TABLE OF CONTENTS
I was never a fan of coffee in years past. This was largely due to some of the negative connotations (often unproven) regarding its consumption and overall good health. However, over the years, it has become a part of my tea or hot beverages lineup in moderate ways.
Coffee belongs to the Rubiaceae family and the genus, Coffea (Eira et al. 2006). This family of plants are known for their effects on the neurological system. This is due to its caffeine property, which is one of the main compounds of coffee, and which serves as a stimulant for the nervous system (Sciencedirect.com; Belitz et al. 2009).
Over Seventy (70) species of coffee belong to the Rubiaceae family. As such, once they produce seeds and resemble coffee beans, they are usually considered coffee trees by botanists (Myhrvold et al. 2024; Britannica.com). However, only two (2) species are widely cultivated for consumption – Arabica (Coffea arabica) and Robusta (Coffea canephora). Coffea arabica is said to be the most consumed species, while Robusta or Coffea canephora, reportedly contains more caffeine and is usually used for blending and the production of instant coffee (Davis et al., 2019.).
However, there still exist many controversies surrounding the drinking of coffee, especially due to its caffeine content. Nonetheless, that negative position of coffee is solely changing to a more positive outlook. This is because continuous research has shown that it possesses numerous health benefits, especially as it relates to heart health. Let’s discuss!
The Discussion
Coffee fruit (berry/cherry) comprises both the smooth and tough outer skin of the coffee fruit/berry. The fruits are usually harvested green but will eventually turn deep red or red-violet when they become ripe (Belitz et al, 2009; Purseglove, 1974). However, internationally, coffee is often traded as green coffee, which is the coffee bean that may or may not have what is called the ‘silver skin’ (Belitz et al, 2009; Purseglove, 1974). The ‘silver skin’ is the part which covers the endosperm of the bean (Belitz et al, 2009, etc.) or a thin layer that covers the coffee seeds when it is inside the coffee berries and is usually removed during the roasting process (Belitz et al, 2009; Purseglove, 1974; Klingel et al. 2020).
Coffee is reportedly consumed by millions of people daily, worldwide. This brewed mixture is considered a functional beverage due to its purported ability to prevent some chronic diseases (Esquivel and Jimenez, 2012). However, the extent of its benefits will be dependent on the composition of the fruits and beans as well as how it is roasted (Belitz et al, 2009; Purseglove, 1974).
Most of the coffee consumed globally reportedly comes from the Coffea arabica (Arabica) species and Coffea Canephora (Robusta) (Patay et al. 2016). Arabica coffee is said to have less caffeine than Robusta and is traded more expensively on the international market due to its more distinct properties (Barone and Roberts, 1996; Bertrand et al. 2003).
When coffee is brewed, it is described as a stimulant, which is due mainly to its caffeine content. However, other compounds have caused it to garner the name of being a functional beverage. Some of the other profound compounds of coffee include its polyphenols (i.e. chlorogenic acid, flavonols and anthocyanidins (George and Ramalakshmi, 2008), anthocyanidins (Ramírez-Coronel et al. 2004) as well as antioxidants, phytonutrients, and key enzymes (Heimbach et al. 2010). Coffee has also been shown to have antiviral activity (Utsunomiya et al. 2008).
These and many other compounds have contributed to the beneficial effects of coffee on the body, such as having a positive effect on the cardiovascular system, diabetes risk, and liver disease risk among others (Nieber, 2017).
Some of the purported nutrients in coffee include niacin (vitamin B3), magnesium, potassium, as well as vitamin E (USDA Nutrient Database, 2004). Additionally, according to the same nutrient database, an 8oz cup of brewed coffee provides about seven (7) mg of magnesium and one hundred and sixteen (116) mg of potassium (http://www.nal.usda.gov/fnic/foodcomp), which can help contribute to our daily intake of these nutrients. Coffee reportedly also has many functional properties such as flavonoids, ferulic acid and caffeic acid (Meletis, 2006). It also possesses antioxidant properties (Rufian-Henares et al 2007, etc.).
In this post, we will be exploring five (5) proven health benefits of consuming coffee as well as its main bioactive compound – caffeine. The five benefits to be discussed are – its effects on the cardiovascular system, diabetes risk, as well as its protective effects on the liver. We will also look at its benefits to the neurological system, especially as it relates to nervous system disorders. The post will also explore some of the reported side effects of consuming coffee.
Five (5) Health Benefits of Consuming Coffee:
- Caffeine Properties
- Cardiovascular Health
- Diabetes Risk
- Liver Health Risk
- Parkinson’s Disease Risk
Coffee and Caffeine Properties
Caffeine is the main and most investigated and controversial compound of coffee. But is it a bad thing? Well, many reports would indicate – No! Caffeine is the main alkaloid that naturally occurs in coffee beans (James, 2004). It accounts for up to four (4%) percent of the dry beans. However, the percentage will vary depending on the agricultural practices (Belitz et al. 2009; Dessalegn et al. 2008 etc.). It is also what contributes to the bitterness of coffee (Farah et al. 2006).
When an individual consumes coffee, it first goes to the stomach and then the small intestines, ending up in the brain and other tissues of the body (Higdon and Frei, 2006). Additionally, because coffee is a stimulant, its consumption may lead to general alertness, stimulation of the central nervous system, rise in blood pressure and increased urination (diuretic) (Carrillo and Benitez, 2000; Belitz et al. 2009; Reich et al. 2008).
Caffeine may also enhance one’s mood, and exercise routine. Reports also purport that it may reduce some of the symptoms associated with Parkinson’s disease (Heckman et al. 2010). Caffeine has also been associated with some negative effects such as causing one to feel drowsy (sleepiness) as well as being addictive (DuFrene and Rubinstein, 2010).
However, most of the controversial side effects of coffee have been associated with high doses of caffeine, which can cause anxiety, restiveness, nervousness, etc. (Daly and Fredholm, 1998). Further, some research purports that long-term consumption may increase one’s risk of cardiovascular disease (Yang et al. 2010). Nonetheless, other studies have denoted otherwise.
High consumption of coffee based on most research, is anywhere from six (6) cups or more per day. However, research has shown that this was not associated with a higher or lower risk of cardiovascular disease (Ding et al. 2014). Additionally, four (4) cups per day were purportedly associated with an increased risk of mortality, but only for persons under fifty-five (55) years old (Liu et al. 2013). Nonetheless, these effects cannot be denoted as definitive due to many purported factors such as brewing methods, individual genetics and even the diet and lifestyle of people in general.
It must be noted that coffee is not the only beverage that contains caffeine. As such, one must be aware of the others which have proliferated our grocery aisles. For example, teas (may have upwards of twenty-eight (28) mg depending on where it is sourced or grown, sodas (soft drinks) may have around forty (40) mg, energy drinks (80 mg), and beverages made with cocoa powder (6 mg) (International Food Information Council Foundation, IFIC review, 2017).
Coffee and Cardiovascular Health
As indicated above, there are mixed reviews as it relates to coffee and cardiovascular disease. However, most research purports that moderate consumption of coffee was associated with positive outcomes for cardiovascular health (Lepper MH. et al. 1963). Several meta-analyses did not support the arguments of coffee consumption and higher incidences or risk of cardiovascular disease. As such, the conclusion then was uncertain (Conti et al. 2007; Mostofsky et al. 2012).
On the other hand, a large study conducted in 2014 by Ding and Colleagues, purported that moderate daily consumption of coffee was associated with a reduced risk of cardiovascular disease (Ding et al. 2014). Moderate consumption of coffee as per this study refers to 3-5 cups per day. Interestingly, consuming more than six (6) cups of coffee per day was neutral, as it did not show a higher or lower risk of cardiovascular disease (Ding et al. 2014). However, a cap was not mentioned as per the upper limit of coffee consumption daily.
Further studies also confirmed the findings of the 2014 findings by Ding and colleagues. These studies did not find any association between heavy coffee consumption and cardiovascular risk (Malerba et al. 2013). However, a study by Liu et al (2013) found that four (4) cups or more per day was more associated with mortality (death), but only for persons under fifty-five (55) years of age.
Nonetheless, the findings of some research remain contradictory, which has prompted researchers to note that no definitive results may be ascertained as several factors must be taken into consideration when it comes to studies of this nature. Factors such as brewing methods and dietary assessment.
Further, research contends that currently, no clinical basis exists for the association between moderate coffee consumption and an increased risk of cardiovascular disease, including incidences of stroke (Kim et al. 2012). To this extent, research purports that caffeine, as well as other compounds of coffee, may have a positive effect on the cardiovascular system, instead of a negative one. Especially, when it is consumed moderately.
Coffee and Diabetes Risk
Research has purported health benefits when it comes to the consumption of coffee and metabolic disorders such as type 2- diabetes. However, like cardiovascular disease risk, which in some research, remains controversial, the same holds for diabetes. This is because some studies have shown an inverse association between coffee consumption and metabolic disorders. An inverse association means, when the value of one variable is high, then the other is low and vis-à-vis.
The major study in 2014 by Ding and colleagues with participants that had type-2 diabetes, showed an inverse relationship between coffee consumption and the risk of type-2 diabetes when compared with no coffee consumption. The number of cups mentioned in this study was six (6) cups per day. The results showed a lower risk of developing type-2 diabetes, even with up to six (6) cups per day. These findings applied to both men and women. However, the findings suggested that coffee had a more protective effect for women, than men. Nonetheless, these findings were based solely on self-reported dietary questionnaires and as such, may have some biases and limitations.
Interestingly, further studies by (Ding et al. 2014) also showed similar results with decaffeinated coffee. This is because it was shown to have the same protective effect where type-2 diabetes was concerned as with caffeinated coffee. These results differ somewhat from those of a European-based study which purported lower incidences of type-2 diabetes for caffeinated coffee than decaffeinated coffee of four (4) or more cups per day ((Floegel et al. 2012).
Therefore, the evidence is profound in these studies for an increase in insulin sensitivity for coffee consumption, whether it be caffeinated or decaffeinated (Loopstra-Masters et al. 2011). The studies also purported that other compounds of coffee, for example, polyphenols, which are high in antioxidants, may also be a contributing factor to the positive effect of coffee consumption and the risk of type-2 diabetes (Bhupathiraju et al. 2013; Ong et. al. 2012). As such, coffee has been mostly shown to have a protective effect against type-2 diabetes, not only due to the caffeine but other active compounds.
Coffee and Liver Health
Coffee consumption may also have a positive effect on the liver, especially in persons suffering from liver diseases such as fibrosis, etc. This was purported by several studies, one major one being a 2016 study by Wadhawan and Colleagues (Wadhawan et al. 2016).
The researchers concluded that the consumption of two (2) or more cups of coffee per day by people with preexisting liver disease, showed a lower incidence of fibrosis and cirrhosis as well as decreased mortality from cirrhosis due to alcohol consumption (Klatsky and Armstrong, 1992; Tverdal and Skurtveit, 2003). It must be noted that this result was also the conclusion for the meta-analysis by Liu et al. (2015), whose study was based on coffee consumption and hepatic fibrosis and cirrhosis.
This was also the findings of other studies which concurred that the consumption of two (2) or more cups of coffee per day was associated with a lower risk of chronic liver disease when compared to people who did not consume coffee (Liu et al. 2013; Shim et al. 2013, etc.). This may be due to the findings that the consumption of coffee was able to reduce the hardening of the liver, which would indicate a reduction in inflammation and fibrosis in persons with nonalcoholic fatty liver disease as well as hepatitis B and C (Hodge et al. 2014).
Hepatitis B and C reportedly cause inflammation of the liver (yalemedicine.org). Further research also showed an inverse association between coffee consumption of more than four (4) cups per day and elevated levels of serum enzymes (Klatsky et al. 2006), especially in persons who were heavy alcoholic drinkers.
However, some researchers have argued that these results may not only be due to the caffeine in coffee but by other compounds, in this case – chlorogenic acid, cafestol and Kahweol (Xu et al. 2014; Shimamoto et al. 2013, etc.). Nonetheless, in the case of liver disease, especially liver fibrosis and cirrhosis, chlorogenic acid, cafestol and kahweol have been highlighted as possible contributors to coffee’s positive effects on the liver.
According to research, chlorogenic acid reportedly has a hepatoprotective (prevent damage) effect on the liver (Wan et al. 2013). In fact, in a study by (Xu et al. 2014), it was found that chlorogenic acid was effective in suppressing induced oxidative stress and thus provides a hepatoprotective effect on the body. The other two (2) highlighted compounds, cafestol and kahweol may also provide a protective effect on certain factors that may cause liver damage (Furtado et al. 2012; Shim et al. 2013).
Additionally, the researchers theorized that these compounds may also play a role in the detoxification and prevention of liver damage. To this extent, consistent research has shown a positive effect between coffee consumption and liver disease. Nonetheless, no concrete evidence has been as to the growth or progression of liver disease/s.
Coffee and Parkinson’s Disease Risk
Parkinson’s disease is a disorder that mainly affects the nervous system. Research has shown that caffeine, not only from coffee but from other sources, has an inverse relationship with the risk of Parkinson’s disease (Hernan et al. 2002). The positive effect of coffee and caffeine consumption was shown for both men and women.
In a study conducted in 2000, it was found that men who did not drink coffee were at a higher risk of developing Parkinson’s disease over the next Twenty-four to Thirty (24 -30) years than those who consume at least three (3) cups (28oz) daily (Ross et al. 2000). However, in another study conducted in 2001, it was found that men who consume at least one cup of coffee regularly were at risk of developing Parkinson’s disease over the next ten (10) years than those who did not (Ascherio et al. 2001).
On the other hand, the risk of developing Parkinson’s disease for women was dependent on if they had estrogen replacement therapy. In that, studies only found an inverse relationship for women who never had postmenopausal estrogen therapy. However, a heightened risk was observed for women who did have this therapy and had drunk at least six (6) cups of coffee per day (Ascherio et al. 2003).
As such, the researchers purport that estrogen may have a modifying effect on caffeine, especially as it relates to the risk of Parkinson’s disease. Therefore, estrogen may work to prevent particular metabolism of caffeine, resulting in a higher risk threshold for post-menopausal women who had used estrogen (Pollock et al. 1999).
How much coffee can I drink daily?
A definite verdict is still out on the number of cups of coffee per day that may have absolute beneficial results, especially when it comes to disease prevention or progression. However, most research has indicated moderate consumption is beneficial. Moderate consumption in most cases was 3 – 5 cups per day. Even up to six (6) cups per day was proven beneficial in some studies.
Moderate consumption apparently may have a positive effect on the cardiovascular system, and diabetes risk among other diseases discussed in this article. Nonetheless, most of these studies did not take factors such as brewing methods, cultivars, and dietary assessments, among others. As such, like with all other foods that may have a positive effect on our health, moderation, remains key.
Precautions and Side Effects of Consuming Coffee
Some research has indicated controversial results as it relates to the mentioned diseases of this post – cardiovascular, liver, diabetes, and Parkinson’s, but not all of them. Further, some persons may benefit more than others when it comes to coffee consumption due to several factors such as gut bacteria, how they metabolize coffee, lifestyle (i.e. physically active or not) and overall diet. Also, there is no definite amount that may prevent or slow the progression of any disease.
Further, the side effects of consuming coffee will vary from person to person. However, not all persons will experience side effects from coffee, especially when consumed moderately. Nonetheless, reports have indicated anxiety, restiveness, nervousness, etc. (Daly and Fredholm, 1998).
Illustrative Summary
Here is an illustrative summary of the Five (5) HEALTH BENEFITS of CONSUMING COFFEE
Let’s Sum Up!
Coffee has been getting some good reviews over the last few years. However, the controversy still exists, especially when it comes to its effects on some diseases, for example, cardiovascular disease, and diabetes, among others.
Nonetheless, research has shown that it may have a protective effect on the cardiovascular system, the liver as well as diabetes. It may also have a positive effect where Parkinson’s disease is concerned, especially in moderate consumption, coupled with a healthy and active lifestyle.
Notably, though, the development of some diseases may far exceed that of even a healthy diet or the consumption of coffee or other foods that may provide profound benefits to the body. This is because other complex scenarios may play a role, such as one’s genetics etc. Nonetheless, the best we can do is practice a healthy diet and seek to incorporate foods that can positively impact our health while removing those that will hinder it. As such, coffee might be a worthwhile addition.
However, in all things, moderation is the key, especially in the case of caffeine consumption, whether it be coffee or other caffeinated beverages.
So, now that we have explored coffee and some of its major compounds, is it a beverage that you consume? How many cups do you consume per day? Share it nuh!
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