Benefit of cinnamon (Cinnamomum burmannii) in lowering total cholesterol level after consumption of high-fat containing foods in white mice (Mus musculus) models

Introduction

Hypercholesterolemia is a state where the cholesterol level in the body exceeds the normal range. Hypercholesterolemia can increase the risk of atherosclerosis, coronary artery disease, pancreatitis, diabetes mellitus, thyroid disorder, liver disease and renal disease¹.

Data from the Indonesian Ministry of Health in 2019 reported it’s estimated that coronary artery disease to be the first killer, 26.4% of all deaths in Indonesia². Out of the 17 million the premature death (under the age of 70) due to non Communicable disease, most cases are in low-and middle income countries, and 37% are caused coronary heart disease and 6.7 million of these were triggered by stroke (WHO, 2015)³.

In Indonesia, the development of traditional medicine is performed by exploring herbs known to be beneficial for health, and this information is passed from generation to generation. One such herb is such as gambier (Uncaria gambir Roxb.)⁴, which has antioxidant effects and lowers blood glucose when treating type 2 diabetes mellitus. There is also bangun-bangun leaves (Coleus amboinicus), which are believed to be effective in relieving pain when distilled as ethanol and water extract⁵. Traditional medicine that comes from plants is used commonly by many people in Indonesia. One of these medicines is cinnamon (Cinnamomum burmannii,) which is often eaten daily with food. Cinnamon is a native plant in Indonesia and can be found abundantly in Central of Java, (Karanganyar), West Sumatra (Padang), Jambi (Kerinci), etc⁶. Cinnamon has been shown to reduce total cholesterol, low-density lipoprotein and triglyceride levels, as well as increasing high-density lipoprotein levels⁷. Cinnamon is a flavoring ingredient that has been used in daily routines as a spice. Data from various literature on cinnamon reveal that it mainly contains essential oils and important compounds such as cinnamaldehyde, eugenol, cinnamic acid, and cinnamate⁶.

This study was conducted to determine the efficacy of cinnamon in reducing total cholesterol levels of mice (Mus musculus) given high-fat feed. Mice were used in this study because of they have a similar biology to humans, and can therefore be a model for human hyperlipidemia^8–10.

Methods

This is an experimental study in an animal model with a pre-post control study design. This study was conducted at the Pharmacology Laboratory of the Faculty of Medicine, Universitas Sumatera Utara, Indonesia.

Results

Figure 1 shows that groups K0 (negative controls), K1 (positive controls), K2 (CE 2 mg/20gBW), K3 (CE 4 mg/20gBW), and K4 (CE 8 mg/20gBW), had a decrease in total cholesterol levels. There is a significant difference in total cholesterol among the groups (p=0.001 between groups). A post-hoc Bonferroni test was performed to see the difference in total cholesterol averages within each group.

Figure 1. Total cholesterol per treatment group before (day 14) and after (day 28) treatment.

K0, negative control group, no treatment or high-fat food (aquadest); K1, positive control group, diet of high-fat containing food (HFC; quail's yolk); K2, HFC + cinnamon extract (CE) dose 2mg/20g body weight (BW); K3, HFC + CE dose 4mg/20gBW; K4, HFC + CE dose 8mg/20gBW.

It was seen that there was a difference in average total cholesterol levels between K0 (107.5 ± 1.87 mg/dl) vs K1 (120.3 ± 5.53 mg/dl), (p = 0.001). This shows that in the K1 group (positive control) given quail yolk succeeded in increasing cholesterol in mice with a significant difference compared to the K0 group (negative control), which was only given aquadest. In addition, differences in total cholesterol levels in the K1 group (120.3 ± 5.53 mg/dl) compared with K2 (107.3 ± 3.61 mg/dl), K3 (106.8 ± 4.57 mg/dl) and K4 (106.7 ± 0.51 mg/dl) groups showed that a significant decrease in total cholesterol levels (p = 0.001). This proves that CE is efficacious in reducing total cholesterol levels. Between groups K2, K3, and K4, which were all given CE, there was not a significant difference between total cholesterol levels (p > 0.05).

Figure 2 shows that there were increases in BW in all five groups. The largest increase of BW was in group K2, which was the positive control group who were given HFC quail egg yolk at 0.5 ml/20gBW. The smallest increase in BW was found in group K5, which was the group provided with HFC quail egg yolk and CE with the dose of 8 mg/20gBW (highest dose in this study). One-way ANOVA showed that there was no significant difference in BW between groups (p=0.419), which could be inferred that the action of giving CE gave no effect in increasing BW in the mice.

Figure 2. Total body weight per treatment group before (in day 14) and after (in day 28) treatment.

K0, negative control group, no treatment or high-fat food (aquadest); K1, positive control group, diet of high-fat containing food (HFC; quail's yolk); K2, HFC + cinnamon extract (CE) dose 2mg/20g body weight (BW); K3, HFC + CE dose 4mg/20gBW; K4, HFC + CE dose 8mg/20gBW. *Mean delta = (average BW at the end of the study) - (average BW at the beginning of the study)

Discussion

The aim of the study to investigated cholesterol levels was lowered in mice using CE and quail egg yolks for a high-fat diet for 28 days. In this study, it was proven that giving 0.5ml quail egg yolk for 28 days increased the total cholesterol level between the negative and positive control groups (post-hoc Bonferroni K0 vs K1; p=0.001).

There was a significant difference in the decrease of total cholesterol after treatment among all groups in this research. However, this is not consistent with Vanessa et al. (2013) who stated that there was a decrease, but the difference was not statistically significant. Their study was only conducted for 14 days, whereas our study was conducted for 28 days, leading to differing results¹⁴.

Cholesterol is formed by the action of HMG-CoA reductase enzyme (3-hydroxy-3-methylglutaryl-CoA)¹⁵. If hypercholesterolemia is left without implementing proper diet or treatment, it can cause occlusion in a blood vessel. To treat hypercholesterolemia, some medicines, such as simvastatin, could be given¹⁵. The use of statins will competitively block HMG-CoA reductase and efficiently reduce serum LDL cholesterol. But, treatment using simvastatin can cause rhabdomyolysis¹⁶. Thus, it needed research on traditional or herbal medicine, e.g. CE, that needs developed and have minimal adverse effects.

Cinnamon (Cinnamomum burmannii) has cinnamaldehyde as its biggest compound. Cinnamaldehyde, a phenolic component abundantly found in Cinnamomum⁶. Bandara et al. (2011) stated that cinnamon had the ability to be an antioxidant, antivirus, antifungal, antimicrobe, antitumor, and can lower cholesterol and blood pressure with low fat compounds. Cinnamon is believed to have a direct role in lipid metabolism and preventing hypercholesterolemia and hypertriglyceridemia, as well as in preventing free fatty acids with its strong lipolytic activity¹⁷. In the present study we believe that the increase of cholesterol levels due to quail egg yolk could be decreased with cinnamon by its ability to block HMG-CoA reductase enzyme and suppress lipid peroxidation through increased antioxidant enzyme activity¹⁸. In research by Pai et al. (2013), it was stated that cinnamaldehyde could lower cholesterol and triglyceride levels by the action of some enzymes secreted in certain amounts, which might contribute to bile acid synthesis¹⁹.

Our study showed that there was no difference in BW of the mice between groups (p = 0.419). This is not consistent with Vafa et al. (2012) who stated that consuming 3 grams of cinnamon for 8 weeks could decrease some biochemical and anthropometric variables compared to previous states significantly, i.e. a decrease of 1.19% body weight, 1.54% body mass index and 1.36% body fat. In addition to lowering BW variables, it could also decrease fasting blood glucose level by about 9.2%, and 6.12% of HbA1c and 15.38% of triglyceride levels²⁰.

Leaf and Antonio (2017) stated that the higher the food intake, the higher the increase in BW²¹. In the present study, in addition to standard food intake, giving hypercholesterol and interventional food should increase BW, because the mice had increased energy intake. The amount of food intake will affect the amount of energy intake, which will be saved as fat and impact on the mice’s BWs, since energy intake is inversely proportional to physical activity. A high-fat diet group has low sensitivity to leptin, which results in increased appetite and food intake, thus increases the BW²¹. However, this was not the case in our study.

Conclusion

In the present study, a high-fat containing food used in combination with cinnamon extract (Cinnamomum burmannii) for 28 days could decrease total cholesterol levels in mice. Cinnamon extract is believed to have direct effects in lipid metabolism and prevent hypercholesterolemia and hypertriglyceridemia, as well as decreasing free fatty acids by its strong lipolytic activity.

Data availability

Acknowledgments

The author gives appreciation and thanks to the Pharmacology Laboratory of the Faculty of Medicine, Universitas Sumatera Utara for allowing the author to use the facility for collecting data in this research. In addition, thanks to all lecturers and examiners who had given advice and suggestions to the author, and all other parties who had contributed to this research.