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Pharmaceutical Inorganic Chemistry, Study notes of Inorganic Chemistry

Our Lady of Fatima University (OLFU)Inorganic Chemistry

Pharmaceutical Inorganic Chemistry is a foundational subject for pharmacy students, focusing on the principles and applications of inorganic compounds in medicine. It starts with the basics of chemistry, including the history, branches, and significance in daily life. Students learn about matter, atomic structure, bonding, and chemical reactions, gaining essential knowledge about how substances interact and transform. The course covers the classification and properties of elements, especially those relevant to pharmaceuticals such as sodium, potassium, calcium, magnesium, zinc, and silver. It also explains important theories like acid-base reactions, gas laws, and solution chemistry. Special emphasis is given to the roles of elements in therapy, diagnostics, and drug formulation. The study of kinetics, equilibrium, and periodic groups connects theoretical knowledge to practical pharmaceutical use.

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PHARMACEUTICAL INORGANIC CHEMISTRY | DRG | Page 1
PRELIMS
Lesson 1: Introduction to Chemistry
What has chemistry done for us?
- Anaesthetics (Local, Generalize)
- Antibiotics
- Batteries
- Birth Control
- Catalytic Converters
- Fertilizers
- Fuels
- Plastics
- Screens
- Water Treatment
Branches of Chemistry
Organic Chemistry
- deals with the reaction of the study of most carbon-containing
compounds
Inorganic Chemistry
- the study of all substances not classified as organic, mainly those
compounds that do not contain carbon
Physical Chemistry
- the study of the structure of matter, energy, changes, and the
laws, principles and theories that govern the transformation of
matter and their relations.
Analytical Chemistry
- the identification, separation, and quantitative determination of
the components of different molecules.
Biochemistry
- specializes in the study of substances and processes occurring in
living things.
Theoretical Chemistry
- the use of Mathematics and computers to understand the
principles behind observed chemical behavior and to design and
predict the properties of the compounds.
Agrochemistry
- deals with the application of chemistry for agricultural
production, food processing and environmental remediation.
Astrochemistry
- study of composition and reactions of the chemical elements and
molecules founding the stars and in the space and of the
interactions between this matter and radiation.
Cluster Chemistry
- involves the study of the cluster of branched atoms, intermediate
in size between single molecules and bulk solids.
Combinational Chemistry
- is the chemistry associated with soil, air and water and of the
human impact on natural systems.
Geochemistry
- study of chemical composition and chemical processes
associated with the Earth and other planets.
Green Chemistry
- concerned with the processes and products that eliminate or
reduce the use of hazardous substances.
Medical Chemistry
- chemistry as it applies to pharmacology and medicine.
Nuclear Chemistry
- is a branch of chemistry associated with nuclear reactions and
isotopes.
Photochemistry
- is a branch of chemistry concerned with the interaction between
light and matter
History of Chemistry
- Prior to 1000 B.C., processing of natural ores(dolomite) to produce metals
for ornaments and weapons and the use of embalming fluids are already
being used.
History
- Ancient civilizations and technologies formed the various branches of
Chemistry, and has applied to in several ways:
- The Greek philosophers were the first to formulate theories about the
behavior of matter.
- By about 400 B.C. they had proposed that all matter was composed of four
fundamental substances: fire, earth, water, and air
- “whether matter is continuous, and thus infinitely divisible into smaller
pieces, or composed of small, indivisible particles…
- The latter was supported by Demokritos of Abdera (c. 460–c. 370 B.C.) and
Leucippos, who used the term atomos (which later became atoms) to
describe these ultimate particles.
- Experimental Chemistry originated from alchemy, a mystical chemistry
devoted to things such as converting common metal into gold. The
philosophers called the followers of alchemy as alchemists.
- Alchemy was referred to as a pseudoscience
History
Pythagoras (530 B.C.)
- believed that the earth is spherical in shape and rotated an axis
once a day.
Aristotle (384-323 B.C.)
- held that the elements Fire, Water, Air, and Earth were the
building blocks of all substances.
- recognized that most ordinary, material things are composed of
multiple substances, although he thought that some of them
could be composed of a single, pure substance.
Archimedes (287-212 B.C.)
- discovered the laws concerning pulleys, levers and of floating
bodies which in turn gave rise to the concepts of density and
specific gravity.
- “Law of Buoyancy”
Hero of Alexandria (A.D. 62-150)
- whose main work was devoted to describing gaseous behavior
and in many respects anticipated the kinetic molecular theory
Modern Chemistry
- development of systematic metallurgy (extraction of metals from ores) by a
German, Georgius Agricola [aka Georg Bauer] (1494–1555)
- medicinal application of minerals by a Swiss alchemist/physician known as
Paracelsus [1493–1541]
- Philippus Aureolius Theophrastus Bombastus Von Hohenheim
Robert Boyle (1627-1691)
- carefully measured the relationship between the pressure and
volume of air.
- Published his book “The Skeptical Chymist” in 1661, paving way to
give birth the quantitative sciences of physics and chemistry
- Boyle’s Law (P1V1 = P2V2)
- The phenomenon of combustion evoked intense interest in the 17th and 18th
centuries.
- Georg Stahl (1660–1734) suggested that a substance he called “phlogiston”
flowed out of the burning material.
- Phlogiston = Oxygen
Joseph Priestly (1733-1804)
- an English clergyman and scientist discovered oxygen and was
found to support vigorous combustion and was thus supposed to
be low in phlogiston
- By the late 18th century, combustion had been studied extensively; the gases
carbon dioxide, nitrogen, hydrogen, and oxygen had been discovered; and
the list of elements continued to grow
OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
COLLEGE OF PHARMACY
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Download Pharmaceutical Inorganic Chemistry and more Study notes Inorganic Chemistry in PDF only on Docsity!

PRELIMS

Lesson 1: Introduction to Chemistry What has chemistry done for us?

  • Anaesthetics (Local, Generalize)
  • Antibiotics
  • Batteries
  • Birth Control
  • Catalytic Converters
  • Fertilizers
  • Fuels
  • Plastics
  • Screens
  • Water Treatment Branches of Chemistry ● Organic Chemistry
  • deals with the reaction of the study of most carbon-containing compounds ● Inorganic Chemistry
  • the study of all substances not classified as organic, mainly those compounds that do not contain carbon ● Physical Chemistry
  • the study of the structure of matter, energy, changes, and the laws, principles and theories that govern the transformation of matter and their relations. ● Analytical Chemistry
  • the identification, separation, and quantitative determination of the components of different molecules. ● Biochemistry
  • specializes in the study of substances and processes occurring in living things. ● Theoretical Chemistry
  • the use of Mathematics and computers to understand the principles behind observed chemical behavior and to design and predict the properties of the compounds. ● Agrochemistry
  • deals with the application of chemistry for agricultural production, food processing and environmental remediation. ● Astrochemistry
  • study of composition and reactions of the chemical elements and molecules founding the stars and in the space and of the interactions between this matter and radiation. ● Cluster Chemistry
  • involves the study of the cluster of branched atoms, intermediate in size between single molecules and bulk solids. ● Combinational Chemistry
  • is the chemistry associated with soil, air and water and of the human impact on natural systems. ● Geochemistry
  • study of chemical composition and chemical processes associated with the Earth and other planets. ● Green Chemistry
  • concerned with the processes and products that eliminate or reduce the use of hazardous substances. ● Medical Chemistry
  • chemistry as it applies to pharmacology and medicine. ● Nuclear Chemistry
  • is a branch of chemistry associated with nuclear reactions and isotopes. ● Photochemistry
  • is a branch of chemistry concerned with the interaction between light and matter History of Chemistry
  • Prior to 1000 B.C., processing of natural ores(dolomite) to produce metals for ornaments and weapons and the use of embalming fluids are already being used. History
  • Ancient civilizations and technologies formed the various branches of Chemistry, and has applied to in several ways:
  • The Greek philosophers were the first to formulate theories about the behavior of matter.
  • By about 400 B.C. they had proposed that all matter was composed of four fundamental substances: fire, earth, water, and air
  • “whether matter is continuous, and thus infinitely divisible into smaller pieces, or composed of small, indivisible particles…
  • The latter was supported by Demokritos of Abdera (c. 460–c. 370 B.C.) and Leucippos, who used the term atomos (which later became atoms) to describe these ultimate particles.
  • Experimental Chemistry originated from alchemy, a mystical chemistry devoted to things such as converting common metal into gold. The philosophers called the followers of alchemy as alchemists.
  • Alchemy was referred to as a pseudoscience History ● Pythagoras (530 B.C.)
  • believed that the earth is spherical in shape and rotated an axis once a day. ● Aristotle (384-323 B.C.)
  • held that the elements Fire, Water, Air, and Earth were the building blocks of all substances.
  • recognized that most ordinary, material things are composed of multiple substances, although he thought that some of them could be composed of a single, pure substance. ● Archimedes (287-212 B.C.)
  • discovered the laws concerning pulleys, levers and of floating bodies which in turn gave rise to the concepts of density and specific gravity.
  • “Law of Buoyancy” ● Hero of Alexandria (A.D. 62-150)
  • whose main work was devoted to describing gaseous behavior and in many respects anticipated the kinetic molecular theory Modern Chemistry
  • development of systematic metallurgy (extraction of metals from ores) by a German, Georgius Agricola [aka Georg Bauer] (1494–1555)
  • medicinal application of minerals by a Swiss alchemist/physician known as Paracelsus [1493–1541]
  • Philippus Aureolius Theophrastus Bombastus Von Hohenheim ● Robert Boyle (1627-1691)
  • carefully measured the relationship between the pressure and volume of air.
  • Published his book “The Skeptical Chymist” in 1661, paving way to give birth the quantitative sciences of physics and chemistry
  • Boyle’s Law (P1V1 = P2V2)
  • The phenomenon of combustion evoked intense interest in the 17th and 18th centuries.
  • Georg Stahl (1660–1734) suggested that a substance he called “phlogiston” flowed out of the burning material.
  • Phlogiston = Oxygen ● Joseph Priestly (1733-1804)
  • an English clergyman and scientist discovered oxygen and was found to support vigorous combustion and was thus supposed to be low in phlogiston
  • By the late 18th century, combustion had been studied extensively; the gases carbon dioxide, nitrogen, hydrogen, and oxygen had been discovered; and the list of elements continued to grow OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

● Antoine Lavoisier (1743–1794))

  • Father of Chemistry
  • a French chemist who finally explained the true nature of combustion. His experiments suggested that mass is neither created nor destroyed (Law of Conservation of Mass).
  • he published the first modern chemistry textbook, Elementary Treatise on Chemistry, in which he presented a unified picture of the chemical knowledge assembled up to that time. ● Joseph Proust (1754– 1826)
  • showed that a given compound always contains exactly the same proportion of elements by mass.
  • The principle of the constant composition of compounds, originally called “Proust’s law,” is now known as the Law of Definite Proportion. A given compound always contains exactly the SAME PROPORTION OF ELEMENTS BY MASS. ● John Dalton (1766– 1844)
  • an English schoolteacher thought about atoms as the particles that might compose elements.
  • Law of Multiple Proportions – when two elements form a series of compounds, the ratios of the masses of the second element that combine with 1 gram of the first element can always be reduced to small whole numbers.
  • By 1869, the concepts of atoms and molecules were well established, and it was possible for Mendeleev and Meyer to describe different forms of the periodic table.
  • In 1896, Becquerel discovered radioactivity, and another area of study was opened.
  • Studies of subatomic particles, spectra, and electricity finally led to the atomic theory of Bohr in 1913…
  • …which was soon modified by the quantum mechanics of Schrodinger and Heisenberg in 1926 and 1927. ● Isaac Newton
  • Father of Modern Chemistry
  • 3 Laws of Newton ● Marie Curie
  • Discovered the radioactive elements (Radium and Polonium ● Robert Boyle
  • the first scientist who gave the first process definition of a chemical element, reaction and chemical analysis ● Henry Cavendish
  • he discovered the hydrogen gas which he termed "inflammable air"
  • found out that water was composed of two gases, hydrogen and oxygen ● John Dalton
  • Known for the discovery of modern atomic theory ● Ernest Rutherford
  • Proposed that atoms are mostly empty with a positively charged nucleus Filipino Scientists ● Julian Banzon
  • He researched methods of producing alternative fuels. ● Dr. Benjamin Cabrera
  • developed innovations in drug treatments against diseases caused by mosquitoes and agricultural soil. ● Paulo Campos
  • built the first radioisotopes laboratory in the Philippines.
  • "The Father of Nuclear Medicine in the Philippines". ● Ernesto del Rosario
  • best known for his achievements in industrial biotechnology and applied physical chemistry. ● Armando Kapauan
  • specialized in environmental chemistry.
  • taught one of the first environmental chemistry courses in the country. ● Luz Oliveros Belardo
  • researched the phytochemical properties of plants in the Philippines for natural products. ● Alfredo Santos
  • noted researcher in the chemistry of natural products. Lesson 2: Matter, Atoms and Isotopes Matter Mass
  • Constant at any place and time
  • Refers to the amount of the substance
  • When travelled to the moon, the mass of an object will still be the same
  • Can never be zero Weight
  • Varies, depends on the amount of gravity
  • Refers to the downward pull of the objects towards the center of the earth
  • When travelled to the moon,the weight of an object will only be 1/6 of its weight on earth
  • Can also be zero Properties of Matter Extrinsic Property
  • Are the physical properties of matter which may EP:
  • Not the characteristics of the substance itself
  • Depends on the amount, also called extensive properties
  • Examples are height, weight, temperature, size, shape, volume, etc Intrinsic Property
  • Are the properties of matter which are constant.
  • Give the characteristics of the substance its unique identity
  • Those which do not depend on the amount, also called intensive properties.
  • Examples are boiling point,freezing point, melting point,viscosity, refractive index, etc Classifications of Matter I. Pure Substance
  • kind of matter possessing definite, fixed, and unvarying composition with unique set of properties- are made up of only one kind of matter. a. Elements b. Compounds a. Elements
  • simplest form of substance that cannot be decomposed by chemical means.
  • building blocks of matter a.1Metals – elements characterized by their brilliant luster, ductility, malleability and are good conductors of heat and electricity. a.2 Non-metals – possess the characteristics opposite of metals. a.3 Metalloids – elements which possesses the characteristics of both metals and nonmetals. b. Compounds OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
  • Discovered by Joseph John Thompson.
  • Was the first component of the atom to be identified.
  • A mass of 9.109 x 10↑31kg
  • A charge of -1.602 x 10^-19 coulombs Protons
  • One of the components of a nucleus.
  • Discovered by Eugene Goldstein.
  • A mass of 1.673 x 10^-27 kg
  • Charge of +1.602 x 10^-19 coulombs Neutrons
  • Another component of a nucleus.
  • Discovered by James Chadwick in 1932.
  • A mass of 1.675 x 10^-27 kg
  • Has no charge Atomic Number
  • number of protons in the nucleus of an atom of an element, also the number of electrons in an atom
  • This quantity is fundamental to the identity of each element because it is related to the electrical make-up of atom,therefore:
  • Atomic # = # of protons = # of electrons Mass Number
  • total number of protons and neutrons on the nucleus of nucleons, therefore
  • :mass # = # of protons + # of neutrons Nuclear Notation A- Mass number N - neutrons Z - atomic number
  • Aluminum
  • Magnesium
  • Gold
  • Silver
  • Mercury
  • Argon
  • Neon
  • Cadmium
  • Lead Isotopes
  • atoms of the same element with the same atomic number, but different mass numbers.
  • In other words, they have the same number of protons and electrons but different number of neutrons.
  • Many elements exist as two or more stable isotopes, although one isotopes is usually present in greater abundance than another isotopes. Lesson 3: Quantum Mechanical Mode of the Atom Energy Levels of the Orbitals
  1. Principal energy levels - n, assigned values 1-
  2. Energy sublevels - s, p, d, f s sublevel – 1 orbital p sublevel – 3 orbitals d sublevel – 5 orbitals f sublevel – 7 orbitals
  3. Orbitals – Two electrons per orbital Pauli Exclusion Principle
  • The Pauli exclusion principle states that a maximum of two electrons, each having opposite spins, can fit in an orbital. Hund’s Rule of Maximum Multiplicity
  • All the subshells in an orbital must be singly occupied before any subshell is doubly occupied. Furthermore, the spin of all the electrons in the singly occupied subshells must be the same Electron Configuration of an Atom
  • is the representation of the arrangement of electrons distributed among the orbital shells and subshells. used to describe the orbitals of an atom in its ground state, but it can also be used to represent an atom that has ionized into a cation or anion by compensating with the loss of or gain of electrons in their subsequent orbitals. Rules for Assigning Electron Orbitals Aufbau Principle
  • Each electron occupies the lowest energy orbital available Writing Electron Configuration Chemical BondsChemical bonds – are forces of attraction that exist between a positive ion and a negative ion or between molecules. ● Octet rule –an atom other than hydrogen tends to form bonds until it is surrounded by eight electrons. Exceptions to the Octet Rule
  • There are three types of ions or molecules that do not follow the octet rule:
  1. Ions or molecules with an odd number of electrons.
  2. Ions or molecules with less than an octet.
  3. Ions or molecules with more than eight valence electrons (an expanded octet Three Important Types of Interatomic Bonds ● Ionic - Electrostatic attraction between ions ● Covalent - Sharing of electrons ● Metallic - Metal atoms bonded to several other atoms Ionic Bonding OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

● When a metal and a non-metal get together. ● Ionic bond or electrovalent bond is the electrostatic force that holds ions together in an ionic compound. It is formed by the transfer of electrons from an atom of low ionization energy (alkali and alkaline earth metal) to a more electronegative element (halogen and oxygen) Covalent Bonding ● There are several electrostatic interactions in these bonds

  • Attractions between electrons and nuclei
  • Repulsions between electrons
  • Repulsions between nuclei ● A bond in which two electrons are shared between atoms. ● Each covalent bond has 2 electrons that are shared. ● Only the valence electrons are involved in these covalent bonds. ● Covalent compounds – is formed when electron are shared equally between two atoms with the same or almost the same electronegativity. Electronegativity
  • is the relative attraction that an atom and molecule has for the shared pair of electrons in covalent bond.
  • In a bond between two identical atoms the pair of electrons are shared equally.
  • Chemists have found that in many bonds the pair of electrons are attracted to one of the atoms more than to the other. Multiple Bonds Single Bond Double Bond Triple Bond Metallic Bond
  • consists of a group of cations held in a fixed position in the metal and the valence electrons which are free to move about among the different electron clouds Hydrogen Bond Van der Waals Dipole Bond Lewis Symbol
  • Lewis structures for 16 elements
  • It is rare to use Lewis pictures for other elements (transition metals, etc.)
  • One dot = 1 electron Lewis Structure - Diagrams for bonding in molecules
  • Lewis structures are representations of molecules showing all valence electrons, bonding and nonbonding. Lewis Structures - A way to keep track of those valence electrons
  1. Find the sum of valence electrons of all atoms in the polyatomic ion or molecule.
  • If it is an anion, add one electron for each negative charge.
  • If it is a cation, subtract one electron for each positive charge.
  • The central atom is the least electronegative element that isn’t hydrogen (why?). Connect the outer atoms to it by single bonds. Writing Lewis Structures ● Then assign formal charges.
  • For each atom, count the electrons in lone pairs and half the electrons it shares with other atoms.
  • Subtract that from the number of valence electrons for that atom: The difference is its formal charge. **Binary Compound
  1. Metal + Non-metal**
  • Name the metallic element first
  • Name the non-metallic element, then add the suffix-ide Example
  • NaCl – Sodium chloride
  • KBr – Potassium bromide Two Non-Metals
  • Identify the number of atoms of each of the elements in the covalent compounds Example
  • CCl4 - Carbon tetrachloride
  • CO – Carbon monoxide Binary Acid
  1. Use the prefix hydro
  2. Name the non metallic element
  3. Add the suffix –ic acid Example HCl – Hydrochloric acid HF – Hydrofluoric acid Tertiary Compounds
  4. Name the metallic element
  5. Identify the polyatomic ion Example
  • Na2SO4 – Sodium sulfate
  • H2 SO3 – Sulfurous acid Lesson 4: Chemical Reactions Evidences of Chemical Reactions OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

Hence, a formula weight gives the mass of one formula unit in a.m.u. (atomic mass unit) or gram per mole.

  • The molecular weight of a compound is the sum of the atomic weights of all the atoms present in a molecule. Formula weight applies to both ionic and molecular compounds. Mole Relationships
  • The mole is the amount of a substance in grams that contains Avogadro’s number (6.02 x 1023) of units (atoms, molecules or formula units). It only means that 1 mole of C atom is equal to 12 g of C.
  • A mole may be expressed as the weight in grams of elements over the atomic weight or molecular weight of the element or compound. Percent Composition of Compounds
  • In order to calculate the percentage composition of a certain compound, the atomic mass is divided by its molecular weight and multiplied by 100. If weight is given, it should also by its molecular weight and multiplied by 100. Empirical Formula ● The empirical formula is the smallest whole number ratio of atoms present in a compound ● TO find the empirical formula of a compound, three steps should be followed:
  • If a percentage is given, ASSUME that it is a 100g sample.
  • Solve for the number of moles of each element.
  • Find out the simplest ration of moles from step 2 by dividing the smallest value Molecular Formula ● The molecular formula is the actual number of atoms present in a molecule of the compound. ● In finding out the molecular formula:
  1. Determine the empirical weight of the empirical formula.
  2. Calculate the molecular ratio by dividing the molecular weight of the compound from its empirical weight. mr = molecular weight (MW) Empirical weight (EW)
  3. Multiply the mr (molecular ratio) obtained with the empirical formula in order to get the molecular formula Calculations based on Balanced Equations
  • A balanced equation may be interpreted on a molecular based in terms of moles of reactants and products on a mass basis.
  • This is very useful in calculating for the amount produced in each reaction. Stoichiometric calculations can be used to determine the amount of reactant needed to produce a desired amount of product. Lesson 5: Solution Components of a Solution ● Solute – the substance that is dissolved ● Solvent – the dissolving medium. ● Solubility - The amount of solute that dissolves in a given amount of solvent to produce a saturated solution. Mixture ● Liquid-Liquid ● Liquid-Solid ● Solid-Solid Types of Solution ● Gas – this is a solution wherein the solute and the solvent are both gases. ● Liquid – this is a solution in which the solute can be a solid, liquid or a gas and the solvent is a liquid. ● Solid – this is a solution composed of a solid, liquid or a gas solute and a solid solvent. Classification of Solutions Degree of Saturation ● Saturated – a solution that contains the maximum amount of solute that a solvent can dissolve. ● Unsaturated – a solution that contains less amount of solute that the solvent can dissolve ● Supersaturated – a solution that contains more amount of solute than the solvent can dissolve. Miscibility (liquid solutions) ● Miscible – all the components of the solution dissolve in each other in all proportions. ● Immiscible – the components of the solution are completely insoluble in one another regardless of the proportions involved. Reference or Standard Solutions ● Isotonic – when two solutions have the same amount of solute concentrations ● Hypotonic solution – when one solution have a lower solute concentration than that of another solution Hypertonic solution – when one solution contains a higher solute concentration than that of another solution OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

Solubility

  • The measure of how much solute can be dissolved in a given amount of solvent at a given temperature. Factors Affecting Solubility ● Temperature ● Pressure ● Surface area ● Nature of solvent ● Stirring the mixture Concentration of Solutions
  • Concentration is the amount of solute dissolved in a given amount of solution. This will affect the properties of a solution both the physical and chemical ● Concentrated– a solution that contains large amount of solute in relation to the solvent in the solution. ● Dilute – a solution that contains small amount of solute in relation to the solvent in the solution. Molarity
  • Molarity is defined as the number of moles of solute per liter of solution(Chang, 2007) Molarity = moles of solute / Liter solution M = (g solute / mwt.solute) / Liter solution Molality
  • Molality is the number of moles of solute per kilogram solvent. Molality = moles of solute / kilogram of solvent m = ( wt. solute / mwt. solute ) / kg solvent Normality (N)
  • Normality is defined as the gram-equivalent weight of solute per liter of solution. Normality = gram-equivalent weight of solute / liter of solution N = gew solute / L solution Where : gew = wt of solute / (mwt solute / oxidationstate of cation) Gas Law Properties of Gas ● Wide spaces between particles ● Move very freely ● Expand to fill container ● No definite volume ● Readily soluble/miscible ● Low density ● Compressible ● Expand when heated Quantities that Influence the Nature and Behavior of Gases:
  • Pressure (P) – force exerted by a gas per unit areaStandard Pressure: 1 atm (atmosphere) = 760 mmHg
  • Temperature (T) – average kinetic energy of gas particles Standard Temperature: 273 K = 0°C
  • Volume (V) – space occupied by gas particles1 mol of gas = 22.4 L
  • Number of Particles (n) – expressed in mole1 mol of gas = 6.02 x 10^ particles
  • Molecular Mass (m) 1 mol of gas = molecular mass (g) Boyle’s Law ● Pressure-Volume Relationship by English chemist Robert Boyle in 1662. ● As volume becomes smaller, more collisions occur and the air pressure increases; pressure and volume are directly related at constant temperature and amount of gas Charles' Law ● Volume-Temperature RelationshipbyFrench physicist Jacques AlexandreCharles in 1787. ● The kinetic energy of gas particles increases as temperature increases;the Kelvin temperature and volume of a gas are directly related with no change in pressure and amount of gas. Gay-Lussac’s Law ● Pressure-Temperature Relationship by French scientist Joseph Louis GayLussac in 1808. ● If the gas is heated, its pressure will increase, with constant volume and number of moles, the pressure of a gas is directly related to its Kelvin temperature Combined Gas Law ● Used to solve for changes in pressure, volume and temperature of a gas. Avogadro’s Law ● Volume-Mole Relationship by Italian scientist AmadeoAvogadro in 1811 ● The volume of the gas is directly related to the number of moles at constant temperature and pressure Ideal Gas Law ● Boyle’s Law, Charles’ Law and Avogadro’s Law were combined where the variables pressure, volume,temperature and amount of gas equated to a single constant R or the universal gas constant. OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

● When concentration of a reactant is increased, more molecules are crowded into given volume and the total number into a given volume and the total number of number of molecular collisions per unit time is increased

  • Increase in the rate of the reaction. Law of Mass Action
  • States that the speed of a chemical change is proportional to the concentration of the reacting substances. ↑conc = ↑speed chemical reaction Lesson 2: Group IA and Group IB Terminologies
  • Periodic Table
  • also known as the periodic table of elements, is a tabular display of the chemical elements, which ARE ARRANGED by atomic number,electron configuration, and recurring chemical properties. The structure of the table shows periodic trends. History
  • Antoine Lavoisier ● Father of Modern Chemistry ● List 33 chemical elements (Oxygen, Sulfur and Hydrogen)
  • Johann Wolfgang Dobereiner ● Law of Triads (Dobereiner’s triad) – related properties Dobereiner’s Triad
  • Leopold Gmelin ● Gmelin System - he had identified ten triads, three groups of four, and one group of five.
  • Jean-Baptiste Dumas ● describing relationships between various groups of metals.
  • August Kekule ● Ability of Carbon to bond other 4 elements. (Concept of Benzene) ● Founder of Theory of Chemical Structure
  • John Newlands ● Law of Octaves ● Arrange the elements according to atomic number but slightly differ from modern P.T. Newlands’ Law of Octaves
  • Dmitri Ivanovich Mendeleev and Julius Lothar Meyer ● Published periodic table
  • Henry Mosley (Modern Periodic table) Mendeleev’s Periodic Table (1969) MODERN PERIODIC TABLE OF ELEMENTS Things to remember ● Periods & Groups
  • The periodic table has a total of 7 periods and 18 groups. ● Groups A are referred to as representative elements (s and p block) ● Groups B are transition elements (d and p block) ● Inner transition elements include Actinides and lanthanides series ( F block) Group 1A : Alkali-Metals
  • MOST REACTIVE GROUP
  • Stored in inert solvent: kerosene coated and paraffin
  • Don’t occur free in nature
  • Salt soluble
  • Valence electron: 1
  • Activity ↑ with atomic number
  • Alkalinity ↑ with atomic number
  • Degree of solvation ↓ with atomic number Hydrogen - 1
  • By Henry Cavendish (1766)
  • Aka: “inflammable air”
  • Lightest and Most abundant element
  • Cation: monovalent or hydronium; Anion: hydride
  • Preparation: LANE PROCESS & MESSERSCHMIDT PROCESS: 99% PURE HYDROGEN
  • Isotopes: ● 1H-most abundant; PROTIUM ● 2H-heavy hydrogen; DEUTERIUM• ● 3H-radioactive: TRITIUM LITHIUM - 2
  • Greek word, “lithos” which means stone. “Earth Stone”
  • Discoverer: Johan August. Arfvedson, 1817
  • Lightest metal on Earth ● USES: ● Heat exchanger in air condition ● LiBr - depressant ● Li2CO3 (Lithase®) – DOC for Bipolar Disorder ● LiD (Deuterium) – used inHydrogen bombs Diuretic ● Lithium carbonate (Li2CO3) ● Quilonium-R ● Lithane • Eskalith ● Indication: Bipolar disorder Component of Lithia water Sodium (Natrium) - 4
  • 6 th most abundant element in Earth
  • the cation of choice to optimize the pharmaceutical utility of organic medicaments (therapeutic action due to anion, except NaCl)
  • Most abundant extracellular fluid cation
  • Humphry Davy, 1897 ● SODIUM ACETATE (NACH3 COO)
  • Acetado de Sosa,Urinary and systemic alkalinizer
  • Diuretic
  • Antacid ● Tests:
  • Zinc uranyl acetate (ZnUO2(CH3COO)4)
  • Mg uranyl acetate (MgUO2(CH3COO)4)
  • Cobalt uranyl acetate ● SODIUM BICARBONATE (NAHCO3) OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
  • Sol de Vichy, Soda Saleratus
  • Baking soda
  • Systemic antacid
  • Carbonating agent ● HCO3 - 2nd major extracellular anion ● Side effects:
    • Systemic alkalosis
    • Rebound hyperacidity
    • Edema ● SODIUM CARBONATE (Na2CO3)
  • primary standard for acid-base titrations
  • manufacture of “soda lime glass”
  • Preparation: SOLVAY PROCESS
  • Efflorescence: loss of water of crystallization
  • Forms: ● Decahydrate is washing soda, sal soda, soda crystal ● Sesquihydrate is trona, urao ● Anhydrous is soda ash, calcined soda ● SODIUM DIHYDROGENPHOSPHATE (NaH2PO4) ● Fleet enema (Rectal) ● Cathartic ● Source of P or Phosphate ● Urinary acidifier ● Sodium metabisulfite
  • “Sodium pyrosulfite”
  • Water soluble antioxidant (REDUCING AGENT) ● SODIUM CHLORIDE
  • rock salt, halite, table salt, Soler salt
  • Uses: ● Electrolyte replenisher (NSS, Lactated Ringer’s soln.) ● Tonicity adjuster ● Condiments ● Preservative ● Antidote for Silver poisoning ● SODIUM CITRATE
  • Alkalinizer
  • Buffer
  • Diuretic
  • Expectorant
  • Sequestering agent (Benedict’s rgt)
  • Anticoagulant in vitro (Sodium citrate is the ANTICOAGULANT OF CHOICE for most routine coagulation studies (Harr, 2007)
  • Pro-coagulant in vivo ● SODIUM FLUORIDE (NaFl)
  • FIRST fluoride compound used in water fluoridation
  • Anticariogenic (2% solution)
  • Stimulator of bone formation ● SODIUM HYDROXIDE
  • “Caustic soda”; “sosa”; “Lye”; Saponifying agent
  • Titrant for acids
  • Component of soda lime (Ca(OH)2; NaOH, KOH) CO2 absorber
  • Very deliquescent substance
  • Readily attack glass ● SODIUM HYPOCHLORITE
  • Dakin’s solution; Chlorox (5% NaClO)
  • Dakin’s Solution: Modified Dakin’s Solution is Diluted NaClO solution, NF ● Used as irrigant
  • Labarraque’s Solution: oxidizing and bleaching agent ● Disinfectant ● Bleaching agent ● SODIUM IODIDE
  • Solubilizer of iodine
  • Expectorant
  • Antifungal
  • Treatment of goiter ● SODIUM LACTATE
  • Antacid (management of acidosis)
  • Diuretic ● SODIUM NITRITE
  • Salitre (in Philippine market)
  • Vasodilator
  • Preservative
  • Treatment of cyanide poisoning ● CN- higher affinity than Hemeto Hgb
  • NaNO2 is highly correlated to brain tumors, and digestive tract cancer (Pszezola, 1998) due to nitrosamine production. ● CLINICAL CORRELATION
  • CN Poisoning
  • NaNO
  • Amyl nitrite
  • Sodium thiosulfate
  • Others: ● Methylene blue ● Hydroxocobalamin ● SODIUM NITRATE
  • Chile Saltpeter
  • Fertilizer (believed to be the oldest known inorganic fertilizer)
  • Manufacture of explosive
  • Guggenheim process extraction process from ore
  • Test: ● Lunge test – (+) blue color at interface of 2 liquids ● Giess-Ilosvay – (+) red color ● SODIUM SULFATE
  • Glauber's Salt
  • Sal mirabile
  • Saline cathartic
  • Production of detergents and paper pulping ● SODIUM TARTRATE
  • primary standard of KFR for water content determination
  • (+) K → Rochelle salt ● SODIUM THIOCYANATE
  • Hypotensive agent ● SODIUM THIOSULFATE
  • Photographer’s hypo; Prismatic rice
  • Chemical antidote in cyanide poisoning
  • Management of iodine toxicity (converts iodine to harmless iodide) → Treatment of Iodism: NaCl ● OTHER SODIUM DERIVATIVES ● Ion exchangers
  • Cellulose sodium phosphate: binds with calcium
  • Sodium polystyrene sulfonate: tx of hyperkalemia due to acute kidney infection ● Sodium starch glycolate ● Saccharin sodium ● Sodium cyclamate ● SLS ● Sodium stearate ● Sodium alginate ● MSG ● Sodium nitroprusside(infuse slowly) Potassium (K) - 19
  • AKA: Kalium, Potash
  • Most abundant and predominant INTRACELLULAR CATION
  • Deficiency: Hypokalemia → paralysis
  • Toxicity: Hyperkalemia → cardiac arrest ● Glass modification:
  • Potassium gives glass brown and light resistant
  • MnO2: masks blue-green color
  • Boron/ Borates: decreases the coefficient of expansion
  • Pb: increase refractive index ● Pharmacologic action:
  • Diuretic; muscle contraction ● POTASSIUM DIHYROGEN PHOSPHATE
  • Cathartic ● POTASSIUM CHLORIDE
  • Kalium durules® El
  • ectrolyte replenisher (slow IV drip)
  • Source of potassium IMPORTANT NOTE: Never give by rapid IV push ● DARROW’S SOLUTION
  • Oral glucose and electrolyte solution OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
  • Aka: Argentum, “shining bright”
  • Oligodynamic property (germicidal action)
  • Protein ppt
  • Best conductor of electricity
  • 2nd malleable metal
  • Toxicity: Argyria
  • Antidote: NSS SILVER NITRATE
  • “Lapiz infernulariz”, “Lunar caustic”, “Indelible ink”, “Caustic pencil”
  • Treatment of warts
  • Eye antiseptic for newborn babies of mother with gonorrhea.
  • Wet dressing for 3rd degree burn at 0.5% AMMONIACAL SILVER NITRATE
  • Ag(NH3)2NO
  • “Howe’s solution”
  • Dental protective
  • Desensitizing agent
  • Tollen’s rgt SILVER PROTEINATES Mild Silver Proteinate (19-25% antiseptic) Agryol Eye antiseptic, for vaginitis Strong Silver Proteinate (7.5-8.5% germicidal) Protargol Germicide for ear and throat Colloidal Silver Proteinate (18-22% gen. germicidal) Collargol General Germicide Colloidal Silver Chloride Lunosol silver protein stabilizer: Disodium EDTA Gold (Au) - 79
  • : “Aurum”, “Shining dawn”, KING OF ALL METALS
  • Most malleable and ductile
  • 3rd best conductor of electricity
  • Dissolved by: ● Aqua regia (Royal Water) ● Selenic acid (H2SeO4) > the only SINGLE acid that can dissolve gold CHRYSOTHERAPY/ AUROTHERAPY Aurothioglucose (IM) Solganal® - Treatment of gout and R.A
  • Felty’s syndrome (RA, neutropenia, splenomegaly) Gold Na thiomalate (IM) Myochrysine® Treatment of gout and RA Auranofin Ridaura® Given orally for RA Group IIA and Group IIB: Alkaline Earth Metals Group IIA and Group IIB
  • Alkaline Earth Metals
  • Oxides and Hydroxides = basic compound
  • Found on this Earth’s crust
  • 2
  • Be - Mg - Ca- Sr - Ba - Ra BERYLLIUM - Be - 4
  • Breryllo
  • Bertrandite
  • Never employed in medicine because it is the MOST TOXIC METAL.
  • Fluorescent lamp
  • Toxic: Berylliosis
  • Inflamed lungs
  • Sob MAGNESIUM - Mg - 12
  • Magnesia
  • 2nd most abundant intracellular cation
  • Present in chlorophyll (Significance: Photosynthesis)
  • Present in Grignard’s reagent
  • 7th most abundant element (2.3%) ● Natural sources:
  • As silicates: (talc, asbestos)
  • As CO3 ( magnesite, dolomite)
  • As SO4 ( kieserite ) ● Pcol action:
  • Laxative
  • Depressant
  • Natural Ca-channel blocker
  • Antidote for Magnesium poisoning: Ca gluconate ● IDENTIFICATION TEST FOR MAGNESIUM
  • p-nitrobenzene resorcinol→ blue lake
  • Oxine reagent → yellow precipitate
  • Diphenyl carbazide → violet-red
  • Quinalizarin reagent → blue precipitate ● Magnesium vs Beryllium both produces blue precipitate with quinalizarin reagent; addition of bromine water differentiates the two ● MAGNESIUM CARBONATE
  • “Magnesia”
  • Antacid, laxative ● MAGNESIUM OXIDE/ CALCINED MAGNESIA
  • Antacid, laxative
  • COMPONENT OF UNIVERSAL ANTIDOTE
  • (1 part) MgO
  • (2 parts) Activated charcoal
  • (1 part) Tannic acid ● MAGNESIUM SULFATE
  • “Epsom salt”
  • Cathartic (PO)
  • Anticonvulsant (IM)
  • Pre-eclampsia triad ● HPN, proteinuria, edema•
  • Eclampsia ● triad + seizure
  • Antidote for Ba toxicity, barbiturates poisoning MAGNESIUM HYDROXIDE
  • “Milk of magnesia”
  • “Magnesia magma”
  • FYI: Do you know milk of amnesia?
  • same as magnesium carbonate
  • Component of Maalox (Mg(OH)2 + Al(OH)3 + Simethicone) ● Side effect: diarrhea add aluminum hydroxide
  • Type of bottle for dispensing milk of magnesia: BLUE BOTTLE HYDRATED MAGNESIUM SILICATE
  • Talc, Soapstone, French chalk
  • “softest mineral” known
  • Uses ● Filtering agent ● Clarifying agent ● Dusting powder MAGNESIUM CITRATE
  • Lemonada purganti
  • Purgative lemonade Calcium - Ca - 20
  • 2nd most abundant cation in EXTRACELLULAR fluid
  • major constituent of bones and teeth → hydroxyapatite
  • Vitamin D is needed for its maximum absorption
  • Pharmacologic action: ● Blood coagulation factor ● Important muscle contraction ● Important release of neurotransmitter ● Primary element of bones and teeth, (98-99%)
  • Sources: ● Dolomite OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

● Gypsum ● Phosphate rock ● Apatite

  • Deficiency states: ● Osteoporosis: most common bone disorder; defective bone resorption ● Osteomalacia: defective bone mineralization in ADULT ● Rickets: defective bone mineralization in CHILDREN ● Hypocalcemia CALCIUM BROMIDE
  • Sedative – depressant CALCIUM CHLORIDE
  • “Muriate of lime”
  • Ca replenisher CALCIUM CARBONATE
  • Precipitated chalk
  • Prepared chalk
  • Calcite
  • Marble
  • Limestone
  • Uses ● Antacid ● Ingredient of toothpaste ● Dentifrice CALCIUM GLUCONATE
  • Ca supplement and replenisher
  • Antidote for Mg2+ poisoning CALCIUM LACTATE
  • Ca supplement CALCIUM BIPHOSPHATE
  • source of Ca and PO CALCIUM HYDROXIDE
  • Slaked lime
  • Milk of lime
  • Calcium hydrate
  • Uses: ● Antacid ● Saponifying agent ● Prevention of milk curdling promoting digestibility of the milk CALCIUM OXIDE
  • Lime
  • Quicklime
  • Calx
  • Uses ● Component of Bordeaux mixture ● Insecticide CALCIUM PHOSPHATE
  • Bone ash
  • Antacid CALCIUM HYPOCHLORITE
  • Chlorinated lime
  • Chloride of lime
  • Uses ● Disinfectant ● Bleaching agent CALCIUM SULFATE
  • CaSO4. ½H2O or 2H2O ● Plaster of Paris (hemihydrate form)
  • Gypsum (dihydrate) ● Terra alba
  • Uses ● Rodenticide ● prep of surgical casts and dental impressions DIBASIC CALCIUM PHOSPHATE
  • Recommended calcium salt as electrolyte replenisher Strontium - Sr - 38
  • Use: manufacture of flares (red fireworks)
  • Radioactive strontium is used as bone scanner
  • Strontium has an affinity for bones and useful in studying bone lesions STRONTIUM CHLORIDE
  • Sensodyne
  • Temperature desensitizing agent
  • ADR: Darkens the teeth Barium - Ba - 56
  • Aka: Heavy
  • Toxicity: Baritosis
  • Antidote: Epsom salt
  • Use as green flares BARIUM SULFATE
  • “Barium meal”
  • Radiopaque substance used for GIT imaging
  • Doesn’t dissociate in the GIT
  • CO2 absorber BARIUM HYDROXIDE
  • CO2 absorber Radium - Ra - 88
  • Discovered by Curie
  • Measurement: Becquerel
  • Board Question: What is the FIRST radioactive element discovered by curie? POLONIUM.
  • Radioactive element use for: ● Cancer radiotherapy ● Diagnostic purpose Group IIB: Volatile Metals Property: ● Exhibit auto complexation ● Only Zinc is amphoteric ZINC - Zn - 30
  • Soft metal together with Cd
  • Present in insulin
  • Carbonic Anhydrase enzyme
  • Used to coat iron to make galvanized iron
  • Deficiency: Parakeratosis
  • Toxicity: Metal Fume Fever
  • Antidote: NaHCO3 ( Sodium Bicarbonate)
  • Most common zinc ore = SPHALERITE
  • TEST: Dithizone – (+) red color extract ZINC CHLORIDE
  • Burnett’s disinfectant fluid
  • Component of Lucas reagent
  • Astring-o-sol (original formula)
  • Uses: ● Disinfectant/antiseptic ● Dentin desensitizer ● Corrosive ZINC OXIDE
  • Zinc white
  • Lassar’s paste, Flowers of Zinc
  • Component of calamine lotion ● Zinc carbonate 15% ● Zinc oxide 5% ● Glycerin 5% ● Water 75% ● Ferric oxide 0.5% ZINC SULFIDE
  • white lotion ingredient
  • Zinc sulfate + Sulfurated Potash
  • Only “white sulfide”
  • Lithopone : 30% ZnS, 70% BaS
  • Uses ● Parasiticide ● Topical protectant ● Antiseptic ZINC SULFATE
  • ZnSO4. 7H2O
  • White vitriol
  • Uses: ● Pharmaceutical necessity for white lotion OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
  • Eye wash
  • Component of cold cream and in the preparation of sodium borate preparation Buffers
  1. Phosphate Buffer System
  2. Borate Buffer System Phosphate Buffer System
  • Has the advantage of containing the dihydrogen and monohydrogen phosphate ions, one of the physiological buffer pairs normally found in the body– Ex: Sorensen phosphate buffer system
  • Disadvantage: – insolubility of the phosphate salts of such metals such as Ag,
  • Zn and Al – it supports microbial growth Borate Buffer System
  • Borate buffer system has been used in preparations containing metals that would otherwise precipitate in the presence of phosphate.
  • Since BORATES ARE TOXIC, these buffer systems are suitable in external preparations, ophthalmic and nasal solutions but are contraindicated in parenteral solutions 3 primary borate buffer system
  1. Feldman’s Buffer System (pH 7-8.2) – consists of solution containing boric acid, sodium chloride (to make it isotonic) and the alkaline solution containing sodium borate
  2. Atkins and Pantin Buffer System (pH 7.6-11) –consists of alkaline solution of sodium carbonate and acid buffer solution of boric acid and sodium chloride.
  3. Gifford Buffer System (pH 6-7.8) – similar to Feldman’s Buffer System however in place of NaCl, potassium chloride is used to make it hypotonic. Aluminum - Al - 13
  • Latin word, alum or alumen
  • Ore = Boehmite, Gibbsite, Bauxite Sources
  • Cryolite
  • (Na3AlF6 , sodium hexafluoroaluminate)
  • Chief Source: Bauxite ore
  • Pharmaceutical Uses of Aluminum:
  • Deodorant
  • Protectant
  • Antiseptic
  • Antiperspirant
  • Adverse Effects: Constipation
  • Toxicity: Shaver’s disease/ Bauxite pneumoconiosis – A progressive lung disorder caused by exposure to aluminum oxide which is present in bauxite fumes Aluminum chloride
  • astringent, antiseptic, component of deodorant Aluminum hydroxide Al(OH)
  • Amphojel
  • Cremalin gel
  • Adverse Events: ● Constipation ● PO4 deficiency Aluminum phosphate (AlPO4)
  • “Phosphagel”
  • Antacid
  • Astringent Aluminum carbonate Al2 (CO3 )
  • Treatment of phosphatic calculi Alum
  • Al K(SO4 )2 .12H2O
  • Deodorant (Tawas) Aluminum oxide (Al2O3 )
  • Alumina
  • Treatment of silicosis Aluminum acetate
  • Al(CH3COO- )
  • Burrow’s solution, Domeboro’s soln
  • Astringent
  • Dihydroxyaluminum amino acetate ● Gastric antacid ● Magma and tablet Aluminum silicates
  • KAOLIN ● ”native hydrated aluminum silicate”, “china clay”, “porcelain clay”, “Bolus Alba” ● adsorbent & demulcent in diarrhea
  • BENTONITE (Wilkinite) ● “native hydrated colloidal Al silicates” ● mineral soap, soap clay ● suspending agent
  • PUMICE ● ”Na, K, Al silicates”, “Piedra Pomez” ● volcanic origin -dental abrasive, dentifrice ● grades of pumice: flour/superfine, fine, coarse Gallium - Ga
  • Aka: Eka-aluminum
  • Substitute for Hg in manufacture of arclamps.
  • Treatment of cancer related hypercalcemia
  • Lowest melting point (29.75 degrees C)
  • Discovered by Paul-Emile Lecoq de Boisbaudran, 1875
  • Gallia, latin for France Thallium - Ti - 81
  • “Thallos”
  • Discovered by William Crookes, 1861
  • Green shoot or green twig
  • 2nd most toxic metal
  • Antidote: Prussian Blue GROUP III-B ELEMENTS: The Lanthanide Series The Actinide Series Group IIIB: The Scandium Group
  • This is a very long group of elements, which include scandium, yttrium, lanthanum, actinium and the two inner transition series. Scandium
  • AKA: Eka-boron
  • Discovered by Lars Fredrik Nilson, 1879.
  • Occurs in euxenite and gadolinite.
  • A silvery metal which develops a yellow top cast on exposure to air.
  • Used in light weight alloys in aircraft Yttrium
  • Occurs in Yttria. It is present in elevated levels in the moon rock returned by Apollo.
  • Silvery metal and stable in air.
  • Used in the red phosphors in colored- TV tubes and magnets in microwave equipment and lasers.
  • 1794, Johan Gadolin, Isolated Yttria What are the two inner transition series?
  • Lanthanides (rare elements, atomic number 58-71) and
  • Actinides (atomic number 89-103) Lanthanides
  • All lanthanides are f-block elements,corresponding to the filling of the 4f electron shell, except for lutetium which is a d-block lanthanide.
  • The lanthanide series is named after lanthanum.
  • 1787, Ytterby, Sweden in a strange black mineral (gadolonite) Lanthanide series OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

● Lanthanum ● Cerium ● Praseodymium ● Neodymium ● Promethium ● Samarium ● Europium ● Gadolinium ● Terbium ● Dysprosium ● Holmium ● Erbium ● Thulium ● Lutetium

  • All the lanthanide elements (Lathrough Lu) occur in mixtures, which are hard to separate due to similarity in chemical properties.
  • +3 = most stable
  • +2 and +4 = most common
  • Monazite, Xenotime, Euxenite Actinide series
  • All the actinide elements (Ac throughLr) beyond uranium are prepared synthetically and only exist as radioactive isotopes, which are usually not very stable.
  • The actinide series encompasses the 15 chemical elements that lie between actinium and lawrencium on the periodic table, with atomic numbers 90 –
  • The actinide series is named after actinium.
  • The actinide series is included in some definitions of the rare earth elements. IUPAC is currently recommending the name actinoid rather than actinide, as the suffix "-ide" generally indicates ions ● Actinium ● Thorium ● Protactinium ● Uranium ● Neptunium ● Plutonium ● Americium ● Curium ● Berkelium ● Californium ● Einsteinium ● Fermium ● Mendelevium ● Nobelium ● Lawrencium
  • All these elements form compounds with the 3+ oxidation state and also the 2+ state is known
  • Uranium = Klaproth in 1789
  • Thorium = Berzelius, 1829
  • The elements have physical properties that are typical metals. They are all quite reactive chemically and the oxides are basic. Group IV - The Crystallogens
  • 4 valence Group IV A: The Carbon Family
  • C, Si, Ge, Sn, Pb
  • Tetrels
  • Carbon = NM
  • Si, Ge = Metalloids
  • Sn, Pb = Metals CARBON
  • abundant nonmetallic, tetravalent element, has several allotropic forms.
  • exhibits remarkable properties, some paradoxical
  • different forms include the hardest naturally occurring substance (diamond) and one of the softest substances (graphite) known.
  • has great affinity for bonding with other small atoms, including other carbon atoms,
  • and capable of forming multiple stable covalent bonds with such atoms.
  • the greatest importance attaches to its function as the basic building unit of organic compounds.
  • It also occurs in compounds such as carbonates, oxalates, tartrates and acetates.
  • used as a reducing agent in the preparation of many metals
  • relatively inert at room temperature
  • At elevated temperature, it combines directly with OXYGEN, HALOGENS and most other NON-METALS CARBON ALLOTROPES Tetrahedral Lattice Poor electrical conductor Excellent heat conductor Koh-I-Noor = most expensive Activated Charcoal
  • Component of universal antidote
  • Adsorbent
  • Used in Diarrhea and in poisoning
  • ATM = 211 Carbon dioxide (CO2 )
  • Carbonic acid gas
  • Respiratory stimulant (CO poisoning)
  • Treatment of persistent hiccups
  • Used in the manufacturing of soda, carbonated water
  • Dry ice ● Refrigerants ● Solid CO ● Acne, corns, calluses, moles, warts and eczema Carbon monoxide (CO)
  • Cherry red color of blood
  • 210X affinity to hemoglobin
  • Automobile exhaust
  • ANTIDOTE: ● oxygen(100%) ● artificial air (80% Helium; 20% Oxygen) ● hyperbaric O2 (HBOT = Hyperbaric Oxygen Therapy) ● O2 -CO2 mixture Silicon - Si - 14
  • A tetravalent metalloid, silicon is less reactive than its chemical analog carbon
  • Discovered by Jons Jacob Berzellus, 1824
  • Latin, “Silex or Silicis” = “flint” “hardstone”
  • 2nd most abundant element on crust, 27.7% Silicon powder
  • as coarse powder with a dark gray color with bluish tinge Silicon Carbide
  • Carborundum Silica Gels Silicon dioxide
  • Miner’s phthisis, Grinder’s asthma, Potter’s rot
  • Silica
  • Abundant in nature
  • Poisoning: Silicosis (hemoptysis)
  • pneumoconiosis
  • ANTIDOTE: Alumina (Al2O3 ) Amorphous Silicon = dark brown Crystalline = less reactive, dark-gray
  • Feldspar, Kaolinite, Anorthite OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO

→ plumbate (PbO3 2-) IDENTIFICATION TESTS OF IONS Pb2+

  1. K2CrO4 : yellow ppt of PbCrO4 soluble in NaOH
  2. HCl: white ppt of PbCl2soluble in boiling or hot water 𝑆𝑛2+^ 𝑆𝑛4+
  1. 𝐻 2 S Brown ppt of Sns Yellow part of SnS2 𝑆𝑛𝑆 2
  2. 𝐻𝑔𝐶𝐼 2 White ppt of 𝐻𝑔𝐶𝐼 2 turning Gray No reaction Carbon
  • CH3COO- (C2H3O2 - , Ac- , Oac-) → Acids will evolve CH3COOH (vinegar-like odor)
  • CH3COOH heated with C2H5OH → fruity odor, C2H5C2H3O2 (ethyl acetate) CO3 2- and HCO3 -
  1. Acids will evolve CO2 manifested by effervescence (bubbling of gas through the liquid)
  2. Phenolphthalein : dark pink or red for CO3 2-; colorless or light pink for HCO 𝐶 2 𝑂 4 − (oxalates) 𝐶 2 𝑂 4 𝑂 6 − (tartrates) 𝐶 6 𝑂 5 𝑂 7 − (citrates) 1.) 𝐶𝑎𝐶𝑙 2 𝐶 𝑎𝑂 2 𝑂 6 White ppt 𝐶𝑎𝐶 4 𝑂 4 𝑂 6 White ppt 𝐶𝑎 3 𝐶 6 𝑂 5 𝑂 7 a.) HAc Insoluble soluble soluble 2). 𝐴𝑔𝑁𝑂 3 (-) Ag mirror on warming Ag mirror on boiling 3). Pyridine & acetic anhydride (-) Emerald green solution Carmine red solution Group IV B: Titanium Subgroup
  • Ti, Zr, Hf Titanium - Ti - 22
  • 9th most abundant
  • “Titans-Sons of Earth”
  • Powerful reducing agent
  • The principal ore are:
  • Rutile, TiO2 (tetrahedral structure),
  • Brookite, TiO2 (orthorhombic structure),
  • Anatase, TiO2 (orthorhombic structure),
  • Ilmenite, FeTiO3 , and
  • Sphene or Titanite, CaO.SiO2 .TiO Titanium dioxide
  • is used as a pigment since it has good covering power and is quite inert.
  • IDENTIFICATION TEST: ● H202 (acidic sol’n): red color
  • Compounds with oxidation states of 2+ (good reducing agents), 3+ and 4+ (most common).
  • It is difficult to prepare the pure metal due to its affinity for carbon, nitrogen, oxygen and hydrogen. Titanium dioxide
  • Solar ray protectant
  • Lotions & sun blocking creams
  • Opacifying agent MOA: reflects UV rays ● Protective – PABA
  • MOA: absorbs UV rays Zirconium - Zr - 40
  • Arabic”zargun” = “gold-colored”
  • Used as deodorant & antiperspirant
  • Causes pulmonary granuloma formation
  • Can lead to cancer
  • The principal ores are:
  • Zircon, ZrSiO4 , and
  • Baddeleyite, ZrO Hafnium - Hf - 72

FINALS

Group VA and VB (The pnictogens) Group VIII - A (Noble Gasses)

  • The members of the Noble Gases are: ● Helium (He) ● Neon (Ne) ● Argon (Ar) ● Krypton (Kr) ● Xenon (Xe) ● Radon (Rn)
  • The noble gases are colourless, odourless,tasteless, nonflammable gases. They traditionally have been labeled Group 0 in the periodic table because for decades after their discovery it was believed that they could not bond to other atoms;that is, that their atoms could not combine with those of other elements to form chemical compounds Helium
  • 2nd lightest gas
  • Inhalation of pure helium -> donald duck like sound
  • Carrier diluent for medicine
  • Placed in BROWN CYLINDER
  • Artificial gas ● 80% He, 20% O ● BROWN GREEN CYLINDER Neon
  • Advertising purposes:
  • 2nd lightest noble gas
  • Bright reddish orange light Argon
  • the most widely distributed and most abundant of the inert gases. It is present in the air (0.94% v/v) in natural gas, occluded in minerals and dissolved in the oceans and all fresh waters.
  • Used substitute to nitrogen gas, inert atmosphere for pharmaceuticals.
  • Container: RED cylinder Krypton
  • Investigated for its use as inhalational anesthetic
  • Discovered by - Ramsay and Travers Xenon
  • Least abundant noble gas
  • Used in production of flash lamps and arc lamps
  • Anesthetic Action Radon
  • “Niton”
  • Inert gas given off by radium salts as decomposition product OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO
  • It is itself radioactive, being a short half-lived alpha emitter and this property has a limited utility in the treatment of cancer Group VIII B - Triads This group is divided into three triads: ● 1st Triad---- Fe, Co, Ni (Iron Family) ● 2nd Triad----Rh, Ru, Pd (Palladium Family) ● 3rd Triad----Os, Pt, Ir (Platinum Family) Iron
  • A transition metal with an atomic number of 26 - Iron, which is the chief constituent of Earth’s core, is the most abundant element in Earth - Essential to organisms since it’s needed for the creation of hemoglobin.
  • Use = Hemathinic
  • a/e = Toxicity, GIT Distress, Cardiac Collapse, Hemachromatosi
  • Antidote = DEFEROXAMINE
  • Physical State: - lustrous metallic with a grayish tinge
  • Chemical Properties: ● Chemically, the most common oxidation states of iron are iron(II)and iron(III). ● momIron shares many properties of other transition metals, including the other group 8 elements, ruthenium and osmium. ● Iron forms compounds in a wide range of oxidation states, −2 to+7. Iron also forms many coordination compounds; some of them, such as ferrouawcene, ferrioxalate, and Prussian blue, have substantial industrial, medical, or research applications.
  • Sources: ● Iron Pyrite or Fool’s Gold (FeS2) ● Magnetite ● Limonite ● Shooting Star ● Ciderite ● Hematite (Fe2O3) ● Falling Star
  • Toxicity: - GIT distress and cardiac collapse (antidote: DEFEROXAMINE)
  • Compounds and its uses: a) Ferrous Sulfate
  • Green Vitriol / Copperas
  • Most economical, most satisfactory ferrous salt
  • A/E: black stool and constipation b) Ferrous Fumarate
  • BN: Toleron
  • Most stable, for pregnant c) Ferrous Gluconate
  • BN: Fergon
  • Less gastric irritation (in px with peptic ulcer) d) Ferrous Carbonate
  • Chalybeate pills, blaud pills
  • Ferruginous taste e) Iron + NH4CH3COO
  • BASHAM’S MIXTURE
  • Astringent, styptic (causes coagulation) f) Ferrous Ammonium Sulfate
  • Ammonium iron (II) sulfate, Mohr’s Salt g) Ferric Chloride
  • Astringent, styptic, rgt for detection of tannins
  • Blue Point Dyes ● Ferrous Ferricyanide [Fe3(CN)6]2 TURNBULL’S BLUE (cherry red blood) ● Ferric Ferrocyanide [Fe4(CN6)]3 PRUSSIAN BLUE (chocolate brown/brownish red blood) ● Si erric may dalang Ferrero papuntang Russia
  • Alloys Misch Metal (30% Fe 70% Ce) Cobalt
  • Metal present in Vitamin B
  • Essential for development of erythrocytes and hemoglobin
  • Use in manufacture of beer
  • Permanent magnet making
  • Deficiency: Megaloblastic anemia
  • SOURCE: Cobaltite
  • Physical State: ● Anhydrous – blue ● Hydrated – pink ● Pure – pinkish white
  • Chemical Properties: ● Common oxidation states of cobalt include +2 and +3, although compounds with oxidation states ranging from −3 to +5 are also known
  • Compound and its uses: a) Cobaltous Chloride
  • Lover’s Ink, Sympathetic Ink
  • Use as indicator for silica gel beads
  • Silica gel = pink (hydrated), blue (anhydrous) Nickel
  • Old nicks copper, Raney Nickel
  • Found in fossil fuel combustion
  • Metal present in fancy jewelry (fake)
  • Catalyst and Poison
  • Toxicity: Nephritis and Hypotension
  • Identification of Nickel ● Dimethylglyoxime (+ result = green color)
  • Physical State: - lustrous, metallic, and silver with a gold tinge
  • Chemical properties: - The most common oxidation state of nickel is
  • Compounds and their uses: a) Nickelous Ion - Green/bluish green in solution b) Ni+ Pectinate - Treatment of diarrhea - Tomectin c) Ni+ Sulfate - Parasiticide, tonic d) Ni+ Carbonate - Tonic Palladium
  • Effective catalyst Osmium
  • Heaviest and densest metal known
  • Osmic acid + Osmium Tetroxide Staining of microscopic specimen used in electron microscopy (Gram + bacteria) Platinum
  • Catalyst
  • Use in making crucibles and wires
  • Sperrylite – abundant source Cisplatin Cis-diaminedichloroplatinum Antineoplastic Tx of prostate cancer Ototoxic agent Radiopharmaceuticals
  • Every atom of an element is composed of a nucleus, containing protons and neutrons,surrounded by electrons. The atomic number is determinant of elements, in that all the atoms composing an element have the same number of protons and therefore, the same numbers of electrons OUR LADY OF FATIMA UNIVERSITY - ANTIPOLO