Tuesday, July 20, 2010

What are the sources?

Natural sources


• contaminated foods (especially seafoods)

• groundwater (which is used as drinking water)

• Volcanic action

• low-temperature volatilization.

• Organic arsenic compounds such as arsenobetaine, arsenocholine, tetramethylarsonium salts, arsenosugars and arsenic-containing lipids are mainly found in marine organisms although some of these compounds have also been found in terrestrial species

• Natural low-temperature biomethylation

• reduction to arsines releases arsenic into the atmosphere











Man-made sources

• medications

• ore smelting/refining/processing plants, galvanizing, etching and plating processes

• burning of fossil fuels especially in coal-fired power generation plants

• Tailings from or river bottoms near gold mining areas (past or present)

• Agricultural chemicals: Insecticides, rodenticides and fungicides

• Commercial arsenic products which include: sodium arsenite, calcium arsenate, and lead arsenate.

• "Paris green" (cupric acetoarsenite) a wood preservative.

• Burning of vegetation

A global phenomena

Bangladesh is not the only country with arsenic pollution of the groundwater, but pollution is exceptionally widespread around the world.



Many other countries and districts in South East Asia, such as Vietnam, Cambodia, and China have geological environments conducive to generation of high-arsenic groundwater.


Footage of people suffering due to arsenic poisoning in bangledesh

Thursday, July 15, 2010

Portable X-ray Fluorescence

Portable X-ray Fluorescence





Portable X-ray fluorescence has recently been accepted as a field technique to measure arsenic in dry solid samples, such as soil and dried sludge. The main interferents listed in this method were variations in particle size, moisture, and lead co-contamination.

X-ray fluorescence (XRF) is the emission of characteristic "secondary" (or fluorescent) X-rays from a material that has been excited by bombarding with high-energy X-rays or gamma rays. The phenomenon is widely used for elemental analysis and chemical analysis, particularly in the investigation of metals, glass, ceramics and building materials, and for research in geochemistry, forensic science and archaeology.

Advantages:
  • Measuring devices are normally portable

Disadvantages:
  • Detection is only accurate at gram per liter concentrations, which is not suitable for determining low arsenic concentrations typical in drinking water.

Colorimetric Test Kits

Colorimetric Test Kits





Field kits have been used extensively to test for arsenic in groundwater, and in many cases, it is the only assay applied. The current baseline methodology involves a variety of technologies that are all variations of the “Gutzeit” method, developed over 100 years ago. These assays have been applied almost exclusively to water samples, although they may be applied to testing solid waste and soil, using either an acidic extraction or an acidic oxidation digestion of the sample.

The “Gutzeit” method procedures:

1. treat the water sample with a reducing agent that transforms the arsenic compounds present in the water into arsenic trihydride (arsine gas).

2. Arsenic is separated from the sample

3. The arsenic trihydride diffuses out of the sample where it is exposed to a paper impregnated with mercuric bromide.

4. The reaction with the paper produces a highly colored compound.

5. The concentration of the arsenic can be approximated using a calibrated color scale.

Advantages:
  •  inexpensive
  • minimally trained personnel can readily perform it and read the results in the field.

Disadvantage:
  • sulfur, selenium, and tellurium compounds have the potential of interfering with this assay.

Arsenator

The Wagtech Arsenator® system

A quick and portable device avaible in the market to detect concentration of arsenic.



The complete system comes with sufficient reagents and consumables for over 400 tests.

• Low cost digital arsenic testing device

• Fully portable, designed specially for field use

• Immediate results in the field in less than 20 minutes

• Simple, safe and easy to operate

• Gives accurate test results between the critical range of 2µgl (ppb) to 100µgl (ppb)

• Designed in conjunction with Prof. Walter Kosmus and laboratory tested by Imperial College London

• Field tested in conjunction with UNICEF/WHO WAT/SAN monitoring programmes

• Environmentally friendly

Using Bacteria and Plants for Arsenic Detection

Have you all imagine bacteria and plants been used for arsenic detection?Let's take a look at this innovative bio-technology that have been developed.

There is no justification for using biological monitoring where direct physical and chemical methods can achieve comparable results both as quickly and as cheaply. The decision of whether biological monitoring is appropriate or not must depend on the specific aims of, and the resources available for, the particular investigation.


The strengths of biological monitoring lie primarily in the close stimulation of biomonitors with the biological systems under study. Often the biomonitor will be part of that biological system.

Some of the criteria for selecting good biological monitoring species include:

-the organism must be capable of accumulating metals in measurable amounts.

-the organism, or relevant parts of it, must be readily available both in terms of quantity and distribution so that unbiased sampling is possible.

-it should be available throughout the year, or for the whole period of study, with relative ease of collection.

-The organism should show a differential uptake/accumulation which is related to exposure thus allowing either: (a) relative pollution levels to be determined, or (b) the establishment of a more quantitative relationship to deposition rate or air concentrations.

-for assessing airborne contamination, the organism should not be subject to substantial uptake or ingestion of metals from other sources.

-repeatability is essential

-cost of collection and analysis should be acceptable



Bacteria

All cell-based organisms have intricate mechanisms for detoxifying arsenic compounds that involve a wide variety of proteins that chemically modify, transport and extrude the arsenic from the cell. The biological synthesis and activation of these proteins is regulated by the presence of arsenic, often through specific genetic mechanisms. In one commonly employed mechanism, activation of the genes that encode the proteins for arsenic resistance depends on the reversible binding of a regulatory protein to a Deoxyribonucleic acid (DNA) control sequence associated with that gene. When the regulator is bound to the analyte it can switch the gene on to synthesize the required proteins to activate the arsenic detoxification system. Understanding the identity, specificity, and sensitivity of the genetic elements and their corresponding regulatory proteins is key to technologies employing biosensors. When creating an arsenic biosensor, the arsenic-responsive DNA control sequences are linked to an additional gene. This gene, called a reporter gene, produces a protein whose properties can be readily observed: as an enzyme that generates a highly colored material or a fluorescent protein. Using techniques developed from molecular biology, it is possible to develop a microbe that generates a visible signal, usually fluorescing bright yellow, when it comes in contact with arsenic compounds.

Genetically modified microbes were used in another recent study to develop a set of semi-quantitative assays for potable water. The investigators also developed an assay that produced a visible blue color with arsenite concentrations above 8 ppb.



Advantages:

- can detect arsenic down to ppb levels

-good potential for assaying arsenic





Disadvantages:

-apply only to water assays

- limited success rate

- it is not clear whether the microbes are measuring all of the arsenic in a sample or just the bioavailable arsenic.





Plants

However, far less research involving the use of plants to detect arsenic has been conducted than for the use of microbes. A strong research effort involving the study of plants that accumulate and store arsenic, primarily for the remediation of arsenic-contaminated sites, is underway. A recent study demonstrated changes in color pigmentation of two water plants upon exposure to arsenic. This effect requires an incubation period of three days and can be quantified with a series of standards. Although this is a very good “low tech” assay, it requires more study to rule out, for instance, the effect of other stresses, such as nutrient levels or microbial infection, which can generate the same pigment change as arsenic absorption.

In considering plant material for monitoring purposes it is important to reiterate that the size, shape, canopy structure and surface characteristics of the plants or plants organs used together with their degree of exposure will all contribute to the efficiency of particulate capture and retention. A further consideration is the relationship between the surface area and weight of the plant organs concerned because these will affect the expression of the results and may complicate the interpretation and comparison of data.


Advantage:
-its general ubiquity. Only in situations of extreme aerial contamination is vegetation likely to be sufficiently scarce to cause sampling problems.

Disadvantage:

- coloration changes in plant systems may be due to factors other than arsenic detection.

-samples may vary between general herbage of several species to leaves, whole leafy shoots and bark of single species.





A student team from the University of Edinburgh has used genetically engineered bacteria to detect arsenic in water. In combination with a drop of pH indicator (far right), samples turn red (middle) in the presence of arsenic and yellow in its absence.

For more information ,feel free to read up more on : http://www.technologyreview.com/Biotech/18103/


STAY TUNED!~

Wednesday, July 14, 2010

Bio tools to detect asernic level in area

Yo people!Today topic will be : bio tools available to detect/survey the amount of asernic in an area.

How monitoring of arsenic was done?

Monitoring arsenic in ground water should be planned nationally.

1. Random testing of tube wells throughout the country to determine the extent of the problem.

2. Subsequently, blanket testing of all wells in selected districts should follow, to identify each and every contaminated well.

3. Blanket testing programmes could also include other activities that are essential for additional monitoring and management operations, such as

  •  The location of each well using a Geographic Information System (GIS)
  • The diagnosis of arsenicosis patients in the district surveyed
  • The introduction of various water treatment measures in that district.



Blanket testing system



Geographic Information System (GIS)




These large scale monitoring methods have  help to detect the amount of arsenic in the area where further actions can be taken .

Knowledge about arsenic detection

Arsenic is commonly found throughout the environment in a wide array of chemical species that vary in toxicity and mobility. Many of these chemical species can be transformed due to biological activity or other changes in the environment, such as a change in oxidation-reduction potential and pH. This prospect for natural environmental change creates the possibility that a wide variety of arsenic species are constantly transforming at any time.


To determine the potential transformation and risk of arsenic in the environment for remedy decisions, the analysis of environmental samples should include identifying and quantifying both the total quantity of arsenic present and the specific chemical forms present, a procedure known as speciation.

However, speciation by a laboratory is expensive and the sample collection methods to ensure the preservation of in situ conditions are difficult and expensive.

The main species of arsenic found in the environment are the arsenic (III) and arsenic (V) oxyacids. Arsenates, arsenate anions, along with neutral arsenite constitute the main targets for field analytical assays.

In contaminated soils, inorganic arsenate is the predominant species.

In general, the arsenate and other arsenic (V) species are immobilized on geologically available surfaces, usually as iron oxides. Although arsenic (V) compounds are considered a low risk, bacterial and other environmental activities can readily convert them back into more mobile and more toxic forms of arsenic.

Groundwater and soil also contain organoarsenic species. In general organoarsenic compounds are less toxic than their corresponding oxyacids. Although usually found in lower concentrations, under the right conditions, they can be found in very high concentrations. In freshwater lakes, methylated arsenic can make up to 60% of the total arsenic. There are also arsenic sulfur species that constitute a sizable portion of arsenic geology and reducing environments in sediment and in solution. Although all of these species are not as common or currently believed to be as toxic as arsenic oxyacids they constitute a sizable fraction of the naturally occurring arsenic and should be a target in field measurements.

Monday, July 12, 2010

Case study: Bangladesh affected by arsenic

Knowing more about arsenic, we will now look at a case study of Bangladesh to showcase the seriousness of arsenic poisoning to humans’ health.






Picture extracted from: http://www.bdix.net/sdnbd_org/world_env_day/2002/current_issues/arsenic/maps/arsenic.gif

High level of arsenic contamination can be observed in Bangladesh with more than 20 % of the total land contains arsenic of concentration more than 50 μ g/ L as depicted from the picture.

History…

For the past two decades the water from over a million tube-wells has been slowly poisoning Bangladeshi villagers with naturally occurring arsenic. Over 18 million people are drinking this poisoned water daily.

Arsenic is naturally occurring in pyrite bedrock underlying much of West Bengal. The poisoning began to occur as millions of kiloliters of water were being pumped out from deep within underground reservoirs for more water resources. As a result, the water level dropped and exposed the arsenic-bearing pyrite to air leading to oxidisation, a reaction which flushed arsenic into the remaining water, contaminating them with arsenic compounds. This has lead to a large numbers of clean wells to be contaminated and expose more people to arsenic poisoning.



In the 1970’s, villagers in Jampukkur started to notice dark spots spread across their bodies; not knowing exactly what was actually causing it. Until 1993 did the villagers learned that they were drinking arsenic contaminated water with 95% of the village wells being contaminated.

Not only did arsenic take away millions of life in Jampukkur, it has also leaved citizens in tremors and pain. More reports of broken marriage surfaced when husbands send disfigured wives back to their parents for the fear that their wives disfigure is cause by arsenic poisoning. In Jampukkur, literally no young men and women get married at all. People believe that arsenic poison can be passed on from the parent to child, leading to many arsenic poisoned women having problems finding husbands.

Some scientists hypothesize that Bangladesh's problem is caused by local water chemistry. Others suggest it is because of the way vegetation decomposes in the monsoon cycles of wet and dry periods, which affect levels of oxygen in ground water.


And local factors enhance the impact of the poison, including a poor diet and addiction to chewing intoxicating betel palm seeds.

Prevention is the only solution, because there is no satisfactory treatment to arsenic poisoning, say experts.



Pumping water at Bangladesh well





So….do you wish to be the next victim of arsenic? !





Sunday, July 11, 2010

understand whats arsenic and how it affect us

Hi people. =) In this post, we will be sharing with you all some information about arsenic and how it enters our water supply.


SO What’s ARSENIC?



Arsenic is actually a metalloid element that belongs to the nitrogen group.It’s widely distributed in the earth’s crust with only a trace amount in all rock, soil and air. Concentration of arsenic in ground may be higher in certain areas due to weathering and anthropogenic activities such as metal mining, smelting, fossil fuel combustion and pesticide uses.

Arsenic can occurs in crystalline, power, amorphous or vitreous forms.Being toxic in nature, Arsenic is more toxic in its inorganic form than its organic form.It’s invisible, tasteless and odorless when present in water, which put people off guard when they drank water containing arsenic.Lastly, arsenic can be found in more than 200 mineral species.



Health impacts of arsenic in water bodies





Arsenic in drinking water causes bladder, lung and skin cancer, and may cause kidney and liver cancer. Studies have also found that arsenic can harm the central and peripheral nervous systems, as well as heart and blood vessels, and causes serious skin problems. It may also cause birth defects and reproductive problems-National Academy of Sciences.


How arsenic gets into our water bodies?





Arsenic can either enters water supplies through natural deposits in the earth’s crust or from industrial and agricultural pollution. As arsenic is widely used in industry and agriculture processes, this rises the chance of the water bodies been contaminated with arsenic.Beside that, arsenic is also a by product of copper smelting, mining and coal burning.


In the next post we will be discussing further about the impact of arsenic to human, with bangladesh as our case study.

Stay tune!for more intersting knowledge =)!

Sunday, July 4, 2010

Welcome to our blog~!

Welcome to our blog on environmental monitoring and control!

The first topic that we will be discussing will be ARSENIC.

In countries where clean drinking water is scarce, people tend to have a higher exposure to water that are contaminated.One of these contaminents in water bodies is arsenic.

So have youall wonder how arsenic, a naturally-occuring metal in ground enters our water bodies?

Stay tune to our blog to find out more about the impact of arsenic and modern technologies used to detect and monitor arsenic!