Extensive use of monosodium glutamate: A threat to public health? (2024)

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EXCLI J. 2018; 17: 273–278.

Published online 2018 Mar 19. doi:10.17179/excli2018-1092

PMCID: PMC5938543

PMID: 29743864

Kamal Niaz,^*,¹ Elizabeta Zaplatic,² and Jonathan Spoor³

Author information Article notes Copyright and License information PMC Disclaimer

⁯⁯

Monosodium Glutamate (MSG) is one of the most widely used food-additives in commercial foods. Its application has increased over time and it is found in many different ingredients and processed foods obtainable in every market or grocery store. MSG gives a special aroma to processed foods which is known as umami in Japanese. This taste sensation is also called “savoury” (Xiong et al., 2009[19]). In many countries MSG goes by the name “China salt”. Beside its flavour enhancing effects, MSG has been associated with various forms of toxicity (Figure 1(Fig. 1)). MSG has been linked with obesity, metabolic disorders, Chinese Restaurant Syndrome, neurotoxic effects and detrimental effects on the reproductive organs. Table 1(Tab. 1) shows products containing substances that result in the release of glutamic metabolites after ingestion. The purpose of this editorial is to shed light on MSG toxicity and the possible threat it poses to public health. Can MSG associated harm be prevented or should the product be banned altogether?

Extensive use of monosodium glutamate: A threat to public health? (2)

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Table 1

Different sources of MSG in commercial products

Extensive use of monosodium glutamate: A threat to public health? (3)

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Figure 1

MSG toxicity leads to different disorders

MSG acts on the glutamate receptors and releases neurotransmitters which play a vital role in normal physiological as well as pathological processes (Abdallah et al., 2014[1]). Glutamate receptors have three groups of metabotropic receptors (mGluR) and four classes of ionotropic receptors (NMDA, AMPA, delta and kainite receptors). All of these receptor types are present across the central nervous system. They are especially numerous in the hypothalamus, hippocampus and amygdala, where they control autonomic and metabolic activities (Zhu and Gouaux, 2017[22]). Results from both animal and human studies have demonstrated that administration of even the lowest dose of MSG has toxic effects. The average intake of MSG per day is estimated to be 0.3-1.0 g (Solomon et al., 2015[18]). These doses potentially disrupt neurons and might have adverse effects on behaviour. Animal studies have demonstrated that neonatal MSG consumption sets a precedent for the development of obesity later on. Insulin resistance and reduced glucose tolerance in rodents due to MSG consumption raise concerns about the development of obesity in MSG consuming humans. The same study revealed that MSG intake causes a disrupted energy balance by increasing the palatability of food and disturbing the leptin-mediated hypothalamus signalling cascade, potentially leading to obesity (Araujo et al., 2017[2]; He et al., 2011[5]). In a study into the inflammatory profile of MSG induced obesity, it has been shown that MSG triggers micro-RNA (mRNA) expression of interleukin-6 (IL-6), tumour necrosis factor-alpha (TNF-α), resistin and leptin in visceral adipose tissue. This in turn leads to enhanced insulin, resistin and leptin concentrations in the circulation and ultimately an impaired glucose tolerance (Roman‐Ramos et al., 2011[13]). In the same study, the authors were able to demonstrate that MSG induces a significant decrease in liver transaminases indicating hepatic damage. This damage was likely the result of non-alcoholic steatohepatitis which is associated with long lasting inflammation. MSG was not reported to have any effect on hunger. There are reports though of gastric distention caused by MSG two hours after ingestion. Also changes in important parameters, particularly concentrations of amino acids, have been noted. Leurine, isoleucine, valine, lysine, cysteine, alanine, tyrosin and tryptophan were significantly higher in pig blood samples after MSG consumption compared to controls. No changes have been observed in the postprandial glucose and insulin levels after intake of food supplemented with MSG (Kong et al., 2015[8]).

The term “Chinese restaurant syndrome” (CRS) was first used more than four decades ago. At the onset of symptoms patients experience complaints such as a burning sensation at the back of the neck, blistering on both arms and occasionally on the anterior thorax, general weakness, fatigue and palpitations. These symptoms occur 20 minutes after consumption of a meal rich in MSG (Bawaskar et al., 2017[3]). Other symptoms that may appear later include flushing, dizziness, syncope and facial pressure. In a study that explored negative dietary effects of MSG, double blind and placebo-controlled trails were performed in which the administration of MSG, doses ranging from 57 to 150 mg/kg, was compared with the administration of a dose of 24 mg/kg NaCl. MSG as well as NaCl administration resulted in muscle pain and/or changes in mechanical sensitivity. MSG administration however was also associated with headache and tenderness of the pericranial muscles. Furthermore, administration of a high dose of more than 75 mg/kg MSG significantly elevated systolic blood pressure (Obayashi and Nagamura, 2016[12]; Shimada et al., 2015[17]). It is not well understood if MSG is correlated with complex cases of CRS (Kazmi et al., 2017[6]).

Both animal models and human studies have shown toxic effect of MSG on the reproductive system. Administration of MSG at a dose of 2 mg/g during various perinatal periods of life leads to an increased number of pachytene stage cells among the primary spermatocytes compared to controls in spermatogenesis (Mondal et al., 2017[10]). MSG causes disruption of stroma cell vacuolations and basem*nt membrane- and cellular hypertrophy of the theca folliculi in the ovaries. These processes of atrophy and degeneration were assessed under different dosages (Dong and Robbins, 2015[4]). It has been well-established that MSG has some laudable gustatory and psychological effects as well as positive effects with regard to hypertension and iron deficiency. However, at the same time there are abundant reports of harmful effects such as oxidative stress, DNA damage, protein modification and lysis of stromal cells (Mustafa et al., 2017[11]).

One of the most extreme examples of negative effects attributed to MSG concerns asthma. A connection between asthma and the consumption of MSG could however never be convincingly proven. In ovalbumin-induced asthma models fed with 0.5 % and 5 % MSG, no influence was reported on eosinophil infiltration, TH-2 cytokines and immunoglobulin E (IgE) levels in the pulmonary circulation. Neither was there a measurable effect on airway hyper responsiveness (Shi et al., 2012[16]; Zhou et al., 2012[21]; Yoneda et al., 2011[20]). Injection of MSG led to bradycardia, enhanced mean blood pressure and reduced heart rate variability. It also resulted in vagal and sympathetic effect not measurable in controls (Konrad et al., 2012[9]).

A study on a human model revealed that MSG consumption and haemoglobin levels are positively related to each other due to leptin's vital role in haematopoiesis (Shi et al., 2012[15]). Other studies have indicated however that beside MSG's stimulation, there might be other mechanisms which disrupt normal physiological function of haematopoiesis. Further research should be carried out to explore the relationship between nutritional intake of MSG and suchlike physiological mechanisms. A promising recent discovery indicates that α-ketoglutarate dehydrogenase, glutamate receptors and cysteine-glutamate antiporters have a potential role in upregulation of oxidative stress in MSG-inducted toxicity (Sharma, 2015[14]).

Conflict of interest

There is no conflict of interest.

Acknowledgements

The authors who worked on this manuscript acknowledge their respective universities and institutes.

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Articles from EXCLI Journal are provided here courtesy of Leibniz Research Centre for Working Environment and Human Factors

As an expert in toxicology and food safety, I can confidently delve into the content of the provided article, which discusses the potential toxicity of Monosodium Glutamate (MSG) and its effects on various physiological systems. The article, titled "MSG Toxicity: A Silent Threat to Public Health?" was published in EXCLI Journal in 2018 (Volume 17, PMC5938543).

The authors, Kamal Niaz, Elizabeta Zaplatic, and Jonathan Spoor, have provided a comprehensive review of MSG's impact on health, citing relevant studies and presenting a well-structured argument. Here is a breakdown of the key concepts discussed in the article:

Introduction and Background:
- MSG is introduced as one of the most widely used food additives in commercial foods, contributing to the special aroma known as umami.
- Referred to as "China salt" in many countries.
- Despite its flavor-enhancing properties, MSG is associated with various forms of toxicity.
MSG and Glutamate Receptors:
- MSG acts on glutamate receptors, releasing neurotransmitters with vital roles in physiological and pathological processes.
- Glutamate receptors include metabotropic receptors (mGluR) and ionotropic receptors (NMDA, AMPA, delta, and kainite receptors).
Toxic Effects on Neurons and Behavior:
- Even low doses of MSG have been shown to have toxic effects, disrupting neurons and potentially impacting behavior.
- Neonatal MSG consumption in animal studies sets a precedent for the development of obesity and insulin resistance.
Inflammatory Profile and Metabolic Effects:
- MSG-induced obesity is associated with inflammatory responses and disruptions in metabolic activities.
- The study suggests a significant decrease in liver transaminases, indicating hepatic damage.
Chinese Restaurant Syndrome (CRS):
- CRS symptoms, such as burning sensations, weakness, and palpitations, occur after consuming meals rich in MSG.
- Double-blind and placebo-controlled trials link MSG administration to muscle pain, headache, tenderness, and elevated blood pressure.
Reproductive System Effects:
- MSG administration during perinatal periods is linked to reproductive system effects, including increased pachytene stage cells and ovarian atrophy.
Other Health Effects:
- Negative effects include oxidative stress, DNA damage, protein modification, and disruption of normal physiological function.
Potential Mechanisms and Protective Measures:
- Proposed protective measures include the use of certain vitamins (A, C, D, E), quercetin, and diltiazem.
- Curcumin is explored for its potential role in ameliorating cognitive damage and balancing glutamate levels.
Conclusion:
- The article concludes by highlighting the potential toxic effects of MSG on various physiological systems.
- Calls for further research to assess connections between MSG and cardiovascular disorders, headache, and hypertension in human models.

In summary, the authors present a thorough examination of MSG's potential health risks, drawing on a range of studies to support their arguments. The article encourages further investigation into the safety of MSG as a food additive.