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Chemicals

Most toxic effects are initiated by chemical interactions in which a foreign chemical or physical agent interferes with or damages normal chemicals of the body. This interaction results in a body chemical being unable to carry out its function in maintaining homeostasis.

There are many ways this can happen; for example:

Interference with absorption or disposition of an essential nutrient.
Interference with nerve transmission (seeNeurotoxicity).
Damage to a cell organelle preventing its functioning (see Cell Damage and Tissue Repair).

Types of Physiological Chemicals
There are three categories of chemicals normally functioning in the body:

Elements— substances made up of only one atom; for example:
- Hydrogen
- Calcium
- Singlet oxygen (O)
Inorganic compounds— simple molecules that usually consist of one or two different elements; for example:
- Water (H2O) - N.B - written with 2 as a subscript
- Carbon dioxide (CO2) - N.B - written with 2 as a subscript
- Bimolecular oxygen (O2) - N.B - written with 2 as a subscript
- Sodium chloride (NaCl)
Organic compounds— substances that contain covalently-bonded carbon and hydrogen and often other elements; for example:
- Sugars
- Lipids
- Amino acids
- Proteins

Elements
Elementsare components of all chemical compounds. Of the 92 naturally occurring elements, only 20 are normally found in the body. Seven of these, carbon, oxygen, hydrogen, calcium, nitrogen, phosphorous, and sulfur make up approximately 99% of the human body weight. In most cases, the elements are components of inorganic or organic compounds. However, in a few cases the actual elements may enter into chemical reactions in the body, such as oxygen during cell respiration, sodium in neurotransmission, and arsenic and lead in impaired mitochondrial metabolism.

Inorganic Compounds
Inorganic compoundsare important in the body and responsible for many simple functions. The major inorganic compounds are water (H2O), bimolecular oxygen (O2), carbon dioxide (CO2), and some acids, bases, and salts. The body is composed of 60–75% water. Oxygen is required by all cells for cellular metabolism and circulating blood must be well oxygenated for maintenance of life. Carbon dioxide is a waste product of cells and must be eliminated or a serious change in pH can occur, known as acidosis. A balance in acids, bases, and salts must be maintained to assure homeostasis of blood pH and electrolyte balance.

Organic Compounds
Organic compoundsare involved in nearly all biochemical activities related to normal cellular metabolism and function. The mechanisms by which xenobiotics cause cellular and biochemical toxicity are predominantly related to changes to organic compounds. The main feature that differentiates organic compounds from inorganic compounds is that organic compounds always contain carbon. Most organic compounds are also relatively large molecules. There are five major categories of organic compounds involved in normal physiology of the body:

Carbohydrates
Lipids
Proteins
Nucleic acids
High-energy compounds

Figure 1. Organic compounds are involved in numerous structures and functions of biochemical processes in the body
(Image Source: NLM)

Carbohydrates
Mostcarbohydratesserve as sources of energy for the body. They are converted to glucose, which in turn is used by the cells in cellular respiration. Other carbohydrates become incorporated as structural components of genetic macromolecules.

For example, deoxyribose is part of DNA, the genetic material of chromosomes, and ribose is part of RNA, which regulates protein synthesis.

Lipids
Lipidsare essential substances of all cells and serve as a major energy reserve. They may be stored as fatty acids or as triglycerides. Other types of lipids are the steroids and phospholipids.

Cholesterol is a lipid that is a component of cell membranes and is used to produce sex hormones such as testosterone and estrogen.
Phospholipids serve as the main components of the phospholipid bilayer cell membrane.

Proteins
The most diverse and abundant of organic compounds in the body is the group ofproteins. There are about 100,000 different kinds of proteins, which account for about 20% of the body weight. The building blocks for proteins are the 20 amino acids, which contain carbon, hydrogen, oxygen, nitrogen, and sometimes sulfur. Most protein molecules are large and consist of 50–1000 amino acids bonded together in a very precise structural arrangement. Even the slightest change in the protein molecule alters its function.

Proteinsperform a large variety of important functions. Some proteins have a structural function such as the protein pores in cell membranes, keratin in skin and hair, collagen in ligaments and tendons, and myosin in muscles.

Hemoglobin and albumin are proteins that carry oxygen and nutrients in the circulating blood.
Antibodies and hormones are proteins.

A particularly important group of proteins are the enzymes.

Enzymes,which are catalysts, are compounds that accelerate chemical reactions, without themselves being permanently changed. Each enzyme is specific in that it will catalyze only one type of reaction. Enzymes are vulnerable to damage by xenobiotics and many toxic reactions occur by changing the shape of the enzyme ("denaturation") or by inhibiting the enzyme ("inhibition").

Nucleic Acids
Nucleic acidsare large organic compounds that store and process information at the molecular level inside virtually all body cells. Three types of nucleic acids are present:

Deoxyribonucleic acid (DNA)
Ribonucleic acid (RNA)
Adenosine triphosphate (ATP)

Nucleic acids are very large molecules composed of smaller units known as nucleotides. A nucleotide consists of a pentose sugar, a phosphate group, and four nitrogenous bases. The sugar in DNA is deoxyribose while the bases are adenine, guanine, cytosine, and thymine. RNA consists of the sugar, ribose, plus the four bases adenine, guanine, cytosine, and uracil. These two types of molecules are known as the molecules of life. For without them, cells could not reproduce and animal reproduction would not occur.

DNA is in the nucleus and makes up the chromosomes of cells. It is the genetic code for hereditary characteristics. RNA is located in the cytoplasm of cells and regulates protein synthesis, using information provided by the DNA. Some toxic agents can damage the DNA causing a mutation, which can lead to the death of the cell, cancer, birth defects, and hereditary changes in offspring. Damage to the RNA causes impaired protein synthesis, responsible for many types of diseases. Figure 2 shows the structure of DNA and RNA. Note that DNA is double-stranded and known as the double helix. RNA is a single strand of nucleotides.

High-Energy Compounds
Adenosine triphosphate (ATP)is the most important high-energy compound. It is a specialized nucleotide located in the cytoplasm of cells that serves as a source of cellular energy. ATP contains adenine (amino acid base), ribose (sugar), and three phosphate groups. ATP is created from adenine diphosphate using the energy released during glucose metabolism. One of the phosphates in ATP can later be released along with energy from the broken bond induced by a cellular enzyme.

Knowledge Check (Solutions on next page)

1) A substance in the body that contains covalently-bonded carbon and hydrogen is an:
a) Organic compound
b) Inorganic compound
c) Element

2) The nucleic acid located in the nucleus, which makes up the chromosomes of cells, is:
a) ATP
b) RNA
c) DNA

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As an expert in the field of biochemistry and toxicology, my comprehensive understanding of the intricate relationships between chemicals and physiological processes allows me to shed light on the concepts discussed in the provided article.

The article revolves around the impact of chemicals on the human body, delving into the fundamental categories of physiological chemicals. Let's break down the key concepts mentioned:

Chemical Interactions and Toxic Effects:
- Most toxic effects result from foreign chemicals interfering with normal body chemicals, disrupting homeostasis.
- Examples include interference with nutrient absorption, neurotoxicity affecting nerve transmission, and damage to cell organelles.
Physiological Chemicals:
- Three categories: Elements, Inorganic Compounds, and Organic Compounds.
Elements:
- Elements are components of all chemical compounds.
- Only 20 out of the 92 naturally occurring elements are normally found in the body.
- Seven major elements (carbon, oxygen, hydrogen, calcium, nitrogen, phosphorous, sulfur) make up about 99% of human body weight.
Inorganic Compounds:
- Important for simple functions.
- Major compounds include water (H2O), oxygen (O2), carbon dioxide (CO2), acids, bases, and salts.
- Maintenance of water balance, oxygenation of blood, and pH balance are crucial.
Organic Compounds:
- Involved in biochemical activities.
- Always contain carbon; five major categories include carbohydrates, lipids, proteins, nucleic acids, and high-energy compounds.
Carbohydrates:
- Serve as energy sources.
- Converted to glucose for cellular respiration.
- Some become structural components of genetic macromolecules.
Lipids:
- Essential substances, major energy reserve.
- Include fatty acids, triglycerides, steroids, and phospholipids.
- Cholesterol is a component of cell membranes.
Proteins:
- Diverse and abundant organic compounds.
- Building blocks are 20 amino acids.
- Perform various functions, such as structural support, transport of oxygen and nutrients, and enzymatic catalysis.
Nucleic Acids:
- Large organic compounds storing and processing information.
- Types include DNA, RNA, and ATP.
- DNA in the nucleus is the genetic code; RNA in the cytoplasm regulates protein synthesis.
High-Energy Compounds:
- ATP is a crucial high-energy compound.
- Acts as a source of cellular energy through the release of phosphate groups during glucose metabolism.

In summary, the article elucidates the intricate web of interactions between different chemical components in the body, emphasizing the critical role they play in maintaining normal physiological functions and the potential disruptions caused by toxic agents.