humans. Red wine, green, black and oolong teas, fruits like plum, apples, peach, strawberry and cherry, and beans and grains like broad bean, lentil and cocoa are rich in catechins. As per one study, Chocolate contributes 20% of the daily catechin intake in the Dutch population, and tea contributes 55%. Mediterranean diets, which are rich in wines and fresh fruits and vegetables, were found high in catechins. Mediterranean diet which is considered as one of the healthiest is found to provide about 100 mg of catechins and procyanidins per person per day.  Total catechin contents of green and black tea are about 420 and 250 mg/L, respectively.  About 12.5 grams of areca nut (Chali or white supari) or about 4 grams of red supari (Kempadike) can provide the equivalent amount of catechin to humans. 

Catechin are found to exhibit physiological effects, including antibacterial, antifungal, antiviral, antioxidative, and antitumor activities. Recent studies have suggested that catechins also promote oral health and contribute to a reduced risk for some systemic disease.

The oral cavity of humans contains more than hundred species of microbes. An increase in the number of these microorganisms like high pathogenic potential species, such as cariogenic and periodontopathic bacteria, and the change of microbial biota may result in, not only oral infection, but also systemic diseases, such as infective endocarditis and aspiration pneumonia. It is very important to control the growth of these microorganisms and its biota just after oral cleaning in order to suppress disease onset. Numerous studies have proved that catechin formulations inhibited the growth of the Actinomyces, periodontopathic bacteria and Candida strains tested, but did not inhibit that of the oral Streptococci that are important in the normal oral flora. Thus, it was clear that catechins can improve the oral hygiene and deter the onset of oral infection, and systemic diseases, such as infective endocarditis and aspiration pneumonia.

Perhaps, the ancient Indian medical practitioners were aware of the importance of catechin present in areca nut and hence had prescribed chewing of Tambula (Betel quid) after every meal.  

References

Tamura & Ochiai (2012) Exploring the possible applications of catechin (gel) for oral care of the elderly and disabled individuals, Japanese Dental Science Review, Vol. 48, pp. 126—134

Yusuf Yilmaz (2006). Novel uses of catechins in foods. Trends in Food Science & Technology, Vol. 17, pp. 64–71

Sari et al., (2020). Distinct phenolic, alkaloid and antioxidant profile in betel quid from four regions of Indonesia, Scientific Reports, Vol. 10 : 16254

Song et al., (2022). UHPLC-MS/MS identification, quantification of flavonoid compounds from Areca catechu L. extracts and in vitro evaluation of antioxidant and key enzyme inhibition properties involved in hyperglycemia and hypertension. Industrial Crops & Products. Vol. 189, pp. 115787.

 

6. Health benefits conferred by the constituents of Areca nut. Part-III (Arecatannins)

 

Tannins are an interesting class of polyphenols, believed to confer numerous health benefits. Tannins are categorized into two classes, namely, hydrolysable tannins and condensed tannins. Areca nut contains mainly condensed tannins which are having at least one monomer as catechin / epicatechin.   

Areca tannin is the main constituent of phenolic compounds found in areca nut. Its concentration can be as high as 40% by weight of the total phenolic content. It is made out of two epicatechin and one catechin molecules and hence categorized under condensed tannin group. 

Due to their complex structure, these tannins exhibit good antioxidant properties. Tannins can exert their function primarily at cellular but also physiological levels, presenting themselves as promising agents for preventing or treating several pathophysiological conditions. They exhibit important effects on cardiac well-being and inflammatory states. In addition, the antioxidant effect could also determine cascading effects that may prevent the growth of cancer cells. Tannins have the unique ability to complex with proteins. The interaction of tannin with proteins is one of the main mechanisms of biological activity of tannins.

Most consumed tannins can reach the colon almost intact, where the high molecular weight structures cannot be readily absorbed and must be further metabolized by the gut microbiota. The gut microbiota depolymerizes the condensed tannins and derivatize them into phenolic acids and valerolactones. Catechin and epicatechin can be readily absorbed in the proximal intestinal tract, while oligomer and polymer absorption rates decrease with increasing number of hydroxyl groups and molecular size.

Numerous research reports are showing that these tannins can help decrease the risk of cardiovascular and Alzheimer’s disease, delay cellular ageing, and maintain intestinal microbiota homeostasis. There are studies on their functions as molecules with pharmacological activity potentials, such as ROS (reactive oxygen species) reducing agent, anti-inflammatory, antifungal, antimicrobial, antiviral, anthelmintic, antimutagenic, and anticancer activities. Considering these health benefits, there is a serious contemplation to include tannins as “Nutraceuticals”.

References.

1.  Moura de Melo et al., (2023). Biological and pharmacological aspects of tannins and potential biotechnological applications, Food Chemistry, Vol. 414, 135645.

2.   Molino et al., (2023). Why is it important to understand the nature and chemistry of tannins to exploit their potential as nutraceuticals? Food Research International Vol. 173, 113329.

3.  Mugeri et al., (2022). Pharmacology and toxicology of tannins. Archives of Toxicology, Vol. 96, 1257–1277.

5. Health benefits conferred by the constituents of Areca nut. Part-II (Procyanidins)

 

B-type procyanidins are found to be one of the most abundant phenolic compounds found in Areca nuts. (–)-epicatechin is the most common monomeric unit of procyanidins. These procyanidins are also present in abundance in Cocoa, apples, grape seeds, and red wine.

These procyanidins have 20 times the antioxidant capacity of vitamin C and 50 times the antioxidant capacity of vitamin E. Procyanidins can neutralize the reactive oxygen species (ROS).

Several processes in our body, such as differentiation, metabolism, proliferation, and apoptosis, are maintained in a normal physiological state by our body’s endogenous antioxidative system. They keep the system in a state of dynamic redox equilibrium. Excessive production of reactive nitrogen species and reactive oxygen species (ROS) causes oxidative stress. Accumulation of ROS can trigger a cascade of reactions that causes direct damage to DNA, lipids, and proteins, ultimately leading to tissue dysfunction. Aside from that, ROS accumulation can contribute to the development of diseases, including cancers, neurodegenerative disorders, cardiovascular diseases, and metabolic disorders.

When the ROS level is low, it is usually advantageous and beneficial for cells and tissues, and normal rate of cell division, tissue repair, and angiogenesis happens without any interruption. Excessive ROS production disrupts multiple biomolecules, which can cause membrane damage. Furthermore, it will inactivate membrane receptors and enzymes, reduce membrane fluidity, increase membrane permeability to ions, and, in extreme cases, rupture the cell membrane and cell lysis leading to the cell death. In addition, lipid peroxides, nitric oxides, and superoxide radicals accumulate in cells and directly damage them by generating unstable radicals and interfering with natural antioxidant molecules and enzymes. Thus, high level of ROS causes apoptosis (programmed cell death), cell damage, DNA mutations, and cell death.

Procyanidin has been shown to prevent oxidative stress-induced DNA damage and promote DNA repair via various pathways. Furthermore, it is discovered that procyanidin could increase the expression and activity of antioxidant enzymes. One of the primary functions of antioxidants is to prevent apoptosis and reduce the level of ROS in cells. Procyanidins effectively does it.  Numerous researches have proved the beneficial effects of consumption of Cocoa, apples, grape seeds, and red wine and their ability to confer antioxidant property to the body. Procyanidins present in them is primarily responsible for the same. Interestingly, areca nut is one of the most abundant sources of procyanidins.

References

1.  Osakabe et al., (2023) Hormetic response to B-type procyanidin ingestion involves stress-related neuromodulation via the gut-brain axis: Preclinical and clinical observations, Frontier in Nutrition, DOI 10.3389/fnut.2022.969823.

2.   Dasiman et al., (2022) A Review of Procyanidin: Updates on Current Bioactivities and Potential Health Benefits, Biointerface Research in Applied Chemistry, Vol. 2 (5), pp. 5918 - 5940

4. Health benefits conferred by the constituents of Areca nut. Part-I (Procyanidins)

 

Areca nut contains a large number of phenolic compounds in substantial quantity. Depending on the stage of maturity they are harvested, and the method of processing, the concentration of phenolic content and type of phenolic compounds can vary. In general, total phenolic content are found to be highest in the areca nuts of 4-5 months maturity and keeps decreasing as it reaches maturity. Flavonoids (flavones, flavanones, flavanols, flavonols), phenolic acids and polyphenols (procyanidins, areca tannins etc.) are some of the important classes of phenolic compounds found in areca nuts. These compounds are responsible for the dark brownish colour in the boiled nuts (Red supari). They impart astringent taste to the nut. They turn red in the presence of lime. Most of the perceived therapeutic properties of areca nut are attributed to these flavonoids, phenolic acids and polyphenols. Almost all of them are highly potent antioxidants.

B-type procyanidins are found to be one of the most abundant phenolic compounds found in Areca nuts. B-type procyanidins can be categorized by their degree of polymerization: monomers form linkages leading to oligomers. The most common monomeric unit is (–)-epicatechin. B-type procyanidins containing 2–7 monomeric units are defined as oligoprocyanidins. They are abundantly available in Red supari (kempadike), produced out of areca nuts of  6-7 months maturity and Bing lang. These procyanidins are also present in abundance in Cocoa, apples, grape seeds, and red wine.

Various conclusive evidence suggests that the intake of foods rich in B-type procyanidins is linked to reduced risk for cardiovascular disease including coronary heart disease, myocardial infarction, and stroke. Randomized controlled trials and subsequent meta-analyses have confirmed that the dark chocolate containing large amounts of B-type procyanidins can mitigate states related to the metabolic syndrome, including hypertension, dyslipidemia (abnormally high levels of fats in the blood) and glucose intolerance. In addition, the latest largescale study found a 27% reduction in cardiovascular death by ingestion of cocoa flavanol fraction, which is rich in B-type procyanidin monomer and oligomers, for 3.6 years. Recent studies have focused on the benefit of B-type procyanidin ingestion for the central nervous system (CNS).

Almost all B-type procyanidins ingested in food move into the colon, and some are degraded by the beneficial bacteria residing in the small intestine. Further it is broken down into low molecular weight phenolic acids in the large intestine (colon). Because of their smaller size, monomeric procyanidins are more absorbable than dimeric procyanidins.

References

1.  Osakabe et al., (2023) Hormetic response to B-type procyanidin ingestion involves stress-related neuromodulation via the gut-brain axis: Preclinical and clinical observations, Frontier in Nutrition, DOI 10.3389/fnut.2022.969823.

2.   Dasiman et al., (2022) A Review of Procyanidin: Updates on Current Bioactivities and Potential Health Benefits, Biointerface Research in Applied Chemistry, Vol. 2 (5), pp. 5918 - 5940

3. Health benefits of Arecoline and Areca extracts as per contemporary research

 

Arecoline is a naturally occurring psychoactive alkaloid found in the pericarp (seeds) of Areca nuts of the areca palm (Areca catechu). Arecoline, arecaidine, guvacine, and guvacoline are the most important and prominent alkaloids found in the areca nut. Nicotine, dichroine, acatechu A, acatechu B, homoarecoline, N-ethyl-1,2,5,6-tetrahydro-1-methyl-3-pyridine carboxamide and arecatemines are some of the minor alkaloids found in areca nuts. Arecoline is found to be the most important alkaloid among all, due to its role in modulating many physiological functions upon human consumption. It is found to enhance alertness and learnability, enhance the mood, gives a feeling of great pleasure, causes awakening, stimulates the sexual desire, reduces anxiety and promote calmness.

Arecoline has a wide spectrum of pharmacological effects beyond Central Nervous System modulating cardiovascular, digestive and endocrine systems as well.  Like nicotine, arecoline also evokes addiction and withdrawal symptoms (upon discontinuation). Withdrawal symptoms could be mood swings, anxiety, irritability and insomnia. Due to its addictive nature and activity on central nervous system, it has become the fourth most commonly used human psychoactive substance after alcohol, nicotine, and caffeine. How arecoline is converted to other forms, and disposed in the human body is complex and poorly understood.

Liu & Chang have listed the therapeutic values of arecoline in their review article “The Controversial Roles of Areca Nut: Medicine or Toxin?” published in International Journal of Molecular Sciences. They concluded that arecoline and areca nut extracts can be used for developing alternate therapy for gastroesophageal reflux disease & can be used to stop the progression of hepatocellular carcinoma cells (liver cancer) and the progression of Alzheimer’s disease, eliminate the negative symptoms of psychosis, can be used as various types of worms (take worm, liver fluke, pin worms etc.). They observed that arecoline possesses anxiolytic-like activity.

Volgin and coworkers have concluded that arecoline and related compounds have a considerable potential in medicine with multiple positive neural effects, in their scientific review published in “ACS Chemical Neuroscience” (An American Chemical Society Journal). They went on to propose that Arecoline can be used effectively in neurology and psychiatry. They opined that further translational research is needed to focus on molecular mechanisms of arecoline pharmacology in both clinical and animal models, and to develop low-risk analogues of this drug for future clinical uses.

References:

Liu & Chang (2023). The Controversial Roles of Areca Nut: Medicine or Toxin?, International Journal of Molecular Science, Vol. 24, 8996.

Volgin et al. (2019). DARK Classics in Chemical Neuroscience: Arecoline, ACS Chemical  Neuroscience, Vol. 10 (5) 2176–2185.

                                                                                 ****