Research indicates that even when PM2.5 levels meet safety standards, air can still contain toxic particles harmful to lungs.
Scientists analyzed PM2.5 levels in Shanghai during winter and spring 2025, identifying the chemical makeup of particles.
Metal-containing fine particles (MCFPs), including aluminum, silicon, iron, manganese, and lead, comprised about 80% of metal particles.
Air samples from clean days (PM2.5 concentration under 15 g/m3) were often more toxic to lung cells than polluted days.
Iron-rich MCFPs carrying toxic metals like manganese and lead triggered strong chemical reactions inside cells, damaging DNA.
Most iron-rich particles originated from human activities, especially vehicle emissions and burning coal.
Detailed Insights:
The study used single-particle inductively coupled plasma time-of-flight mass spectrometry to identify the chemical makeup of each particle.
On clean days, oxidative stress in cells was up to 8.1 times higher, and cell death was up to 6.3 times higher, despite lower total particle mass.
Larger mineral particles on days with heavy dust or haze masked the MCFPs, reducing their relative abundance.
The research suggests air-quality monitoring should shift to identifying and controlling specific toxic components like iron-rich MCFPs.
The study highlights that PM2.5 mass alone is an insufficient indicator of air safety due to the presence of hidden toxic particles.
These particles can evade the body’s defenses and persist in organs for years, posing long-term health risks.
Scientific/Technical Concepts Involved:
PM2.5: Fine particulate matter with a diameter of 2.5 micrometers or less, capable of penetrating deep into the lungs and bloodstream.
Oxidative Stress: An imbalance in cells caused by an excess of free radicals, leading to damage to DNA, proteins, and lipids.
Single-particle inductively coupled plasma time-of-flight mass spectrometry: A sensitive analytical technique used to identify the elemental composition of individual particles.