Role of the Synergistic Interactions of Environmental Pollutants in the Development of Cancer.
Francisco Alejandro Lagunas-RangelJenni Viivi Linnea-NiemiBłażej KudłakMichael J WilliamsJörgen JönssonHelgi Birgir SchiöthPublished in: GeoHealth (2022)
There is a growing awareness that the large number of environmental pollutants we are exposed to on a daily basis are causing major health problems. Compared to traditional studies that focus on individual pollutants, there are relatively few studies on how pollutants mixtures interact. Several studies have reported a relationship between environmental pollutants and the development of cancer, even when pollutant levels are below toxicity reference values. The possibility of synergistic interactions between different pollutants could explain how even low concentrations can cause major health problems. These intricate that molecular interactions can occur through a wide variety of mechanisms, and our understanding of the physiological effects of mixtures is still limited. The purpose of this paper is to discuss recent reports that address possible synergistic interactions between different types of environmental pollutants that could promote cancer development. Our literature studies suggest that key biological pathways are frequently implicated in such processes. These include increased production of reactive oxygen species, activation by cytochrome P450, and aryl hydrocarbon receptor signaling, among others. We discuss the need to understand individual pathological vulnerability not only in relation to basic genetics and gene expression, but also in terms of measurable exposure to contaminants. We also mention the need for significant improvements in future studies using a multitude of disciplines, such as the development of high-throughput study models, better tools for quantifying pollutants in cancer patients, innovative pharmacological and toxicological studies, and high-efficiency computer analysis, which allow us to analyze the molecular mechanisms of mixtures.
Keyphrases
- heavy metals
- case control
- gene expression
- mental health
- papillary thyroid
- high throughput
- healthcare
- public health
- reactive oxygen species
- high efficiency
- systematic review
- squamous cell
- ionic liquid
- squamous cell carcinoma
- cancer therapy
- climate change
- single cell
- deep learning
- social media
- current status
- single molecule