Scientists evaluate the impact of toxic, endocrine-disrupting
chemicals like bisphenol A and phthalates on liver function and metabolic
homeostasis
Humans
are constantly exposed to harmful endocrine-disrupting chemicals (EDCs),
including phthalates and bisphenol A (BPA) through cosmetics and plastics. Now
scientists from South Korea have demonstrated that EDCs, particularly in
mixture forms, may damage the mammalian liver and cause metabolic diseases.
While mice exposed to these compounds at permissible human exposure limits
suffered minimal effects, their liver function was greatly affected by higher
levels of EDCs because of disruptions in genetic and non-genetic pathways.
We are increasingly being exposed to endocrine-disrupting
chemicals (EDCs) that interfere with the normal functioning of our hormones. Bisphenol
A (BPA) and phthalates, which are widely used in consumer products including
plastics, aluminum cans, pharmaceuticals, and cosmetics, are well-known EDCs.
Since both BPA and phthalates are structurally similar
to steroid hormones that regulate chemical signaling in the body, they are
capable of manipulating and disrupting hormonal functions. The liver, the seat
of energy metabolism and xenobiotic detoxification, is the main target of these
EDCs. The liver converts these EDCs into non-toxic water-soluble metabolites for
excretion via urine. However, this biotransformation process generates reactive
intermediates that accumulate in the liver, causing cell death and organ
failure.
Studies involving animal models and human urine
samples have confirmed the positive correlation between exposure to individual
EDCs and abnormal liver function. However, they fail to consider real-life
scenarios where uncontrolled multi-chemical exposure occurs simultaneously.
To address this issue, Professor Myung-Geol Pang and
his colleagues from Chung-Ang University, Korea investigated the effects of the combined
exposure to BPA and phthalates on liver function and metabolic homeostasis in mice
models. Elaborating on their study’s design, Prof. Pang observes, “We determined the combined effects of multiple EDCs using a real-life risk simulation concept.” Their study was made available online on May 26,
2022 and is to be published on August 15, 2022, in volume 436 of the Journal of Hazardous Materials.
Prof. Pang and his team evaluated the effects of BPA and
an EDC mixture consisting of BPA and seven phthalate compounds on male mice.
They observed that neither BPA alone nor the EDC mixture affected liver
function at the permissible human daily exposure (DE) limits defined by the
Ministry of Food and Drug Safety in Korea. However, significant changes in the liver
were observed when the dose of the EDC mixture was increased to 25, 250, and
2500 times the DE limit, including an increase in the overall weight of the
liver. The study recorded lipid, triglyceride, and cholesterol—forms in which
fat is stored in the body—buildup in the liver in addition to elevated blood
glucose levels with these high levels of EDC exposure. The scientists speculated
that the EDCs induced the expression of key genes involved in glucose
production and transport pathways, which ultimately impacted liver health.
Since EDC exposure is known to alter liver enzymes,
the team examined the levels of blood serum components that are indicative of
liver injury. Increased levels of the enzyme aminotransferase were observed upon
exposure to EDC mixture levels that were over 25 times the recommended DE
level, indicating liver damage. Additionally, an aspartate and alanine
aminotransferase ratio of >1 was also observed, which indicated a higher
risk of non-alcoholic fatty liver disease and the progression of liver fibrosis
owing to an increased deposition of collagen fiber. Moreover, anti-inflammatory
cytokines were found to be aggravated in EDC-exposed mice, which resulted in
steatohepatitis, a condition where excessive fat accumulates in the liver
causing cell death and progression of liver fibrosis. It must be noted here
that the mammalian immune system secretes pro-inflammatory cytokines in
response to hazardous chemicals, such as EDCs, or infections, thereby
contributing to liver inflammation.
Interestingly, markers of oxidative stress and cell
death by apoptosis were also observed to be abundant in the EDC-exposed mice. The
scientists attributed this to the reduced antioxidant capacity of the liver damaged
by the EDCs.
This study is important in that it evaluates the
impact of toxic chemicals in real-life scenario, which is much needed to
underscore and define their permissible levels in consumer products. “Combined EDC exposure may increase overall
EDC ingestion, resulting in significant health consequences,” explains
Prof. Pang. What implications might their findings have? “Our study tried to change the conventional toxicological approach and we
hope it has an enormous impact on regulatory and public health perspectives,”
says Prof. Pang.
Reference
Authors
Title of original paper
Journal |
Md Saidur Rahman, Won-Ki Pang, Shehreen Amjad, Do-Yeal Ryu, Elikanah
Olusayo Adegoke, Yoo-Jin Park, Myung-Geol Pang
Hepatic consequences of a mixture of endocrine-disrupting chemicals in
male mice
Journal of Hazardous Materials |
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DOI
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https://doi.org/10.1016/j.jhazmat.2022.129236
|
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Affiliations |
Department of Animal Science & Technology and BET Research
Institute, Chung-Ang University, Anseong, Gyeonggi-do 17546, Republic of
Korea
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Chung-Ang University
About Chung-Ang University
Chung-Ang University (CAU) is a private comprehensive research university
located in Seoul and Anseong, South Korea, and it is widely regarded as one of
the best universities in Korea. In particular, CAU’s culture and arts programs
are considered the best in Korea. It was established in 1916. The birth of many
disciplines, i.e. pharmacy, business, media, social welfare, arts, etc. began
at CAU in Korea. Its new vision for completing 100 years is becoming “The
Global Creative Leader.” CAU offers undergraduate, postgraduate, and doctoral
programs in law, management, and medicine; it has 16 undergraduate and graduate
schools each. Recently, outstanding research achievements in the field of Biotechnology
& Natural Resource are attracting attention globally.
Website: https://neweng.cau.ac.kr/index.do
About Professor Myung-Geol Pang