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61,005 resultsShowing papers similar to A Review on Polypropylene Microplastics and Respiratory Toxicity
ClearA Review on Polypropylene Microplastics and Respiratory Toxicity
This review of existing research shows that tiny plastic particles from polypropylene (a common plastic used in food containers and clothing) are now found in the air we breathe and even in human lung tissue. When these microplastics get into our lungs, they can cause inflammation and damage that may lead to breathing problems and other health issues. The findings suggest we need to better understand and reduce our exposure to these plastic particles in our daily environment.
Deleterious effects of microplastics and nanoplastics on rodent lungs: a systematic review
This systematic review summarizes research on how inhaled micro- and nanoplastics affect the lungs in animal studies. The findings show these particles can cause lung inflammation, tissue damage, and immune responses, suggesting that breathing in airborne microplastics may pose real risks to respiratory health.
Microplastics inhalation: evidence in human lung tissue
Microplastic particles were found in human lung tissue samples collected during surgery, confirming that people inhale and retain microplastics in pulmonary tissue, with polypropylene and polyethylene terephthalate among the polymers identified, raising concerns about chronic respiratory and inflammatory effects.
Investigation of pulmonary inflammatory responses following intratracheal instillation of and inhalation exposure to polypropylene microplastics
Rats exposed to polypropylene microplastics through both inhalation and direct lung delivery developed inflammatory responses in their lungs, including increased immune cells and tissue changes. Even at relatively low concentrations, the microplastics triggered pulmonary inflammation, supporting concerns that breathing in airborne microplastics could contribute to respiratory health problems in humans.
Microplastics inhalation and their effects on human health: a systematic review
This systematic review examines how breathing in microplastics affects human health. It finds that airborne microplastics can reach the lungs and may trigger inflammation, oxidative stress, and respiratory issues, with workers in textile and plastic industries facing the highest exposure levels.
Respiratory Toxicity of Microplastics: Mechanisms, Clinical Outcomes, and Future Threats
This review summarized the respiratory toxicity of airborne microplastics, covering their sources, the routes by which they penetrate deep into lung tissue, and the range of clinical outcomes from chronic inflammation to potential malignancy. The authors warn that inhalation exposure represents an underappreciated and growing public health threat.
Investigation of Pulmonary Inflammatory Responses Following Intratracheal instillation of and Inhalation exposure to Polypropylene Microplastics
Researchers conducted short-term pulmonary toxicity studies by exposing mice to polypropylene microplastics via intratracheal instillation and inhalation, finding dose-dependent inflammatory responses in lung tissue that confirm inhalation as a significant exposure route of concern.
Breathing plastics: Influence of airborne microplastics on the respiratory microbiome and health of human lungs (Review)
Researchers reviewed evidence showing that inhaled airborne microplastics can physically interact with the microbial community living in human lungs, disrupting its balance and triggering inflammation linked to conditions like asthma and fibrosis. Because microplastic particles have been found in lung tissue and fluid samples, inhalation is now recognized as a significant exposure route with measurable consequences for respiratory health.
Microplastic and plastic pollution: impact on respiratory disease and health
This review pulls together evidence from lab studies, animal experiments, and workplace exposure research showing that inhaled micro- and nanoplastics can affect lung tissue and may contribute to respiratory diseases. However, the authors stress that it remains unclear how much damage occurs at the levels of plastic particles people actually breathe in daily life, highlighting the need for better measurements of real-world exposure.
Micro- and Nanoplastics and Pulmonary Health: The Current State of Research
This review evaluates the effects of micro- and nanoplastics on the respiratory system, noting that human autopsy studies confirm these particles are retained in lung tissue. Researchers examined how inhaled plastic particles may induce respiratory inflammation, oxidative stress, and other pulmonary effects. The study highlights that while airborne microplastics are a growing concern, our understanding of their short- and long-term impacts on lung health remains limited.
Airborne microplastics: A narrative review of potential effects on the human respiratory system
This review consolidates research on airborne microplastics and their potential effects on the human respiratory system. Studies show that inhaled microplastics can deposit in the lungs, trigger inflammation, cause oxidative stress, and lead to cell damage and death. While human exposure evidence is still limited, animal and cell studies suggest that long-term inhalation of airborne microplastics could pose significant risks to lung health.
Airborne microplastics: Consequences to human health?
Researchers reviewed existing evidence on airborne microplastics and their potential effects on human respiratory health. Studies of workers exposed to plastic fibers and particles have documented airway inflammation and breathing difficulties, suggesting that susceptible individuals may face health risks even from environmental concentrations. The paper calls for greater awareness and future research into the health consequences of inhaling microplastic particles.
Polypropylene nanoplastic exposure leads to lung inflammation through p38-mediated NF-κB pathway due to mitochondrial damage
This study found that polypropylene nanoplastics, one of the most common types of plastic particles, can cause lung inflammation by damaging mitochondria (the energy-producing parts of cells) and triggering inflammatory signaling pathways. These findings suggest that breathing in tiny plastic particles could contribute to lung disease through a specific chain of cellular damage.
An assessment of the toxicity of polypropylene microplastics in human derived cells
Researchers assessed the toxicity of polypropylene microplastics on human-derived cell lines and found that the particles triggered inflammatory responses and oxidative stress at concentrations relevant to environmental exposure. The microplastics also affected cell viability and caused measurable changes in immune-related gene expression. The study raises concerns about potential health effects from chronic human exposure to one of the most commonly produced plastic types.
Pulmonary Toxicity of Polystyrene, Polypropylene, and Polyvinyl Chloride Microplastics in Mice
Researchers tested the lung toxicity of three common microplastic types (polystyrene, polypropylene, and polyvinyl chloride) in mice and found that all three caused pulmonary inflammation, but through different mechanisms. Polyvinyl chloride produced the most severe inflammatory response, while polystyrene and polypropylene showed distinct patterns of immune activation. The study suggests that the type of plastic inhaled matters for understanding respiratory health risks from airborne microplastics.
Airborne micro- and nanoplastics: emerging causes of respiratory diseases
This review examines growing evidence that tiny airborne plastic particles can enter the lungs and trigger or worsen respiratory diseases including asthma, chronic obstructive pulmonary disease, and lung inflammation. The smallest nanoplastics are especially concerning because they can penetrate deep into lung tissue and even enter the bloodstream, yet research on airborne plastic health effects significantly lags behind studies on waterborne exposure.
Polystyrene microplastic particles: In vitro pulmonary toxicity assessment
Researchers tested the effects of polystyrene microplastics on human lung cells in the laboratory and found that the particles triggered inflammation and oxidative stress. The microplastics also weakened the protective barrier function of lung tissue by depleting key structural proteins. The study suggests that inhaling microplastics may increase the risk of respiratory problems by damaging the lung's natural defenses.
Plastic and Human Health: A Micro Issue?
This review evaluates the potential human health impacts of microplastic exposure through food and air, drawing on evidence from particle toxicology and related fields. Researchers note that if inhaled or ingested, microplastics could accumulate in tissues and cause localized inflammation, while chemical additives and adsorbed pollutants may leach out and cause additional toxic effects. The paper emphasizes that chronic, long-term exposure is likely the greater concern, though current data on actual human exposure levels remains limited.
Cytotoxicity Assessment of Nanoplastics and Plasticizers Exposure in In Vitro Lung Cell Culture Systems—A Systematic Review
This systematic review evaluates how nanoplastics and plasticizers affect lung cells in laboratory studies. The research found that these tiny plastic particles and their chemical additives can damage respiratory tissue at the cellular level, triggering inflammation and cell death. These findings suggest that breathing in nanoplastics could pose real risks to lung health, though more research is needed to confirm effects in living humans.
Effects of microplastics on allergic airways and potential pathogenesis: a review
This review examines how microplastics, which can enter the body through breathing, eating, and skin contact, may affect allergic airway conditions. Researchers found evidence that microplastics can damage airway lining cells, disrupt the protective barrier of the respiratory tract, and trigger heightened airway reactivity. The study suggests that chronic microplastic exposure may worsen allergic airway inflammation, though more research is needed to fully understand the mechanisms involved.
Microplastics Exposure Impact on Lung Cancer—Literature Review
This review examines the relationship between micro- and nanoplastic exposure and lung cancer development, summarizing evidence that these particles can enter the respiratory system through inhaled air, contaminated food, and other pathways. Researchers found that microplastics may promote inflammatory and oxidative processes in lung tissue that are associated with cancer progression. The study suggests that chronic microplastic exposure warrants consideration as a potential contributing factor in lung cancer research.
Pulmonary toxicity assessment of polypropylene, polystyrene, and polyethylene microplastic fragments in mice
Researchers tested the lung toxicity of three common plastic types -- polypropylene, polystyrene, and polyethylene -- in mice by exposing them to microplastic fragments. The study assessed how these inhaled microplastic particles from everyday plastics affect lung health, which is relevant since humans regularly breathe in airborne microplastics.
Presence of airborne microplastics in human lung tissue
Researchers examined human lung tissue from autopsies and found microplastic particles and fibers in 13 out of 20 samples. The most common plastics were polyethylene and polypropylene, with particles smaller than 5.5 micrometers. This study provides direct evidence that inhaled microplastics accumulate in human lungs, raising concerns about potential long-term effects on respiratory health.
Microplastics, potential threat to patients with lung diseases
This review examines the potential threat that airborne microplastics pose to people with existing lung conditions, noting that these particles have been found in human lung tissue and sputum. Researchers explored possible mechanisms by which inhaled microplastics could worsen lung diseases, including triggering inflammation and oxidative stress. The study highlights significant knowledge gaps and calls for more research into how microplastic inhalation affects respiratory health.