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61,005 resultsShowing papers similar to The impact of environmental microplastics as emerging carcinogens: A public health concern
ClearMicroplastics as emerging carcinogens: from environmental pollutants to oncogenic drivers
This review examines growing evidence that microplastics and nanoplastics may play a role in cancer development, with these particles found in human tumor tissues from the lungs, colon, stomach, breast, and other organs. The particles appear to promote cancer through chronic inflammation, oxidative stress, DNA damage, and disruption of key cancer-related signaling pathways. While direct proof of causation in humans is still lacking, the accumulating evidence from lab studies, animal experiments, and human tissue analysis suggests microplastics deserve serious attention as potential contributors to cancer risk.
Micro(nano)plastics pollution and human health: How plastics can induce carcinogenesis to humans?
This review examines how microplastics and nanoplastics enter the human body through food, water, and air, and how they may contribute to cancer development. Common plastic types like polystyrene and PVC, along with toxic chemicals they carry such as PAHs and PCBs, have been linked to DNA damage, oxidative stress, and inflammation, all of which can promote cancer. The paper highlights that while the evidence is growing, more research is needed to understand the full cancer risk from chronic microplastic exposure.
Microscopic menace: exploring the link between microplastics and cancer pathogenesis
This review examines the growing evidence linking microplastic exposure to cancer development in humans. Microplastics can accumulate in the body and trigger inflammation, oxidative stress, and other biological changes associated with tumor growth. While more clinical research is needed, the review highlights that microplastics should be taken seriously as a potential factor in cancer risk.
From exposure to oncogenesis: a review on the multifaceted roles of microplastics in tumor initiation and progression
This review examined the evidence linking microplastic exposure to tumor initiation and progression, covering physical, chemical, and inflammatory mechanisms by which MPs may promote oncogenesis. The authors conclude that while current evidence is largely preclinical, accumulating data warrant serious concern about microplastics as environmental carcinogens.
The Relationship Between Microplastics and Nanoplastics with Cancer: An Emerging Health Concern
This review explores the emerging relationship between micro- and nanoplastic exposure and cancer risk in humans. Researchers summarized evidence suggesting that microplastics can carry carcinogenic substances and may trigger inflammatory and oxidative stress pathways linked to tumor development. The study highlights that while early evidence raises concern, more research is needed to establish clear causal connections between plastic particle exposure and specific cancer types.
Insights into the potential carcinogenicity of micro- and nano-plastics.
This review examined existing evidence on the carcinogenic potential of micro- and nano-plastics, finding studies demonstrating genotoxicity, oxidative DNA damage, disruption of cell signaling, and tumor-promoting effects, while noting that direct human carcinogenicity data remain limited and mechanistic pathways require further investigation.
Exposure and inhaling of microplastics: An evidence of cause of cancer
This review examined microplastic inhalation as a potential cause of cancer, surveying pathways by which inhaled MP particles accumulate in lung tissue and drive oncogenic processes through inflammation, oxidative damage, and DNA strand breaks. The evidence reviewed supports classifying microplastic inhalation as an emerging environmental cancer risk factor.
Microplastics – A Growing Concern as Carcinogens in Cancer Etiology: Emphasis on Biochemical and Molecular Mechanisms
This review describes how microplastics smaller than 5 mm can enter human cells and promote cancer development through multiple pathways, including DNA damage, oxidative stress, chronic inflammation, and disruption of cell growth controls. Microplastics also carry other contaminants into the body, and their accumulation in tissues raises concerns about long-term cancer risk, particularly in the lungs, skin, and digestive system.
Rising Concern About the Carcinogenetic Role of Micro‐Nanoplastics
This review raised concerns about the carcinogenic potential of micro- and nanoplastics, synthesizing evidence that these particles can induce DNA damage, oxidative stress, and cellular transformation. It called for accelerated research into whether microplastic exposure increases human cancer risk.
Plastic pollution-Microplastics: Cancer related issues
This review examines how microplastics may contribute to cancer risk, summarizing evidence that ingested microplastics can cross the gut epithelium, accumulate in tissues, induce oxidative stress and inflammation, and carry carcinogenic chemical additives.
Do microplastics (MPs) and nanoplastics (NPs) directly contribute to human carcinogenesis?
This review examines whether microplastics and nanoplastics could directly contribute to cancer development in humans. Evidence from lab and animal studies shows these particles can cause DNA damage, chronic inflammation, oxidative stress, and disrupt important cancer-related signaling pathways. While a direct causal link to human cancer has not been proven yet, the review argues that microplastics should be considered potential cancer-promoting agents that warrant urgent further research.
From Exposure to Oncogenesis: the Role of Microplastics and Associated Pollutants in Cancer - a Literature Review
This literature review examined the growing evidence linking microplastic exposure to cancer development. Microplastics have been found in human lung, liver, and colon tissue, and research suggests they may promote cancer through chronic inflammation, oxidative stress, and by carrying known carcinogens like heavy metals and persistent organic pollutants into the body.
Evaluating the relationship between microplastics and nanoplastics contamination and diverse cancer types development
This review examines growing evidence that micro- and nanoplastics found in human tissues may contribute to cancer development through several pathways. These tiny particles can generate harmful molecules called reactive oxygen species, cause chronic inflammation, and disrupt cell growth signals, all of which are known to promote cancer. While long-term, high-level exposure likely poses the greatest risk, more research is needed to understand the full cancer-related dangers of microplastic exposure.
Exposure and inhaling of microplastics: An evidence of cause of cancer
This review examines epidemiological and experimental evidence linking microplastic inhalation and ingestion to cancer risk, covering mechanisms including oxidative stress, inflammation, and genotoxicity from both particles and associated chemical additives. It highlights lung and gastrointestinal cancers as priority areas of concern.
Rising Concern About the Carcinogenetic Role of Micro-Nanoplastics
This review examined the emerging concern that micro- and nanoplastics may play a role in cancer development, either directly or by carrying chemical carcinogens into the body. Researchers noted that while direct evidence is still limited, the rising incidence of certain cancers in younger populations alongside increasing environmental plastic contamination has raised important questions. The study calls for more focused research to understand whether long-term microplastic exposure may contribute to cancer risk and what preventive measures might be warranted.
Microplastics in Early Onset Carcinogenesis
This review examines the emerging hypothesis that chronic microplastic exposure may contribute to cancer risk, noting that these particles provoke oxidative stress, inflammation, DNA damage, and microbiome disruption. Researchers highlight a temporal overlap between rising plastic production since the 1950s and increasing rates of early-onset cancers, though a causal link has not been established. The study suggests that lifelong microplastic exposure beginning in utero warrants further investigation as a potential contributing factor.
The hidden poison - microplastic : Inflammatory catalyst of cancer development
This review discusses how microplastics act as inflammatory agents within biological tissues, summarizing evidence that ingested and inhaled microplastics can trigger oxidative stress, immune responses, and chronic inflammation in humans and animals.
Microplastics and Cancer: A Comprehensive Review of Their Impact on Tumor Progression and Mechanisms of Carcinogenesis
This comprehensive review examines the growing body of evidence linking microplastic exposure to various types of cancer, including colorectal, lung, liver, and breast cancers. Researchers found that microplastics and nanoplastics may promote tumor progression through mechanisms including oxidative stress, chronic inflammation, and disruption of cellular signaling pathways. While the evidence is still emerging, the study highlights the need for further research into the potential cancer-related risks of widespread microplastic exposure.
Exposure and inhaling of microplastics: An evidence of cause of cancer
This review examined the evidence linking microplastic inhalation to cancer risk, covering how inhaled MPs accumulate in the lungs, trigger chronic inflammation, oxidative stress, and DNA damage, and may contribute to lung carcinogenesis. The authors identified microplastic inhalation as an underappreciated occupational and environmental cancer risk.
The micro(nano)plastics perspective: exploring cancer development and therapy
This review explores the emerging link between microplastics and cancer development. Microplastics can trigger chronic inflammation, oxidative stress, and hormone disruption, all of which are known pathways that may promote cancer growth. Interestingly, researchers are also studying whether engineered microplastics could be used as drug carriers for cancer therapy, though long-term effects remain unclear.
The alarming link between environmental microplastics and health hazards with special emphasis on cancer
This review describes how microplastics enter the human body through the nose, skin, and mouth, then penetrate cells where they can alter gene expression, fuel inflammation, disrupt hormone signaling, and promote uncontrolled cell growth. Studies have linked microplastic exposure to cancers of the lungs, blood, breast, prostate, and ovaries, though the precise molecular mechanisms still need further investigation.
Microplastics and cancer
This review examines evidence linking microplastics to cancer risk, noting that microplastics have been detected at higher concentrations in human tumor tissues than adjacent healthy tissue, and that they can act as vectors for carcinogens while inducing oxidative stress, inflammation, and genotoxicity.
Microplastics and Nanoplastics in Cancer Progression: Biology and Public Health
This review examines emerging evidence that microplastics and nanoplastics may contribute to cancer-related processes by crossing biological barriers and accumulating in tissues. The study highlights that these particles can cause oxidative stress, inflammation, DNA damage, and barrier dysfunction at the cellular level, and may promote tumor-supporting processes including angiogenesis and immune evasion.
The hidden threat: Microplastics and cancer biology
This review synthesizes current research on the potential links between micro- and nanoplastic exposure and cancer biology, examining how these particles may contribute to tumor development in organs including the gut, lungs, skin, liver, kidney, and brain. The study suggests that chronic exposure to plastic particles can trigger molecular changes such as oxidative stress, inflammation, and DNA damage that are associated with cancer initiation, though clear causal evidence in humans is still lacking.