The Dangers of Exposure to Asbestos

Before it was banned, asbestos was widely used in commercial products. Research suggests that exposure to asbestos can cause cancer and other health problems.

It is impossible to determine if a product contains asbestos by looking at it, and you can't smell or taste it. Asbestos is only detected when the material containing it is broken or drilled.

Chrysotile

At its height, chrysotile was responsible for 99percent of the asbestos made. It was used by many industries, including construction insulation, fireproofing and insulation. If workers are exposed to asbestos, they can develop mesothelioma as well as other asbestos-related illnesses. Fortunately, the use of this dangerous mineral has decreased significantly since mesothelioma awareness began to spread in the 1960's. However, traces of it are still found in products that we use in the present.

Chrysotile is safe to use when you have a thorough safety and handling plan in place. People who handle chrysotile do not exposed to a significant amount of risk at current safe exposure levels. The inhalation of airborne fibres has been strongly associated with lung cancer and lung fibrosis. This has been proven both for the intensity (dose) as well as duration of exposure.

One study that studied a factory that used almost exclusively chrysotile to manufacture friction materials, compared the mortality rates of this factory with national mortality rates. It was discovered that, over the course of 40 years, processing chrysotile asbestos at low levels of exposure there was no significant extra mortality in the factory.

Chrysotile fibres are typically shorter than other forms of asbestos. They can pass through the lungs, and enter the bloodstream. This makes them more prone to causing health effects than fibres with longer lengths.

It is extremely difficult for chrysotile fibers to be a threat to the air or pose any health risk when mixed with cement. Fibre cement products have been extensively used all over the world particularly in buildings like hospitals and schools.

Research has revealed that amphibole asbestos, such as amosite, crocidolite, or crocidolite, is less likely to cause diseases. Amphibole asbestos types have been the primary cause of mesothelioma and various asbestos-related diseases. When chrysotile is mixed in with cement, it creates a strong, flexible building product that can withstand extreme conditions in the weather and other environmental hazards. It is also simple to clean after use. Professionals can safely eliminate asbestos fibres when they have been removed.

Amosite

Asbestos refers to a group of silicate mineral fibrous that are found naturally in specific kinds of rock formations. It is composed of six general groups: serpentine, amphibole as well as tremolite, anthophyllite, and crocidolite (IARC 1973).

Asbestos minerals are composed of long, thin fibres that range in length, ranging from very fine to wide and straight to curled. They can be found in nature as bundles or individual fibrils. Asbestos is also found in a powder form (talc), or mixed with other minerals to make vermiculite or talcum powder. These are widely used as consumer goods, like baby powder, cosmetics, and face powder.

The largest use of asbestos occurred in the early two-thirds of the 20th century in the period when it was employed in insulation, shipbuilding, fireproofing and other construction materials. The majority of occupational exposures were asbestos fibres that were borne in the air, but certain workers were exposed to vermiculite and talc that had been contaminated and also to fragments of asbestos-bearing rocks (ATSDR 2001). Exposures varied by the industry, time frame, and geographic location.

Most of the occupational exposures to asbestos were because of inhalation, but certain workers were exposed through skin contact or through eating contaminated food. Asbestos can only be found in the air due to natural weathering and degrading of products that are contaminated like ceiling and floor tiles automobile brakes and clutches, as well as insulation.

There is evidence emerging that non-commercial amphibole fibres may also be carcinogenic. These fibers aren't weaved like the fibrils that are found in amphibole and serpentine they are loose, flexible, and asbestos lawyer needle-like. These fibres are found in the cliffs and mountains of several countries.

Asbestos can enter the environment in many ways, including as airborne particles. It is also able to leach into soil or water. This can be due to both natural (weathering of asbestos-bearing rock) and anthropogenic sources (disintegration of asbestos-containing wastes and disposal in landfill sites). Asbestos contamination in surface and ground waters is primarily caused by natural weathering. However it can also be caused by humans, such as through milling and mining of asbestos-containing materials, demolition and dispersal, and the removal of contaminated dumping material in landfills (ATSDR 2001). The inhalation of asbestos fibers is the primary cause of illness in people exposed to asbestos at work.

Crocidolite

Inhalation exposure is the most common method of exposure to asbestos fibres. The fibres can penetrate the lungs, causing serious health problems. Mesothelioma as well as asbestosis and other illnesses can be caused by asbestos fibres. The exposure to asbestos fibres could also take place in other ways, like contact with contaminated clothing or building materials. This kind of exposure is particularly dangerous when crocidolite (the blue asbestos form) is involved. Crocidolite fibers are smaller and more fragile and therefore easier to inhale. They can also get deeper into lung tissue. It has been associated with a higher number of mesothelioma cases than any other form of asbestos.

The six major types of asbestos are chrysotile amosite and tremolite. They are epoxiemite, tremol anthophyllite, and actinolite. The most commonly used forms of asbestos are epoxiemite as well as chrysotile which together comprise the majority of commercial asbestos employed. The other four asbestos types aren't as prevalent, but could still be found in older structures. They are not as hazardous as amosite and chrysotile, however they could pose a threat when combined with other asbestos minerals or when mined in close proximity to other mineral deposits, such as vermiculite or talc.

Numerous studies have demonstrated that there is a link between stomach cancer and asbestos case exposure. However the evidence is not conclusive. Some researchers have reported an SMR (standardized mortality ratio) of 1.5 (95 percent range of CI: 0.7-3.6) for all asbestos-related workers as well as an SMR of 1.24 (95 percent CI: 0.76-2.5) for those who work in chrysotile mines and mills.

IARC The IARC, which is the International Agency for Research on Cancer, has classified all forms of asbestos carcinogenic. All forms of asbestos could cause mesothelioma and other health issues, although the risk is dependent on the amount of exposure people are exposed to, the kind of asbestos used and the duration of their exposure and the way in the way it is inhaled or asbestos lawyer consumed. IARC has stated that the best option for people is to avoid all types of asbestos lawyer (Healthndream official). If someone has been exposed to asbestos in the past and suffer from a disease such as mesothelioma or other respiratory conditions, they should seek guidance from their physician or NHS 111.

Amphibole

Amphiboles comprise a variety of minerals that form needle-like or prism-like crystals. They are a type inosilicate mineral composed of double chains of molecules of SiO4. They typically have a monoclinic structure in their crystals however some may have an orthorhombic structure. The general formula of an amphibole is A0-1B2C5T8O22(OH,F)2. The double chains consist of (Si,Al)O4 tetrahedrons that are linked in rings of six. The tetrahedrons are separated each other with octahedral strips.

Amphibole minerals are prevalent in metamorphic and igneous rocks. They are usually dark-colored and tough. Due to their similarity in hardness and color, they could be difficult for some to distinguish from the pyroxenes. They also share a corresponding cut. However, their chemistry allows for many different compositions. The chemical compositions and crystal structures of the different mineral groups in amphibole can be used to determine their composition.

The five types of asbestos in the amphibole class include amosite, anthophyllite and chrysotile as well as crocidolite and actinolite. While the most frequently used asbestos type is chrysotile, each variety has distinct characteristics. The most hazardous type of asbestos, crocidolite is composed of sharp fibers that are easy to inhale into the lungs. Anthophyllite can be found in a brownish or yellowish hue and is made primarily of magnesium and iron. It was previously used in cement and insulation materials.

Amphibole minerals are hard to analyze because they have a complicated chemical structure and a variety of substitutions. Therefore, a thorough analysis of their composition requires special methods. EDS, WDS and XRD are the most common methods for identifying amphiboles. However, these methods only give approximate identifications. These methods, for instance cannot differentiate between magnesio hornblende and hastingsite. In addition, these techniques can not distinguish between ferro-hornblende and pargasite.