Chapter 2 Chemical and Biochemical Foundations, Part 1 PDF

Summary

This document details the fundamentals of chemical and biochemical principles used in advanced physiology and pathophysiology. It covers topics such as atoms, ions, the periodic table, molecules, body fluids, and basic chemical reactions. It's intended for academic study, specifically an undergraduate level.

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Chapter 2
Chemical and Biochemical
Foundations, Part 1
Advanced Physiology and Pathophysiology: Essentials for Clinical
Practice

Nancy C Tkacs, Randall L Johnson, and Linda L Herrmann

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 Key Concepts
Atoms bond together, forming molecules—enzymes catalyze reactions of
molecule synthesis, degradation, and exchange
Some atoms and molecules are charged (ions), with acids and bases being
special compounds that ionize
Biomolecules can be hydrophobic and nonpolar, others are hydrophilic and
are either charged (ions) or polar (contain partial charges)
Cell membranes have a lipid hydrophobic core that forms a barrier
between two aqueous solutions—intracellular fluid and extracellular fluid
Small biomolecules build to macromolecules
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Atoms Found in the Body

The Big Four: Oxygen (O), Carbon (C), Hydrogen (H),
Nitrogen (N)

Also found in lesser amounts: Calcium (Ca), Phosphorus
(P), Potassium (K), Sulfur (S), Sodium (Na), Chlorine (Cl),
Magnesium (Mg), Iron (Fe), Copper (Cu), Zinc (Zn), Iodine
(I), and a few others

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Atomic Structure

Nucleus
Protons (positive
charge)s—determine
atomic number
Neutrons

Electrons—negatively
charged, move in a cloud
around the nucleus
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 Periodic Table of Elements

Elements fall into
groups
Within groups,
elements share
similar
properties
Note the
following groups
of atoms found
in the body:
Group 1—Na, K
Group 2—Mg, Ca
Group 15—N, P
Group 16—O, S
Group 17—Cl, I

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 Electron Shells
Electrons are organized into shells, with the innermost shell able
to hold two electrons, and the remaining shells able to hold eight
electrons

Incomplete filling of the outermost shell makes an element
chemically reactive

Hydrogen (element 1)—one electron, good chemical reactivity

Helium (element 2)—two electrons fill outer shell—chemically
inert

Lithium (element 3)—can lose one electron and become Li+, good
chemical reactivity, same group as sodium

Beyond these three elements, the outer shell has eight places.
When all are not filled, the octet rule is not satisfied, and the
element is reactive (C, K)

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 Gaining or Losing Electrons Creates Charged IONS
The outer valence shell of sodium contains one electron—stability is improved by
giving up that electron and developing a positive charge (Na+)

The outer valence shell of chlorine has seven electrons—stability is improved by
gaining one electron and becoming a negatively charged chloride ion (Cl−)

Sodium chloride is formed by an ionic bond between Na+ and Cl−

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 Water Molecules Surround Ions In Solution
Water molecules have partial positive
and negative charges
When NaCl dissolves in water, the
ionic bond is broken and hydrogen
atoms of water are attracted to Cl−,
while oxygen atoms of water are
attracted to Na+
The ions of the body are all stable
when surrounded by water molecules

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 Acids and Bases Dissociate In Solution
Acids are proton (H+) donors, bases are
proton acceptors

When HCl (strong acid) dissolves in water,
the ionic bond is broken and hydrogen
atoms of water are attracted to Cl−, while
oxygen atoms of water add the H+ and
become hydronium ions

When NaOH (strong base) dissolves in
water, Na+ is surrounded by water
molecules, and hydroxide ion is stable.

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 Body Fluids Differ in Composition by Location
Extracellular fluid is rich in
Plasma Interstitial Intracellular
Na+, Cl− Fluid Fluid

Plasma has protein anions
Interstitial fluid has few
proteins

Intracellular fluid is rich in
K+, PO43− (phosphate) and
proteins
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 Body Buffer Systems Maintain pH between 7.35-7.45
Carbonic acid buffer system is
centered on carbonic acid that can
dissociate into water + CO2 (which can
be removed by lungs), or into
bicarbonate + H+—either can be
secreted or reabsorbed by kidneys to
maintain balance

Amino acids have acidic carboxyl
groups and basic amine groups that
buffer pH changes.

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Covalent Bonding involves Atom Electron Sharing

Sharing with one electron contributed from each atom
forms a single covalent bond

Sharing with two electrons contributed from each atom
forms a double covalent bond

Sharing with three electrons contributed from each atom
forms a triple covalent bond

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 Covalent Bond Examples

Each of these
molecules allows
roughly equal
sharing of electrons
between atoms:
characterizing
nonpolar bonding
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Bond Properties Depend on Atom Electronegativity
Polar covalent bonds have unequal electron sharing
(one atom has stronger “pull” on bonding electrons)
This results in molecules with partial charges, shown
as d+ or d−

Bond Type Electronegativity Example
Difference
Nonpolar 0-0.4 O2
Polar covalent 0.4-2.0 H2 O
Ionic > 2.0 NaCl
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 Water is the Polar Solvent of the Body Fluids
Hydrogen bonds (dashed
lines) are weak bonds
formed by the attraction
between partially charged
molecules.

Water has high surface
tension because of hydrogen
bonding

Water makes hydrogen
bonds with itself and with
other polar molecules (like
urea, shown on right)
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Examples of Polar Biomolecules
Biomolecules that have bonds between hydrogen and
electronegative oxygen or nitrogen generally have polar qualities
Carbohydrates, amino acids, nucleic acids, are all polar compounds,
and are therefore hydrophilic (water-loving)
As noted earlier, ions are charged compounds, and they are also
hydrophilic, easily soluble in water and aqueous solutions
Lipids have many C-H bonds with equal electron sharing, they are
nonpolar and hydrophobic (water-hating)

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 Organic Molecules and Terminology
Core structures are based on carbon’s ability to make up to four bonds, allowing complex
chains and branching molecules

Organic groups that include oxygen and nitrogen can modify carbon chains and rings, creating
molecules with unique functional properties

Many organic groups are polar or have characteristics of acids or bases

The addition of an organic group to an existing molecule is described with the suffix “-ation”
(methylation, phosphorylation, hydroxylation)

The removal of an organic group from an existing molecule is described with the prefix “de-”
and suffix “-ation” (demethylation, deamination, decarboxylation)

Many reactions are carried out by enzymes with the suffix “-ase” (carboxylase, hydroxylase)

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Organic Compounds and Functional Groups

Amine Aldehyde

Hydroxyl Ketone
Methyl

Carboxyl

Amino Acid Sugar Sugar
Alanine Ribose Ribulose

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Sulfur-containing Functional Groups

Disulfide bond

Thiol

Amino Acid Amino Acid
Cysteine Cystine

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Disulfide Bonds Shape Cysteine-containing Proteins

Insulin
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Reactions Synthesize, Decompose, and Change Molecules

Glycogen synthesis
describes the serial
addition of glucose
molecules by glycogen
synthase Chemical reactions involving
glucose require that it be
Glycogen decomposition
phosphorylated by a kinase
describes the progressive
enzyme
removal of glucose
molecules by glycogen This is an exchange reaction with
phosphorylase ATP giving up one phosphate that
is transferred to glucose by
hexokinase or glucokinase
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 Carbohydrates
Hexoses (six carbon) and other monosaccharide sugars

Chiral compounds, based on arrangement of four attachments to a central carbon

D- and L- forms, D-sugars are most common in nature

Ribose (five carbon) and deoxyribose sugars are contained in nucleotides and nucleic acids

Disaccharides consist of two monosaccharides bonded together
Sucrose (table sugar) = glucose + fructose
Lactose (milk sugar) = glucose + galactose (absence of enzyme lactase leads to lactose intolerance)
Maltose = glucose + glucose – breakdown product of many starches

Hydroxyl groups on sugars make them very hydrophilic, easily soluble in water, cannot diffuse
across cell membrane lipid barrier, so they require carrier proteins

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 D-glucose
Principal energy source

Sole energy source for the brain under most conditions

Liver regulates blood glucose by synthesis of glycogen
after meals, release of glucose from glycogen while
fasting

Optimal levels: 70–110 mg/dL

Hyperglycemia occurs in diabetes mellitus, leads to
chronic complications Chain Form Ring Form

Hypoglycemia can cause brain dysfunction and coma

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 Carbohydrates are Attached to Cell Surface
Membrane surface markers when attached to proteins (forming glycoproteins) and lipids
(forming glycolipids)

Blood groups are distinguished by A, B, and O antigens attached to membrane sphingolipids

O antigen A antigen B antigen

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