Team:Edinburgh/Human Practices/Waste Treatment/Metal toxicity

From 2013.igem.org

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==Biotoxicity==
==Biotoxicity==
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Heavy metals have a poisoning effect on the human body by interacting with the normal biochemistry of metabolic processes. They are converted to their stable oxidation state (ion) in the stomach after being ingested and combine with proteins and enzymes etc. to form strong chemical bonds (as shown below).
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Heavy metal cause poisoning effect on human body by interacting with the normal biochemistry in metabolic process. They are converted to their stable oxidation state (ion) in the stomach after ingested and combine with proteins and enzymes etc. to form strong chemical bonds.
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The function of the enzyme is therefore inhibited by the poisoning metal, whereas the protein-metal complex reacts with a metabolic enzyme as a substrate. The reaction scheme below indicates that enzyme (E) and substrate(S) react in either the lock-and-key or the induced fit pattern. In either case, a substrate combines with an enzyme in a highly specific way to form an activated enzyme-substrate complex (ES*).
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[[File:Metals1..png|link=]]
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Figure 1. (A: intramolecular bonds, B: intermolecular bonds, P or E: protein or Enzyme, M:  metal)
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The function of the enzyme is therefore inhibited by the poisoning metal, whereas the protein-metal complex acts as a substrate and reacts with a metabolic enzyme. The reaction scheme below indicates that enzyme (E) and substrate(S) react in either the lock-and-key or the induced fit pattern. In either case, a substrate fits into an enzyme in a highly specific way to form an activated enzyme-substrate complex (ES*).
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<span style="text-align: center">[[File:Metals_equation1..png|link=]]</span>
<span style="text-align: center">[[File:Metals_equation1..png|link=]]</span>
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An enzyme cannot interact with other substrates until it is freed (state E). In a multi-enzyme complex (consisting of 3 or more enzymes), which includes enzymes for an entire sequence, the product from one enzyme reacts with a second one in a chain process. The final enzyme yields the final product as indicated in the equation below.
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An enzyme cannot interact with other substrates until it is freed (state E). In multi-enzyme complex (consisting of 3 or more enzymes) which includes enzymes for an entire sequence, reaction between the product from one enzyme and a second one takes place in a chain process. The final enzyme yields the final product as indicated in the equation below.
<span style="text-align: center">[[File:Metals_equation2..png|link=]]</span>
<span style="text-align: center">[[File:Metals_equation2..png|link=]]</span>
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The final produce F inhibits further actions by reacting with E1 since it does not exist at the beginning of the reaction. Hence, E1 is not able to accommodate any other substrate until F is utilized by the human body. If the body is not capable of utilizing the heavy metal–protein substrate, the related enzyme will be permanently blocked, which then is not able to initiate any bio-reaction or function. Therefore, heavy metals remain in the tissue and results in bio-dysfunctions of varying severity.
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The final produce F inhibits further actions by reacting with E1 since it does not exist at the beginning of the reaction. Hence, E1 is not able to interact with any other substrate until F is utilized by the human body. If the body is not capable of utilizing the heavy metal –protein substrate, the related enzyme will be permanently blocked (F and E1 respectively), which then is not able to initiate any bio-reaction or function. Therefore, heavy metal remains in the tissue and results in bio-dysfunctions of various gravities.
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Moreover, a metal ion can easily replace the metal ion in the body’s metallo-enzyme, if they are of a similar size. For example, Zn2+ in some dehydrogenating enzymes can be conveniently replaced by Cd 2+, leading to Cadmium toxicity. The most toxic form of metals in the most stable oxidation states (Cd 2+ and Pb 2+ etc.). In the most stable oxidation states, they can form very stable biotoxic compounds, which are very difficult to be dissociated from metal-biomolecule compounds.
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Moreover, a metal ion can easily replace the metal ion in the body’s metallo-enzyme, if they have the similar size. For example, Zn2+ in some dehydrogenating enzyme can be conveniently replaced by Cd 2+, leading to Cadmium toxicity. The most toxic form of metals in the most stable oxidation states (Cd 2+ and Pb 2+ etc.). In the most stable oxidation states, they can form very stable biotoxic compound, which is very difficult to be dissociated from metal-biomolecule compound.
== Human exposure ==
== Human exposure ==
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[[File:Metals2..png|link=]]
[[File:Metals2..png|link=]]
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Humans are directly exposed to heavy metals by inhalation of metal dust and gas (Pb), as well as by intake of metal-contaminated water (Cd and Hg).
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Humans are directly exposed to heavy metal by inhalation of metal dust and gas (Pb), as well as intake of metal-contaminated water (Cd and Hg). However, protection from metal dust and contaminated water is not sufficient to avoid exposures to heavy metals.
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Industries including mining, papermaking, leather and electroplating release contaminated water into the environment. Soil is therefore polluted by rain or irrigation water where heavy metals are dissolved. The metals are taken up by plants and accumulate in their tissues. Animals that graze on the contaminated plants or drink from the contaminated water, and any life living in polluted water, also accumulate heavy metal in their bodies. Humans are therefore indirectly exposed to heavy metals by consuming contaminated plants or animals. In summary, all living organisms within a given ecosystem are variously contaminated along their cycles of food chain.
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Industries including mining, papermaking, leather and electroplating etc., release contaminated water to the environment. Soils (including agricultural soil) are therefore polluted by rain or irrigation water where heavy metals are dissolved. The metals are taken up by plants and accumulate in their tissues. Heavy metals will also accumulate in bodies of animals if they are grazed by contaminated plant or raised in water body that are contaminated by metal ions. Humans are therefore indirectly exposed to heavy metals by consuming contaminated plants or animal. In summary, all living organisms within a given ecosystem are contaminated to some extent according to their position in the food chain.
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<h2>Metal poisoning </h2>
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<h3>Metal poisoning </h3>
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<h4> Cadmium </h4>
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<h2> Cadmium </h2>
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According to the final report Heavy Metal in Waste published by Europe Commission in 2002, Cadmium accumulates in human body (especially in kidney) and leads to dysfunction of the kidney with impaired reabsorption of, for example, proteins, glucose and amino acids. Furthermore, skeletal damages (e.g. osteomalacia and osteoporosis etc.) are believed to be a critical effect of cadmium exposure indicated by studies on both humans and animal.  
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According to the report 'Heavy Metal in Waste' published by Europe Commission in 2002, Cadmium accumulates in the human body (especially in the kidney) and leads to dysfunction of the kidney with impaired reabsorption of proteins, glucose and amino acids. Furthermore, skeletal damage (osteomalacia, osteoporosis and spontaneous fractures, increased blood pressure and myocardic dysfunctions) are believed to be a symptom of cadmium exposure indicated by studies on both humans and animal.  
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Other effects of cadmium exposure are disturbances in calcium metabolism, hypercalciuria and formation of renal  
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Other effects of cadmium exposure are disturbances in calcium metabolism, hypercalciuria and formation of renal stones.
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stones.
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The International Agency for Research on Cancer (IARC) classifies cadmium in Class 1. ’The agent (mixture) is carcinogenic to humans. The exposure circumstance entails exposures that are carcinogenic to humans.’  Occupational exposure to cadmium may lead to cancer in the lung or prostate. According to a recent review, the epidemiological data linking cadmium and lung cancer is much stronger than for prostatic cancer, whereas links between cadmium and cancer in the liver, kidney and stomach are not fully studied.
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The most notorious cadmium poisoning case is Itai-itai disease, starting around 1912 in Japan. It was caused by the considerable amount of Cadmium released in the rivers (Jinzu River) by mining companies and a mass population was seriously affected by the disease. People were exposed to cadmium through drinking water, eating contaminated rice and vegetables grown on polluted soil. Those who were affected suffered from osteomalacia (softening of the bones) and osteoporosis (loss of bone mass and weakness). Fractures were more common as the bone weakens. In extremely serious cases, Cadmium poisoning led to death after causing a wide range of damage on human body.
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Also earlier this year (June, 2013), it was reported that rice tainted with Cadmium is discovered in southern China, leading to swell in China rice import. The news indicates that heavy metal contamination (in water and soil) is still an issue in many countries, especially developing countries such India and China, where economic development outweighs environmental protection.
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<h4>Clinical effect of other metal poisoning on humans </h4>
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The most notorious cadmium poisoning case is Itai-itai disease, which started in around 1912. It was caused by the considerable amount of Cadmium released in the Jinzu River by mining companies and the population was seriously affected by the disease. People were exposed to cadmium through drinking water, eating contaminated rice and vegetables grown on polluted soil. Those who were affected experienced bone weakness and fracture. Cadmium poisoning also caused coughing, anemia, and kidney failure, leading to death.
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Also earlier this year (June, 2013), it was reported that rice tainted with Cadmium was discovered in southern China, leading to a swell in China's rice import. The news indicates that heavy metal contamination (in water and soil) is still an issue in many countries, especially developing countries such India and China, where economic development outweighs environmental protection.
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<h2>Clinical effect of other metal poisoning on humans </h2>
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<h3>Drinking water quality guideline</h3>
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<h2>Drinking water quality guidelines</h2>
Access to safe drinking-water is important as a health and development issue at a national, regional and local level. WHO has published a guideline, which includes the provisional maximum concentration of metal ion in drinking water. The following table demonstrates the guideline value for different heavy metal.
Access to safe drinking-water is important as a health and development issue at a national, regional and local level. WHO has published a guideline, which includes the provisional maximum concentration of metal ion in drinking water. The following table demonstrates the guideline value for different heavy metal.
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<h2> References </h2>
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1.European Commission. 2002. Heavy metal in waste. URL: http://ec.europa.eu/environment/waste/studies/pdf/heavy_metalsreport.pdf
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2.Duruibe, J. O., Ogwuegbu, M. O. C. and Egwurugwu, J. N. 2007. Heavy metal pollution and human biotoxic effects. International Journal of Physical Sciences.
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{{Team:Edinburgh/Footer}}
{{Team:Edinburgh/Footer}}

Revision as of 03:42, 5 October 2013

Contents

Metal toxicity

Biotoxicity

Heavy metal cause poisoning effect on human body by interacting with the normal biochemistry in metabolic process. They are converted to their stable oxidation state (ion) in the stomach after ingested and combine with proteins and enzymes etc. to form strong chemical bonds. The function of the enzyme is therefore inhibited by the poisoning metal, whereas the protein-metal complex reacts with a metabolic enzyme as a substrate. The reaction scheme below indicates that enzyme (E) and substrate(S) react in either the lock-and-key or the induced fit pattern. In either case, a substrate combines with an enzyme in a highly specific way to form an activated enzyme-substrate complex (ES*).

Metals equation1..png

An enzyme cannot interact with other substrates until it is freed (state E). In multi-enzyme complex (consisting of 3 or more enzymes) which includes enzymes for an entire sequence, reaction between the product from one enzyme and a second one takes place in a chain process. The final enzyme yields the final product as indicated in the equation below.

Metals equation2..png

The final produce F inhibits further actions by reacting with E1 since it does not exist at the beginning of the reaction. Hence, E1 is not able to interact with any other substrate until F is utilized by the human body. If the body is not capable of utilizing the heavy metal –protein substrate, the related enzyme will be permanently blocked (F and E1 respectively), which then is not able to initiate any bio-reaction or function. Therefore, heavy metal remains in the tissue and results in bio-dysfunctions of various gravities. Moreover, a metal ion can easily replace the metal ion in the body’s metallo-enzyme, if they have the similar size. For example, Zn2+ in some dehydrogenating enzyme can be conveniently replaced by Cd 2+, leading to Cadmium toxicity. The most toxic form of metals in the most stable oxidation states (Cd 2+ and Pb 2+ etc.). In the most stable oxidation states, they can form very stable biotoxic compound, which is very difficult to be dissociated from metal-biomolecule compound.

Human exposure

Metals2..png

Humans are directly exposed to heavy metal by inhalation of metal dust and gas (Pb), as well as intake of metal-contaminated water (Cd and Hg). However, protection from metal dust and contaminated water is not sufficient to avoid exposures to heavy metals.

Industries including mining, papermaking, leather and electroplating etc., release contaminated water to the environment. Soils (including agricultural soil) are therefore polluted by rain or irrigation water where heavy metals are dissolved. The metals are taken up by plants and accumulate in their tissues. Heavy metals will also accumulate in bodies of animals if they are grazed by contaminated plant or raised in water body that are contaminated by metal ions. Humans are therefore indirectly exposed to heavy metals by consuming contaminated plants or animal. In summary, all living organisms within a given ecosystem are contaminated to some extent according to their position in the food chain.

Metal poisoning

Cadmium

According to the final report Heavy Metal in Waste published by Europe Commission in 2002, Cadmium accumulates in human body (especially in kidney) and leads to dysfunction of the kidney with impaired reabsorption of, for example, proteins, glucose and amino acids. Furthermore, skeletal damages (e.g. osteomalacia and osteoporosis etc.) are believed to be a critical effect of cadmium exposure indicated by studies on both humans and animal.

Other effects of cadmium exposure are disturbances in calcium metabolism, hypercalciuria and formation of renal stones.

The most notorious cadmium poisoning case is Itai-itai disease, starting around 1912 in Japan. It was caused by the considerable amount of Cadmium released in the rivers (Jinzu River) by mining companies and a mass population was seriously affected by the disease. People were exposed to cadmium through drinking water, eating contaminated rice and vegetables grown on polluted soil. Those who were affected suffered from osteomalacia (softening of the bones) and osteoporosis (loss of bone mass and weakness). Fractures were more common as the bone weakens. In extremely serious cases, Cadmium poisoning led to death after causing a wide range of damage on human body. Also earlier this year (June, 2013), it was reported that rice tainted with Cadmium is discovered in southern China, leading to swell in China rice import. The news indicates that heavy metal contamination (in water and soil) is still an issue in many countries, especially developing countries such India and China, where economic development outweighs environmental protection.

Clinical effect of other metal poisoning on humans

Cr 1.Irritating respiratory effects, possible circulatory effects, effects on stomach and blood , liver and kidney effects, and increased risk of death from lung cancer

2. Allergic responses (e.g., asthma and dermatitis) in sensitised individuals

Fe 1. aggravates the risks of diabetes, liver cancer, heart disease and arthritis

2. enlarged liver, skin pigmentation, joint diseases, loss of body hair, amenorrhea and impotence

Mn 1. Long-term exposure to excessive level leads to iron-deficiency anemia

2. Increased manganese intake impairs the activity of copper metallo-enzymes 3. Parkinson like symptoms 4. Hypertension in patients more than 40

Pb 1. Biological effects depending on the level and duration of exposure. Effects may range from inhibition of enzymes to the production of marked morphological changes and death

2. Effect on the central nervous system. Epidemiological studies suggest that low level exposure of the foetus and developing child may lead to reprotoxic effects, i.e. damage to the learning capacity and the neuropsychological development 3. Effects on haemoglobin synthesis and anaemia observed in children at lead blood levels above 40 µg/dl 4. Kidney damages

Zn 1. Similar sign of illness as Cr

2. Cause system dysfunctions that result in impairment of growth and reproduction

Drinking water quality guidelines

Access to safe drinking-water is important as a health and development issue at a national, regional and local level. WHO has published a guideline, which includes the provisional maximum concentration of metal ion in drinking water. The following table demonstrates the guideline value for different heavy metal.

Element Guideline value
Cd 0.003mg/litre
Cr 0.05mg/litre
Fe 0.3mg/litre
Mn 0.4mg/litre
Ni 0.07mg/litre
Pb 0.01mg/litre

References

1.European Commission. 2002. Heavy metal in waste. URL: http://ec.europa.eu/environment/waste/studies/pdf/heavy_metalsreport.pdf

2.Duruibe, J. O., Ogwuegbu, M. O. C. and Egwurugwu, J. N. 2007. Heavy metal pollution and human biotoxic effects. International Journal of Physical Sciences.