Analysis method reveals unknown chemicals in human serum samples

In the past, chemicals like asbestos and lead caused widespread harm before their dangers were fully understood. Today, many unknown chemicals similarly pose potential risks. Recently, Chiba University researchers developed a new analysis method for detecting such chemicals in the human body. By studying blood samples from pregnant women, they identified 106 compounds, including potentially harmful substances like phthalates and parabens. This innovative approach could inform new regulations to better protect public health.

From the 1960s to the 1980s, the use of lead in fuel, paints, and pipes caused widespread contamination. It is estimated that 170 million Americans alive today were exposed to high lead levels as children, which caused significant harm, including a measurable drop in IQ scores. While we now understand the dangers of these chemicals, large sections of the population are still exposed to them. UNICEF reports that about 800 million children globally, nearly half of whom live in South Asia, are still exposed to unsafe levels of lead resulting from the hazardous recycling of lead-acid batteries.

Much like the hidden dangers of lead in the past, many of the chemicals we are exposed to today remain poorly understood, along with their potential long-term health effects. To address this issue, researchers at Chiba University in Japan have recently developed an innovative method to detect unrecognized foreign chemicals in the human body. The study was made available online on 26 October 2024 and was published in the journal Ecotoxicology and Environmental Safety. Led by adjunct researcher Dr. Akifumi Eguchi, the study included contributions from Dr. Chisato Mori, Dr. Kenichi Sakurai, and Dr. Midori Yamamoto from the Center for Preventive Medical Sciences at Chiba University.

“There is a growing need for non-targeted chemical analysis to detect new or previously unrecognized substances that are not covered by current targeted analyses,” says Dr. Eguchi, emphasizing the need for broader analytical approaches.

Non-targeted chemical analysis poses significant challenges owing to the large volume of data involved. Additionally, since chemicals exist in various forms, it is necessary to distinguish between endogenous (those naturally produced by the body) and exogenous (those derived from external sources like air, water, or food) chemicals.

To address this, the proposed method uses advanced statistical techniques, including Principal Component Analysis, regularized Generalized Canonical Correlation Analysis, Uniform Manifold Approximation and Projection, and OPTICS clustering. These approaches reduce data complexity and help reveal patterns and groupings among the chemical compounds present in the samples, providing deeper insights into their origins and potential impacts.

Using this method, the researchers analyzed serum samples from 84 pregnant women at 32 weeks of pregnancy. These samples were then examined using Liquid Chromatography-Quadrupole Time-of-Flight Mass Spectrometry.

The detected chemicals were classified based on their origin using the PubChemLite for Exposomics database, which contains information on over 371,663 chemicals. Endogenous chemicals were identified as those naturally produced by the body and associated with biological pathways, while exogenous chemicals were categorized as substances introduced from external sources such as the environment, diet, or lifestyle.

The researchers identified 106 compounds, of which 51 were endogenous and 55 were exogenous. Most of the exogenous chemicals were found to have been introduced into the body through dietary sources. Additionally, they found compounds associated with possible health risks, such as phthalates, nitrogenous compounds, and parabens. Moreover, some of the chemicals identified were found to impact biological pathways, such as amino acid metabolism, protein and mineral transport, and energy metabolism.

While these findings show a link between chemical exposure and its effects on the body, the researchers emphasize that they do not establish a direct cause-and-effect relationship. Since most of the exogenous chemicals were linked to dietary sources, it remains unclear whether the changes in metabolites are due to the substances themselves or the diet. Despite these limitations, the study offers a new method for identifying chemicals and evaluating their potential effects on human health.

“These findings can contribute to public health improvement through the implementation of chemical regulations and related protective measures,” says Dr. Eguchi.

Just as the realization of dangers associated with lead and asbestos led to significant reform and restrictions on these chemicals, the results of this study could help identify new potentially harmful chemicals, paving the way for better regulations to protect human health.