We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Papers
61,005 resultsShowing papers similar to Microplastics as environmental modifiers of lung disease
ClearMicroplastics, 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.
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.
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.
Respiratory Toxicity of Microplastics: Mechanisms, Clinical Outcomes, and Future Threats
This review examined the mechanisms by which inhaled airborne microplastics cause respiratory harm, including inflammation, oxidative stress, fibrosis, and impaired mucociliary clearance. The authors also discuss emerging evidence linking microplastic inhalation to worsening asthma, COPD, and potentially lung cancer.
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.
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.
Micro- and Nanoplastic-Induced Respiratory Disease and Dysfunction: A Scoping Review
A systematic scoping review of 68 studies found that inhaled micro- and nanoplastics are detected in human lung tissue and associated with pulmonary inflammation, fibrosis, and impaired lung function, though most evidence comes from occupational settings and in vitro experiments.
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.
Air Pollution Microplastics with the Potential Risk of Lung Disease: A Systematic Review
This systematic review of 20 studies found that airborne microplastics, present in both indoor and outdoor air, can reach deep into the lungs when inhaled. Their accumulation in lung tissue may cause oxidative stress, inflammation, and damage to the lung's protective lining, raising concerns about respiratory diseases from chronic exposure to plastic-contaminated air.
Microplastics and nanoplastics, emerging pollutants, increased the risk of pulmonary fibrosis in vivo and in vitro: A comparative evaluation of their potential toxicity effects with different polymers and size
Researchers compared the lung toxicity of microplastics and nanoplastics made from polystyrene, polyethylene, and polypropylene in mice and human lung cells. They found that all particle types induced signs of pulmonary fibrosis, inflammation, and tissue remodeling, with polystyrene nanoplastics causing the most severe effects. The study suggests that smaller nanoplastic particles and certain polymer types may pose greater risks to lung health.
Detrimental effects of microplastic exposure on normal and asthmatic pulmonary physiology
Researchers exposed both healthy and asthmatic mice to airborne microplastics and found significant lung inflammation, immune activation, and increased mucus production in both groups. Microplastic particles were taken up by immune cells called macrophages, and gene analysis revealed changes in immune response, cellular stress, and cell death pathways. The study suggests that inhaling microplastics may worsen respiratory health in both normal and vulnerable populations.
A particle of concern: explored and proposed underlying mechanisms of microplastic-induced lung damage and pulmonary fibrosis
This paper explores how inhaled microplastics may cause lung damage and scarring (pulmonary fibrosis) through several biological pathways. The research identifies signaling pathways that could be targeted for future treatments to reduce microplastic-induced lung damage. This is relevant to human health because people regularly breathe in airborne microplastic particles.
Breathing under siege: a narrative review on the potential biological mechanisms linking micro- and nanoplastic exposure to lung diseases
This narrative review examines how inhaled micro- and nanoplastics from indoor and outdoor air — including from synthetic textiles and face masks — can trigger lung inflammation, oxidative stress, and fibrosis, and outlines proposed mechanisms linking plastic inhalation to respiratory disease.
Chronic lung tissue deposition of inhaled polyethylene microplastics may lead to fibrotic lesions
In a mouse study, inhaled polyethylene microplastics accumulated in lung tissue over 90 days of repeated exposure, causing chronic inflammation, immune changes, and early signs of lung scarring (fibrosis). Even at the lowest doses, the microplastics triggered inflammatory cell buildup and thickening of lung walls. These findings suggest that long-term breathing of airborne microplastics could lead to permanent lung damage, which is concerning given rising levels of plastic particles in indoor and outdoor air.
Inhaled microplastics and lung health: Immunopathological effects and disease implications
This review examines the molecular mechanisms by which inhaled microplastics damage lung health, focusing on oxidative stress, inflammation, and immune disruption. Researchers found that microplastics trigger reactive oxygen species production, deplete antioxidants, impair mitochondrial function, and compromise immune defenses in lung tissue. The evidence indicates that microplastics may also act as carriers for other toxic pollutants, amplifying respiratory health risks.
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.
Potential toxicity of micro- and nanoplastics in primary bronchial epithelial cells of patients with chronic obstructive pulmonary disease
Researchers investigated how micro- and nanoplastics affect lung cells taken from patients with chronic obstructive pulmonary disease (COPD), a condition that already impairs breathing. The study aimed to determine whether plastic particle exposure poses additional toxic risk to people whose airways are already compromised.
The Effect of Nanoplastics and Microplastics on Lung Morphology and Physiology: a Systematic Review
This systematic review examines how inhaled microplastics and nanoplastics affect lung structure and function. The research found that indoor microplastic concentrations are often higher than outdoor levels due to household materials shedding fibers, and that inhaled particles can accumulate in different parts of the lungs. These findings suggest that breathing in plastic particles at home and work could contribute to respiratory health problems over time.
Microplastics, as a risk factor in the development of interstitial lung disease- a preliminary study
In the first study to explore a link between microplastics and interstitial lung disease (a group of conditions causing lung scarring), researchers found microplastics in the lung fluid of 55% of suspected patients, with most of those cases involving the fibrotic form of the disease. The most common plastics found were polyamide, polyester, PVC, and polyurethane, suggesting that inhaled microplastics may be a risk factor for serious lung conditions.
Investigation of the presence of microplastics and their clinical significance in patients with exacerbation and stable periods of chronic obstructive pulmonary disease
Researchers examined the presence of microplastics in sputum and bronchoalveolar lavage samples from chronic obstructive pulmonary disease (COPD) patients during exacerbation and stable phases. MPs were detected in a majority of patient samples, and their presence was associated with greater airway inflammation, suggesting inhaled microplastics contribute to COPD pathology.
An emerging role of microplastics in the etiology of lung ground glass nodules
This study proposes a mechanistic link between microplastic inhalation and the development of pulmonary ground glass nodules, reviewing evidence that inhaled microplastics may trigger inflammatory and fibrotic processes in lung tissue.
Pulmonary Fibrosis caused by Asbestos Fibers in the Respiratory Airway
This review discusses how inhaled asbestos fibers cause pulmonary fibrosis by generating reactive oxygen species and inflammation in the lungs. While asbestos is not plastic, the mechanisms of fiber-induced lung damage are relevant to understanding how inhaled plastic microfibers might affect lung health. Both types of fibers can become lodged in lung tissue and trigger chronic inflammatory responses.
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.
Lung hazards of microplastics and their toxicological mechanisms
This review summarizes eight key mechanisms by which microplastics cause lung injury, including oxidative stress, inflammation, DNA damage, and disruption of the immune response. Researchers explain how the small size and large surface area of microplastics allow them to evade respiratory clearance and deposit deep in lung tissue. The study provides a comprehensive framework for understanding how inhaled microplastics may contribute to respiratory health problems.