MLVGA-Module-1.pdf

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PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Sublimation
MATTER (Ex: Naphthalene balls)
Solid to gas
Deposition
Gas to solid
Mass + volume (Ex: Dry ice / cardice)
Recombination /
Plasma to gas
SOLID LIQUID GAS Deionization
Ionization Gas to plasma
Indefinite –
Shape

assumes
container shape MATTER CLASSIFICATION
Definite
Indefinite –
Non-
compressible 1. Pure Substance
compressible

Volume

Element – simplest form of substance
Definite
Compound – 2 or more chemicals united
(separated via chemical means)

2. Mixture – 2 or more substance wherein
Molecular
Motion

Gliding Constant individual substance identifies are retained
Vibration
(Ex. Water Falls) Random
(separated via physical means. Alcohol + Water via
distillation)

Homogenous – 1 phase; solution
PLASMA / IONIZED GAS Heterogenous – 2 phases; suspension,
colloid (ex: milk)
4th state of matter
Most abundant state of matter in the CLASSIFICATION BASED ON DEPENDENCE TO THE
universe AMOUNT OF MATTER PRESENT
Has p+ and e-, thus, greatly affected by
magnetic field 1. Extrinsic Property
Ex: Ionized Ne light, aurora, stars, sun Dependent
Length, mass / weight, volume, pressure,
NOTES:
IFA Strength: S > L > G > P
entropy, enthalpy, electrical resistance
Enthalpy (Heat / reaction energy): P > G > L > S
2. Intrinsic Property

PHASE CHANGE Independent
Density / specific gravity (Ex. Water = 1
g/mL or cc), viscosity (resistance to flow),
velocity (m/sec), temperature, color

FUNDAMENTAL CHEMISTRY LAWS

1. Law of Conservation of Mass or Matter

Antoine Lavoiser
Mass / matter is always constant (neither
created nor destroyed)

2. Law of Definite or Constant Proportions
(Proust’s Law)

Joseph Proust
Melting / Fusion /
Liquefaction / Thawing
Solid to liquid Chemical compounds always contain the
Freezing Liquid to solid exact proportion of element in fixed ratio
Evaporation Liquid to gas (by mass)
Condensation Gas to liquid

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 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Ex. H2O →2H + O, C6H12O6 = CH2O ATOMS

3. Law of Multiple Proportion 1. Protons

John Dalton (+) subatomic particle
When 2 elements form more than 1 Atomic no. (basis of electronic
compound, it can be expressed in a fixed configuration)
whole number (by mass) Discovered by Ernes(t) Rutherford; t = +
Ex: CO → 28g/mole, CO2 → 44g/mole
2. Electrons
C = 12 g/mol; O = 16 g/mol
(-) subatomic particle
4. Law of Combining Weights
p+ in uncharged state
Proportions by weight when chemical Negligible weight (1,836 times lighter than
reaction takes place can be expressed in p +)
small integral unit Discovered by:
Ex: MgO → 40g/mole (100%) o JJ Thompson – Cathode ray tube:
Mg = 24g/mole (60%); O = 16g/mole (40%) e- m/2 ratio
o RA MIlikan – Oil drop experiment:
ATOMIC STRUCTURE meas`ure accurate charge and
mass of e-
ATOMIC
CONTRIBUTIONS
MODEL 3. Neutrons
Democritus Atomos “Indivisible”
Matter is made up of No charge
atoms (basic unit)
Atomic mass (Nucleon) = p+ + n0
Postulates: Discovered by James Chadwick
‣ Elements are
Mnemonic: Jimmy (James) Neutron
composed of
indivisible,
indestructible atoms NOTES:
‣ Atoms are alike for a Mass number = # of protons + # of neutrons
given element Atomic number = # of protons
(isotopes) Proton in uncharged state = # of electron
John Dalton Billiard Bell
‣ Atoms are different (proton – charge)
elements that differ in Charge = # of proton = # of electron
size, mass, and other
properties (isobars)
‣ Compounds are 4. Electrochemistry
formed from more than
2 atoms of different Particle separation based on e-
elements
‣ Atoms combine in Ex: Capillary electrophoresis – separation
simple numerical ratios of compounds based on electrophoretic
to form compounds
mobility
Plum pudding /
JJ Thompson
raisin bread
e- in (+) framework Eugene Goldstein – discovered anode rays
Ernest
Rutherford Nuclear (Gold ANODE CATHODE
Atom is mostly empty; Charge (+) Electrode (-) Electrode
foil/a-scattering
(+) particles in nucleus Undergoes Oxidation Reduction
Discovered experiment)
protons (+) AN OX ELECT OUT RED CAT ELECT IN
Niel Bohr Planetary Most used
Modern atomic model Mnemonic OXidation happens in REDuction happens
ANode where in CAThode where
Quantum / Estimates the ELECTrons get OUT ELECTrons get IN
Erwin
Mechanical / probability of finding
Schrodinger
e- cloud an e- in a certain
position (ex. at e-
cloud/orbital)

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 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

NOTES: FORCES OF ATTRACTION
VILEORA – valence increase, lose electrons,
oxidation, reducing agent Intermolecular FA / Van der Waals / Electrostatic
VDGEROA – valence decrease, gain electrons,
reduction, oxidizing agent Between molecule; weak and short-lived
Created by “molecule’s polarizability”;
5. Reducing Agents / Antioxidants exerted when 2 uncharged atoms (n0)
approach very closely
Sulfur dioxide (SO2) Dipole (D) – polar
Sulfates: FeSO4, BaSO4 Induced dipole (DI) – non-polar
Metabisulfate (Na2S2O5)
Keesom Debye London
Thiosulfate (Na2S2O3) H-bonding Orientation Induction Dispersion
Hypophosphite (NaHPO4) (D-D) (D-ID) (ID-ID)
Phosphates (PO4) Strongest IFA > >
Weakest
IFA
Aldehydes H + S, O, N, X Aromatics
Water – Water –
Oxalic Acid (electronegative
water benzene
(Benzene –
atoms) benzene)
Ascorbic Acid

6. Isotopes
Intramolecular FA
Same p+ / atomic no. / element
Within molecule
Differ in atomic mass
Glycosidic – ether bond S-O-S
Non-isotopes: 19F, 127I, 31P
Peptide bond – amide bond AA – peptide
Main isotopes:
– AA bond
o +1: 1H, 12C, 14N, 32S, 35Cl
o +2: 16O, 79Br COVALENT
Nonmetal + nonmetal
Sharing of e-
7. Isobars (Glycosidic and peptide bond)
IONIC
Same atomic mass Transfer of e- Metal + nonmetal (NaCl)
Differ in elements

8. Isotones Valence Shell e- Pair Repulsion (VESPR) Theory

Same neutrons Predicts the geometry of the molecule as
Differ in elements well as any bonded and unbonded
electron pair
9. Isomers
sp, 180°
LINEAR
Same molecular formula Ex: CO2, alkynes, HCN
sp2, 120°
Differ in structure TRIGONAL PLANAR
Ex: Alkenes, formaldehyde
sp3, 109.5°
TETRAHEDRAL / BENT
CHEMICAL BONDS Ex: Alkanes, CCl4, H2O, methane
TRIGONAL
107°
BIPYRAMIDAL
1. Molecule – aggregate of 2 or more atoms in OCTAHEDRAL Exemption to the octet rule
definite arrangement held together by chemical
bonds

2. Ions – with net (+) or (-) charge

3. Empirical Formula – simplest whole number ratio
(might be same with MF); Ex: CH2O vs. C6H12O6

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GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Valence Bond Theory Nonmetals: F > Cl > Br > I (based on
electronegativity)

NOTES:
Co + MgCl2 → NR
Zn + CuSO4 → ZnSO4 + Cu
NaBr + Cl2 → NaCl + Br

NOMENCLATURE OF INORGANIC COMPOUNDS

1. Covalent Compounds

CO: Carbon monoxide
States that bonds are formed by sharing of
SiO2: Silicon dioxide
electron from overlapping atomic orbitals
N2O: Dinitrogen monoxide
(covalent)
CCl4: Carbon tetrachloride
Sigma (S = spherical) – stronger bond
formed, headways overlap 2. Ionic Compounds
Pi (P = dumbbell) – weaker bond formed,
sideways overlap Ex: Pb(NO3)4
Classical: Plumbic nitrate
Molecular Orbital Theory Stock: Lead (IV) nitrate

MONOATOMIC IONS

1. Monovalent

+1 = Grp 1 (H, Li, Na, K ‫ ׀‬Ag)
+2 = Grp 2 (Be, Mg, Ca, Sr, Ba ‫ ׀‬Zn, Cd)
-2 = Grp 6A (Oxide, Sulfide)
-1 = Grp 7A (Fluoride, Chloride, Bromide,
Iodide)

States that bonds are formed from 2. Multivalent (w/ variable charges)
interaction of atomic orbitals from +1, +2 = Hg, Cu
molecular orbitals +1, +3 = Au
Bonding – lower energy (stable) +2, +3 = Fe, Co, Ni
Antibonding – higher energy (unstable) +2, +4 = Sn, Pb
REACTION TYPES +3, +5 = Bi, Sb, As

Synthesis / Combination/ POLYATOMIC IONS
A + B → AB
Direct Union
Decomposition / Analysis AB → A + B OXYGEN CONTAINING POLYATOMIC ANIONS (OXYANIONS)
Single Displacement AB + X → AX + B OXYANIONS SALT OXYACID (Aq)
AB + CD → AC + BD ClO- Hypochlorite Hypochlorous acid (HClO)
ClO2- Chlorite Chlorous acid (HClO2)
Double Displacement / Neutralization ClO3- Chlorate Chloric acid (HClO3)
Metathesis / Exchange (Acid + Base → Salt + Water) ClO4- Perchlorate Perchloric acid (HClO4)
NO2- Nitrite Nitrous acid (HNO2)
Precipitation NO3- Nitrate Nitric acid (HNO3)
SO32- Sulfite Sulfurous acid (H2SO3)
SO42- Sulfate Sulfuric acid (H2SO4)
REACTIVITY SERIES PO43- Phosphate Phosphoric acid (H3PO4)
HYDROGEN CONTAINING POLYATOMIC ANIONS
Metals: Li > K > Ba > Ca > Na > Mg > Al > Mn > Zn > ANION SALT
HCO3- Bicarbonate (Hydrogen carbonate)
Cr > Fe > Cd > Co > Ni > Sn > Pb > H2 > Cu > Ag > Hg HSO3- Bisulfite
> Pt > Au HSO4- Bisulfate

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GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

HPO4-2 Biphosphate NOTES:
H2PO4-1 Dihydrogen phosphate
Magic Number: 1223343 454564567 567 677
Mnemonic:
Si susi pumasok sa pinto
NOTES: Si daddy pumasok sa door
O-containing polyatomic anions (Oxyanions) Pumasok si father daddy (2x)
–ate: common form Pumasok father daddy father
–ite: -1 O to –ate form 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 6s2 4f14 5d10 6p6
hypo…ite -1 O to –ite form 7s2 5f14 6d10 7p6 6f14 7d10 7f14
per…ate +1 O to –ate form
H-containing polyatomic anions
Monohydrogen / bi: with 1H+ ions
Dihydrogen: with 2H+ ions

MOLE RELATIONSHIPS

Avogadro’s Number: 1 mole = 6.022 x 1023 atoms/
molecules

Ex: Calculate the no. of NaOH atoms using
Avogadro’s no. (mass = 20g, MW = 40g/mol)
QUANTUM NUMBERS (FINGERPRINTS)

Principal Quantum Number (n = 1 to 7)
MOLARITY /
FORMALITY MOLALITY (m) NORMALITY (N) PrinSIZEpal
(M)
Main energy level; size of orbital (electron
cloud), distance of e- from nucleus
Ex. O2 = 1s2 2s2 2p4 (n=2)

Factor (f) Azimuthal / Angular Momentum (ℓ = 0 to 3)

Acid (H): HCl = 1, H2SO4 = 2 ASHAPEmuthal
Base (OH): Al(OH)3 = 3 Angular momentum & shape of orbital;
Salt (M): Al2O3 = Al: 3x2 = 6; Na2SO4 = 2 subshell
o ℓ = 0 ─ s: sharp (spherical shape)
ELECTRONIC CONFIGURATION
o ℓ = 1 ─ p: principle (dumbbell
Aufbau Principle shape)
o ℓ = 2 ─ d: diffuse (clover leaf)
o ℓ = 3 ─ f: fundamental
Ex: O2 = ℓ = 1

Magnetic Quantum Number (mℓ = -ℓ, 0, +ℓ)

MagSPACE / magORIENT
Orientation of orbital in space
Ex. O2 = mℓ = -1, 0, +1

Atoms may be built by progressive filling of
energy of main energy sub level (i.e., levels
of lower energy levels are occupied first)
s=2, p=6, d=10, f=14

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GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Magnetic Spin (ms = + ½, - ½) ‣ Effusion – passage of a gas under
pressure through a small opening
Magnetic moment / Rotation Diffusion rate of liquid or gas is directly
Fick’s 1st Law proportional to the conc. gradient
Incomplete; clockwise = ms = +½ (from high to low conc)
Complete; counterclockwise = ms = -½ Henry’s Law of
Decrease T, increase P (sealed
container), more CO2 is dissolved in
Gas Solubility
water
NOTES:
Magnetism Types:
Diagmagnetism – no unpaired e-
Paramagnetism – at least 1 unpaired e- TEMPERATURE

°C = (°F – 32) / 1.8
QUANTUM THEORIES °F = (°C x 1.8) + 32
1. Pauli’s Exclusion Theory K = °C + 273.15
o Absolute temperature
No 2 e- will have same set of quantum o 0K = absolute zero (lowest
number (“exclusive”) possible temperature)
2. Heisenberg’s Uncertainty Theory
SOLUTION
Impossible to predict/ accurately
determine the particle’s velocity (position Solute + solvent
& momentum)
COLLIGATIVE PROPERTIES
3. Hund’s Rule
Dependent on the amount of solute in the
Orbitals are filled up singly before pairing solution
up Ex: vapor pressure lowering, boiling point
Most stable arrangement of e- in subshells elevation (ebullition), freezing point
is the one with greatest no. of parallel depression, osmotic pressure
spins
THERMODYNAMICS
GAS LAWS
Study of energy conversion or
GAS LAWS CONSTANT FORMULA transformation in the universe
Boyle’s T (in K); inverse 𝑃1𝑉1 = 𝑃2𝑉2
Charles P (in atm); DP
PARTS OF THE UNIVERSE

Gay Lussac’s V (in L) 1. System
Combined gas Open System (Non-conservative) – allows
R = 0.08205
exchange of energy and matter
Ideal gas
(Universal gas
T = 0°C / 273K
P = 1 atm / 760 mmHg
Closed System (Conservative) – allows
(STP)
constant) N = 1 mol exchange of energy but not matter
V = 22.4 L

Avogadro’s
Isolated System (Adiabitic Walls) – does
not allow exchange of both energy and
Total pressure in a mixture (non-
Dalton’s interacting gases) is equal to the sum matter
of the partial pressures of each gas
‣ Rate of effusion (diffusion) and speed 2. Surrounding – everything outside the system
gas are inversely proportional to the
square root of their density providing PATH DEPENDENCE
the temperature and pressure are
Graham’s same for 2 gases 1. State Function
‣ Diffusion – gradual mixing of
molecules of one gas w/ the molecules Independent (depends only on initial and
of another gas by virtue of their kinetic
properties final states of system)

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GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Ex: Enthalpy (H), Internal energy (U), Gibb’s Free Energy (ΔG)
Gibb’s Free Energy (G), Entropy (S)
Thermodynamic state function that
2. Non-state Function combines enthalpy and entropy
ΔG = ΔH ‒ TΔS
Dependent
o ΔG < 0 (-) → spontaneous
Ex: Work and heat o ΔG > 0 (+) → nonspontaneous
LAW OF THERMODYNAMICS o ΔG = 0 → equilibrium (no more
work to be done)
Zeroth Law
CHEMICAL KINETICS
If two systems are in thermal equilibrium
respectively with a third system, they must
Study of reaction rates and mechanisms
be in thermal equilibrium with each other
Reaction Rate (M/s)
1st Law: Law of Conservation of Energy
Change in concentration of a reactant or
Energy is neither created nor destroyed
product concentration with time
but can be transformed from one form to
aA + bB → cC + dD
another
Rate Law
Hess’ Law (ΔH)
Expresses relationship of the rate of
Enthalpy (heat/reaction energy): change in
reaction to the rate constant (K) and
independent of reactions/steps that
concentration of reactants raised to some
occurred; only the initial & finals steps
power
would be the basis
aA + bB → cC + dD
+ΔH: Endothermic; COLD (absorbed heat)
–ΔH: Exothermic; HOT (released heat) REACTION RATE THEORIES

2nd Law: Law of Entropy (S) 1. Collision Theory

“No way but UP” Rate of chemical reaction is proportional
For an isolated system, total entropy can to the number of collisions per time
never decrease over time Requirements for effective collision:
Entropy (ΔS) – measure of system’s ✓ Proper orientation
thermal energy per unit temp; ✓ Activation energy (Ea) – minimum
disorderliness of randomness amount of energy required to
o ΔS = (+) → spontaneous; increase initiate chemical reaction
(irreversible) – real case
2. Transition Theory
o ΔS = (-) → nonspontaneous;
constant (reversible) – ideal case Rate depends on activation energy
(in a steady state/ equilibrium) required to form intermediate / transition
o ΔH → does not predict state (where new bonds are formed and
spontaneity old bonds are broken)
3rd Law of Thermodynamics Formation of intermediate complex

If an object reaches absolute zero FACTORS AFFECTING REACTION RATE (DIRECTLY
PROPORTIONAL
temperature (0 K = -273.15 = -459.67°)
Entropy of perfect, solid, crystalline ✓ Nature of reactants – ↑ reactivity ↑
substance is zero at absolute 0 reaction rate (faster)
temperature ✓ Concentration of reactants (except Zero
Order) – ↑ concentration ↑ reaction rate

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GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

✓ Catalyst – ↑ reaction rate; enzymes speed ACIDS AND BASES
up the chemical rxn by lowering Ea
✓ Surface Area – ↑ SA ↓ particle size ↑ ACIDS BASES
reaction rate ↓ reaction time Taste Sour Bitter
✓ Temperature – ↑ Temp ↑ KE ↑ mobility pH 7
(+) Litmus paper Red Blue
of molecules ↑ collision ↑ reaction rate; H2 gas
(+) Metals -
Arrhenius Equation (T, Ea, RR) (corrode metals)
(+) Carbonates / CO2 gas
-
bicarbonates (effervescence)
CHEMICAL EQUILLIBRIUM
Soap: Slippery
(Saponification)
aA + bB ⇌ cC + dD (+) Fat -
NaOH – hard soap
LAW OF MASS ACTION KOH – soft soap

THEORIES
ARRHENIUS
BRONSTED
/ WATER LEWIS
& LOWRY
THEORY
Reaction rate is proportional to the Acid (H+) + H2O = H+ p+ donor e- acceptor
product of the concentrate of the Base (OH-) + H2O = OH- p+ acceptor e- donor
reactants to the power of its coefficient in
a balanced equation Lewis Theory
Keq = 1: No shift (in equilibrium)
Keq > 1: Favors product formation (to the Lewis Acid / Electrophile
right/ forward reaction) o (+) ion or metal
Keq < 1: Favors reactant formation (to the o e- poor specie
left/ backward or reverse reaction) Lewis Base / Nucleophile
o (-) ion or nonmetal
LE CHATELIER’S PRINCIPLE o e- rich specie
Stress reliever PEARSON’S HSAB (HARD-SOFT ACID-BASE)
If an external stress is applied to a system CONCEPT
at equilibrium, the system adjusts to
partially offset the stress as the system Hard-Hard / Soft-Soft
reaches a new equilibrium
Thermodynamically Stronger interaction
CHANGE Hard Acid + Hard Base → Ionic complexes
EQUILIBRIUM EQUILIBRIUM
EXTERNAL STRESSORS Soft Acid + Soft Base → Covalent complex
SHIFT CONSTANT
(Kc) - 25°C
Concentration Yes No
Hard-Soft / Soft-Hard
Pressure & Volume
(For Gases only) Thermodynamically weaker interaction

↑ P = shift to side with Acids & bases Hard Soft
Yes No Ionic radius Small Large
lesser gas moles
Oxidation states High Low
↓ V = shift to side with Polarizability Low High
greater gas moles Electronegativity High Low
Temperature Ions of alkali &
Heavy metals:
alkaline earth
Yes Yes Ag+, Au+, Hg22+/
↑ T, Endo: Right metals: H+, NH4,
Hg2+, Cd2+
↑ T, Exo: Left Examples Ti4+, Cr3+
Catalyst No No H- (Hydride), I-,
OH-, F-, Cl-, CO32-,
SCN-
CH3COO-

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GENERAL CHEMISTRY
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ACID-BASE FORMULA o Q = Ksp → saturated
o Q > Ksp → supersaturated ↓↓
IONIC EQUILIBRIA
GENERAL FORMULA
For weak acids and bases
(pH varies)
(with constant)
Noyes-Whitney Equation – Dissolution rate is
pH = -log[H+] pKa = -log[ka] directly proportional to the solute surface area,
pOH = -log[OH-] pKb = -log[kb] solute conc at boundary layer & diffusion
pH + pOH = 14 pKa + pKb = 14 coefficient
Kw = [H+][OH-] = 1x10-14 Kw = Ka x Kb = 1x10-14

ELECTROCHEMISTRY
Common Ion Effect – Addition of a compound
having an ion in common with the dissolved 1. Spontaneous
substance will result to:
Voltaic cells / galvanic cells
✓ Equilibrium shift Redox reaction (Anode – oxidation;
✓ Suppressed ionization of the dissolved Cathode – reduction)
substance (WA or WB) Electrons migrate from anode to cathode
✓ pH change
2. Nonspontaneous
Henderson-Hasselbalch / Buffer Pair Equation
Electrolytic cells: Electric current is applied
to remove e- and transfer to another cell
(Electroplating)

For buffer solutions (WA + CB or WB + CA) PERIODIC TABLE
pH = pKa (at half neutralization point)
SCIENTIST / LAW CONTRIBUTION / DETAILS
Buffer Solution ‣ 1st extensive list of elements (33)
Antoine Lavoisier
‣ Metals vs Nonmetals
John Wolfgang
Has the ability to resist changes in pH upon Dobereiner
‣ Law of Triads
addition of small amounts of either acid or ‣ Law of Octaves
John Newlands
base ‣ Periods
Weak acid and its CB (salt of WA) ‣ Father of Modern Periodic Table
Dmitri Mendeleev ‣ (Lothar Meyer) Atomic
Weak base and its CA (salt of WB) Mass/Weight
‣ Created Modern Periodic Table
Van Slyke Henry Moseley ‣ Property varies with increasing
atomic number
Buffer capacity Bmax (degree or magnitude ‣ Discovered transuranic elements
of capability to resist change in pH of the ‣ Uranium actinides below
Glenn Seaborg
lanthanides (exhibit radioactivity;
buffer) unstable proton-to-neutron ratio)
‣ Developed a table of atomic
SOLUBILITY PRODUCT CONSTANT Jacob Berzelius weights and introduced letters to
symbolize elements
‣ Every 8th element similar
↑ Ksp = ↑ solubility physicochemical property when
Law of Octaves
arranged according to increasing
Solubility (g/L) – number of grams of solute atomic weight (Ex. H, F, Cl)
dissolved in 1L of saturated solution ‣ Elements (Atomic nos. 1-20) with <
Octet Rule 8 electron “react” to achieve 8
Molar solubility (mol/L) electrons (stable)

Number of moles of solute dissolved in 1L
METAL NONMETAL
of saturated solution Oxides Basic Acidic
Predicting formation of precipitate Good Reducing agents Oxidizing agents
formation (Q ion product constant) – Conductor (of
✔ ✘
electricity)
computed based on initial concentration: Malleable –
o Q < Ksp → unsaturated ✔ Brittle
ability to be

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pounded into PERIODIC TRENDS
thin sheets
Ductile – ability
to be drawn into ✔ ✘
wires
Metallic luster ✔ ✘(except Iodine)
State at RT Solid (except Hg) S, L, G

PERIODIC TABLE

Elements: 118
Periods (Horizontal Rows): 7
Groups / Family (Vertical Columns): 18
Ionization Energy – energy needed to remove
o Grp A: Representative elements
outermost electron in neutral atom
(s & p block)
o Grp B: Transition elements (d Electron Affinity – energy given off when neutral
block) atom gains extra electron (making it more negative)
o Actinides & Lanthanides: Inner
transition elements (f block) Electronegativity
New Elements:
Ability of an atom to attract electron pair
o Nihonium – Nh
to itself, forming covalent bond
o Moscovium – Mc
F: most electronegative (most reactive
o Tennessine – Ts
oxidizing agent)
o Oganesson – Og
O2: 2nd most electronegative
Valence
Valence Atomic Radius – ½ difference between nucleus of 2
GRP A or Elements
e-
charge atoms
H, Li, Na, K, Rb,
1A (Alkali Metals) 1 +1
Cs, Fr, NH4
2A (Alkaline Earth Be, Mg, Ca, Sr, RADIOACTIVITY
2 +2
Metals) Ba, Ra
3A (Boron G.) 3 +3 B, Al, Ga, In, Tl Spontaneous emission of particles /
C, Si │Ge, Sn,
4A (Carbon G.) 4 +/- 4
Pb (+2, +4) ionizing radiation due to unstable nuclei of
N, P │As, Sb, Bi heavier elements
5A (Nitrogen G.) 5 -3
(+3, +5) Non-SI: Curie (Ci) │1 Ci = 3.7 x 1010 decay/
6A (Oxygen G. /
Chalcogens)
6 -2 O, S, Se, Te, Po sec
7A (Halogens) 7 -1 F, Cl, Br, I, At o Discovered: Po & Ra
8A (Inert / Noble/
8 0
He, Ne, Ar, Kr, SI: Becquerel (Bq) | 1Bq = 1 decay/sec
Stable Gases) Xe, Rn
o Discovered: U
REM (Roentgen Equivalent in Man) – unit
GRP B Valence Elements of radiation damage
1B (Coinage M.) +1 Cu (+2), Ag, Au (+3)
Rad / Gray – unit of amount of exposure
2B (Volatile M.) +2 Zn, Cd, Hg & Hg2
3B (Scandium Sc, Y, Lanthanides (La-Lu), to radiation
-
Subgrp) Actinides (Ac-Ir) Radioactive Emissions
4B (Titanium
- Ti, Zr, Hf o Radioisotopes decay randomly
Subgrp)
5B (Vanadium o Beta and gamma can penetrate
- V, Nb, Ta
Subgrp) body tissue
6B (Chromium
- Cr, Mo, W
Subgrp) ALPHA BETA GAMMA
7B (Manganese No mass
- Mn, Tc, Re, Bh Light
Subgrp) Mass Heaviest (4) and charge
(1/2000)
1st Triad: Fe, Co, Ni (+2, +3) (0)
8B (Iron Triad) - 2nd Triad (Light): Rh, Ru, Pd Slowest (0.1 Fast (0.9 Fastest
3rd Triad (Heavy): Os, Ir, Pt Velocity speed of speed of (speed of
light) light) light)

10 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
GENERAL CHEMISTRY
TRANS BY MLVGA, RPh

Penetrating
Low Medium High
Power
Prevented
Paper Al Pb
by

11 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

PERIODIC TABLE OF ELEMENTS FLAME TEST
H Hydrogen
Li Lithium NON-LUMINOUS UNDER COBALT
GROUP IA Na Sodium METALS
FLAME GLASS
Alkali Metals K Potassium Persistent golden
Ammonium Sodium Nil
yellow
Cesium Potassium Violet Crimson red
Cu Copper Lithium Carmine red Purple
GROUP 1B
Ag Silver Calcium Brick red Light green
Coinage Metals
Au Gold Strontium Crimson red Purple
Be Beryllium Barium Yellowish green Bluish green
Mg Magnesium Borate
GROUP IIA Ca Calcium Copper
Alkaline Earth Metals Sr Strontium Green
Thallium
Ba Barium Phosphorous
Ra Radium
Bismuth
Zn Zinc Lead
GROUP IIB
Cd Cadium Arsenic Blue Yellow
Volatile Metals
Hg Mercury Cobalt
B Boron Antimony
Al Aluminum Ammonium Colorless
GROUP IIIA
Ga Gallium
Boron / Icosagens Group
In Indium
Tl Thallium
GROUP IIIB Sc Scandium GROUPS OF ANIONS
Rare Earth Elements Y Yttrium
C Carbon PRECIPITATE FORMED AND VISUAL
# MEMBERS
GROUP IVA Si Silicon RESULT
Carbon Family / Sn Tin w/ 1M AgNO3 + 6M w/ 1M BaCl2 +
HNO3 HNO3
Crystallogens Pb Lead
AgCl – white
Ge Germanium
AgBr – cream
Ti Titanium
GROUP IVB I Cl, Br, I AgI – yellow
Zr Zirconium
Titanium
Hf Hafnium
Insoluble in HNO3
N Nitrogen No ppt
AgS – black,
GROUP VA P Phosphorus
soluble in HNO3
Nitrogen Family / As Arsenic NO2-, S-2,
II
Pnictogens Sb Antimony C2H3O4-
NO2 & C2H3O2
Bi Bismuth
– no ppt
V Vanadium
GROUP VB White ppt of
Nb Niobium
Vanadium SO3, CO3-2, White ppt soluble BaSO4, CaSO4,
Ta Tantalum III
C2O4-2 in HNO3 BaC2O4 soluble
O Oxygen
GROUP VIA in HNO3
S Sulfur
Chalcogens / Ba3(PO3)2 –
Se Selenium
Oxygen Family Ag3PO4 – yellow white
Po Polonium
Ag3AsO4 – brown Ba3(AsO4)2 –
Cr Chromium PO3-3,
Ag2CrO4 – red white
GROUP VIB Mo Molybdenum IV AsO4-3,
BaCrO4 – yellow
Chromium U Uranium CrO4-2
All ppt soluble in
W Tungsten
HNO3 All ppt soluble in
F Fluorine
HNO3
Cl Chlorine
GROUP VII V NO3-, ClO- No ppt
Br Bromine
Halogens White ppt
I Iodine VI SO4-2 No ppt
soluble in HNO3
At Astatine
Mn Manganese
GROUP VIIB
Tc Technetium
Manganese GROUPS OF CATIONS
Re Rhenium
He Helium
Ne Neon GRP I: INSOLUBLE CHLORIDE GROUP
GROUP VIIIA/O Pb+2, Hg+2, Ag+2 Form precipitate w/ dilute HCl
Ar Argon
Noble / Inert Gases
Kr Krypton GRP II: ACID-INSOLUBLE SULFIDES
Ra Radon Do not react w/ HCl but forms
1st Triad: FeCoNi Hg+, Bi+3, Cu+2, precipitate w/ H2S in dilute mineral
GROUP VIIIB 2nd Triad: RuRhoPd Cd+2, As+3, As+5, acid medium
3rd Triad: OsIrPt Sb+3, Sb+5, Sn+2,
Sn+4 Form ppt with (NH4)2S in neutral and
ammoniacal solution

12 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

GRP III: BASE INSOLUBLE SULFIDES ‣ Turmeric paper when dipped into a
Do not react w/ either HCl or H2S in solution of borate acidified w/ HCl →
Fe+2, Fe+3, Al+3,
+3 +6 +3 dilute mineral acid medium produce reddish brown/ orange-red
Cr , Cr , Ni ,
+2 +2 +7 Bromine (Br) ‣ Carbon tetrachloride → orange color
CO , Mn , Mn ,
Form ppt with (NH4)2S in neutral and Carbonate
Zn+2,
ammoniacal solution ‣ In acidic aq. solution → effervescence
(CO3-2)
GRP IV: SULFATE INSOLUBLE GROUPS ‣ Silver nitrate test → white curdy
Do not react w/ either HCl, H2S, or Chloride (Cl) precipitate ppt soluble in ammonia,
(NH4)2S insoluble in nitric acid
Ba+2, Ca+2, Sr+2 ‣ Silver mirror test
Form ppt w/ NH4Cl in neutral / slightly ‣ CaCl2 / Ca(OH)2 (in excess) → no ppt →
acidic medium white ppt w/c dissolve on cooling
GRP V: SOLUBLE / ALKALI METALS Citrate ‣ Pyridine + acetic anhydride (3:1)/
Do not react with any of the rgts stated (C6H5O2) Denige’s reagent (distinguishing test for
citrate & tartrates)
Mg – only grp V cation that will yield a Citrates = Carmine Red
ppt w/ Na biphosphate Tartrates = Emerald Green
Mg+2, Na+, K+, NH4
Na – yellow ppt w/ Co uranyl acetate ‣ NaOH → grayish green slug dissolves in
K – white ppt w/ Na bitartrate Chromium
excess reagent (turn to yellow upon
NH4 – alkalinized vapors turn litmus (Cr)
addition of Na Peroxide)
paper (red → blue)
‣ NaOH → blue ppt of CO(OH)2 (boiling) →
olive green → rose red
‣ Potassium nitrite + acetic acid → yellow
Cobalt (Co)
RADIOPHARMACEUTICALS AND THEIR USES ppt
‣ α-nitroso-β-naphthol → brown ppt
RADIOPHARMACEUTICAL USES soluble in HCl
Tc 99m Phytate
Liver imaging, potency ‣ Dimethylglyoxime → bright red
studies crystalline ppt insoluble in ammonia
Nickel (Ni)
Kidney imaging, ‣ α-nitroso-β-naphthol → reddish brown
Tc 99m Heptagluconate determining renal ppt soluble in HCl
function ‣ Fe+ HCl → deposit of red film on iron
Tc 99m IDA Hepatobiliary studies Copper (Cu) ‣ Potassium ferrocyanide → green ppt.
Tc 99m Etidronate Bone imaging forming a blue solution w/ ammonia
Tc 99m Injection Brain scanning ‣ Chlorine water or potassium
Tc 99m Pyrophosphate permanganate solution → violet color
Cardiac infarct imaging
Iodohippurate I 131 Injection ‣ Sulfuric acid + sodium bisulfate (cold) →
Iodide (I)
Blood plasma volume decolorized
I-131-Human Serum Albumin with cardiac output ‣ Sulfuric acid + oxalic acid (hot) →
determination decolorized
NaI-1125
Localization of ocular Cyanate ‣ Co acetate + acetic acid → azure blue
tumors (CNO) crystal
Na3PO4 Serum Albumin Thyroid function ‣ Silver test → yellow ppt in nitric acid &
Cyanocobalamin 57 Capsule Pernicious anemia Phosphate ammonia
(PO4-3) ‣ Ammonium molybdate → yellow ppt.
soluble in nitric acid & ammonia
COLOR REACTIONS ‣ Flame test → violet or lilac color
‣ Tartaric acid → white ppt of potassium
Potassium (K)
UNKNOWN TESTS bitartrate (only insoluble compound of
‣ H2SO4 + EtOH → fruity odor of ethyl potassium)
Acetate acetate ‣ Ferric chloride → violet color
Salicylate
(C2H3O2) ‣ FeCl3 TS → brownish red / reddish brown ‣ Acid → white ppt of salicylic acid
ppt of basic acetates ‣ HCl → white curdy ppt. insoluble in nitric
Silver (Ag)
‣ Ammonium TS → gelatinous ppt. w/c acid but soluble in ammonia
Aluminum
dissolves in excess of ammonium TS ‣ Flame test → intense golden yellow
(Al)
‣ Aluminon rgt → red lake flame
Sodium (Na)
Ammonium ‣ Acidic Co solution → intense blue ‣ Cobalt uranyl acetate → golden yellow
thiocyanide colored complex at interface Co(CNS)4 ppt
(NH4SCN) ‣ Fe salts → blood red ferric thiocyanate ‣ Silver mirror test
Tartrate
‣ Silver nitrate TS → chocolate brown ‣ Pyridine + acetic anhydride (3:1) →
Arsenates (C4H4O6)
soluble in nitric acid emerald green
(AsO4)
‣ Ammonium molybdate → yellow ppt Thiosulfate
‣ HCl → white ppt turning yellow; SO2
‣ H2SO4 + methanol → green bordered (S2O3)
Borates flame ‣ Hydrogen sulfide → white ppt (only
Zinc (Zn)
(BO3-3) ‣ Turmeric paper (curcumin) → orange + white sulfide)
sodium hydroxide → olive green ‣ (Fluorescein Test) Resorcinol + sulfuric
Saccharin acid + excess NaOH → Fluorescent green
liquid

13 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

ABUNDANCE GLASS

1. Element Made from Silica + Na2CO3
1st – O2 (non-metal)
USP GLASS TYPES AND TEST LIMITS
2nd – Si (non-metal) GENERAL TYPE OF
TYPE GENERAL USE
3rd – Al (most abundant metal) DESCRIPTION TEST
Buffered and
2. Air Gas – N2 (Air = N2 + O2 [71:29]) Highly resistant
Powdered unbuffered
3. Noble Gas – Ar (least abundant – Kr, Xe) I borosilicate
glass aqueous
glass
4. Intracellular and Extracellular Ions solutions
MAJOR / MOST MINOR / 2ND Buffered
ABUNDANT/ MOST aqueous
PRINCIPAL / 1° ABUNDANT / 2° solutions with
CATION PiSo MiCo Treated soda Water pH N = Cl
Added to Quinalizarin Reagent to
Decreasing Acidity: HI > HBr > HCl > HF
differentiate magnesium and beryllium
Ionic property is inversely proportional to
Tox: Bromism (skin eruption, psychosis,
acidity
weakness, HA) – Antidote: NaCl, NH4Cl
Pseudohalogens (Halogenoids — resemble
Kopperschaar’s Solution
halide anions)
o Bromine, 10th normal solution
o CN
o Solution of K bromate and K
o CNS
bromide
FLUORINE (F2) o 0.10N Br solution
o Used in the assay of phenol
Superhalogen (Linus Pauling)
Strongest oxidizing agent IODINE (I2)
Most electronegative element
Heaviest non-metal
Suppressive effect on thyroid (particularly
Easily undergoes sublimation, giving off
when I2 is deficient)
violet vapor
Tox: Fluorosis – mottled enamel, abnormal
Present in thyroid gland, preparation of T3
bone growth
and T4

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 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

o Triiodothyronine (T3) – more Tox: Mn Poisoning = Parkinson-like
active symptoms (resting tremors)
o Thyroxine (T4) – more abundant Potassium Permanganate (KMnO4)
Oldest known germicide, expectorant and o Mineral Chameleon
antifungal o Oxidizing agent
Radioactive isotopes which have a wide o Antiseptic
use in diagnosis and therapy o Antimicrobial (0.02%)
1:5000 (0.02%) – iodine concentration
TECHNETIUM (Tc)
effective to combat many common
bacteria in distilled water Eka-manganese, Technetos
o Greater antibacterial activity vs Cl First element produced artificially
and Br of same strength Used in the preparation of
o Same strength as KMnO4 radiopharmaceuticals (99Tc)
Def: Goiter
Tox: Iodine Poisoning – Antidote: RHENIUM (Re)
Cornstarch, Na thiosulfate
Very rare element
IODINE PREPARATIONS Catalyst for dehydrogenation
Iodine Solution 2% I2 in water + NaI
Iodine Tincture 2% I2 solution + 50% alcohol + NaI
GROUP VIIIA/0: NOBLE / INERT GASES
Strong
Iodine Solution 5% I2 in water + KI
(Lugol’s Solt’n) He, Ne, Ar, Kr, Xe, Ra
Strong Iodine
Tincture
7.5% I2 solution + 88.5% alcohol + KI All Group 0 elements EXCEPT Ra occur in
Phenolated Iodine / the atmosphere and are all monoatomic &
Antibacterial, irritant
Boulton’s Solt’n unreactive
I2 complexed with organic
complexing agent as solubilizer
Valence: 0

Povidone Iodine (Betadine®) HELIUM (He)
Iodophors
Adv: slow release of I2, stability,
reduced irritation, oral tox 2nd lightest gas / air
Disadv: staining, idiosyncratic Container: Brown
reaction
Inhalation of pure He produces a Donald
Duck-like sound or a chipmunk-like sound
ASTATINE (As2)
Pharmacologic Uses:
Only metallic, synthetic, and radioactive halogen ✓ Used to prepare artificial air (20%
O2 + 80% He)
GROUP VIIB: MANGANESE SUBGROUP ✓ Carrier / diluent of medically
Mn, Tc, Re, Bh important gases
Colored, metallic in color NEON (Ne)
MANGANESE (Mn) For advertising purposes (neon lights)
Cofactor involved in: ARGON (Ar)
✓ Protein synthesis
✓ Phosphorylation Most abundant noble gas
✓ Fatty acid and cholesterol Nitrogen substitute as inert atmosphere
synthesis for pharmaceuticals
Necessary for activation of a variety of Container: Dark Green
enzymes such as pyruvate carboxylase By-product of the fractionalization of
Forms a pink ppt w/ S-containing reagent liquid air for possible use as anesthetic
Essential trace element

31 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

KRYPTON (Kr) Pharmacologic Use: Hematinic
Tox: Hemochromatosis (GIT distress,
Least abundant noble gas
cardiac collapse) – Antidote:
Inhalational anesthetic activity
Deferoxamine
Ramsay & Travers – isolated Kr from Ar
Common Ores of Fe:
XENON (Xe) o Hematite (Fe2O3)
o Pyrite / Fool’s Gold (native FeS2)
Virtually ideal anesthetic inert gas o Iron Stone (FeCO3)
sufficiently potent to provide rapid
induction and emergence from surgical IMPORTANT COMPOUNDS OF IRON
anesthesia 1. Ferrous Sulfate (FeSO4)
Investigational with inhalatory anesthetic Green Vitriol
activity
Hematinic agent
RADON (Ra) Most economical and most satisfactory
form of iron preparation
Niton (Ramsay) S/E: Constipation, tarry stool
Synthetic and radioactive noble gas
Treatment of CA (Cervical CA) 2. Ferrous Subsulfate Solution – Monsel’s Solution
Rutherford & Soddy – succeeded in 3. Ferrous Ammonium Sulfate
liquefying the emanation of Radon Mohr’s Salt
Ramsay & Collie – demonstrated the Most important double salt of FeSO4 with
characteristic spectrum of Radon alkali sulfate
NOTES: Radon, Radium – emit alpha particles in their first 4. Ferric Ammonium Sulfate
stage of radioactive decay (treatment of CA)
Ferric Alum
Indicator used in the precipitation method
GROUP VIIIB: IRON TRIAD of analysis

SECOND TRIAD THIRD TRIAD 5. Ferrous Gluconate
FIRST TRIAD
(LIGHT TRIAD) (HEAVY TRIAD) Fergon®
Iron (Fe) Ruthenium (Ru) Osmium (Os)
Hematinic agent
Cobalt (Co) Rhodium (Rh) Iridium (Ir)
Nickel (Ni) Palladium (Pd) Platinum (Pt) Less irritating to the GIT

6. Ferrous Fumarate
IRON (Fe) Toleron®
Hematinic agent
Ferrous (+2) – physiologic; green in solt’n
More stable than FeSO4
Present in tyrosine hydroxylase which
Most tolerable form of Fe
catalyzes the RLS in catecholamines
Less irritating to the GIT than any other Fe
Present in:
preparation
✓ Hemoglobin – O2 transport
✓ Transferrin – transport form 7. Ferrous Carbonate
✓ Ferritin – storage form Chalybeate Pills, Ferruginous Pills, Blaud’s
✓ Cytochrome oxidase (Fe and Cu) Pills
Enhances the absorption of: Hematinic agent
✓ Vitamin C
✓ Copper (Cu) 8. Ferrous Chloride
Most important element in engineering Astringent, styptic
Alloys: Detection test of tannins and phenols
o Steel – Fe + 35% C Will react with:
o Misch Metal – 70% Ce + 30% Fe ✓ Morphine – blue
✓ Benzoic Acid – flesh

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 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

✓ Resorcinol – violet 3. Cobalt Meta-aluminate
Thenard’s Blue
9. Fe + Ammonium Acetate
Test for Al ion (causes Shaver’s Disease)
Basham’s Mixture
Astringent, styptic 4. Cobaltous – used as indicator in silica gel beads
and other dehydrating agents
10. Iron Dextran Injection – IM only
11. Iron Oxide – used as pigment NICKEL (Ni)
12. Iron Pyrite – Fool’s Gold
13. Ferric Ferrocyanide – Prussian Blue Old Nick’s Copper
14. Ferrous Ferricyanide – Turnbull’s Blue Found in fossil fuel combustion
15. Cast Iron / Pig Iron – crude metal obtained from Metal in fancy jewelries
blast furnace that contains 92 – 94% Fe Specified by Dimethylglyoxime Reagent –
16. White Cast Iron (Cementine) – a solid solution red ppt in ammonia
of hard brittle iron carbide formed when molten Ni (+2) – green in solt’n
iron is rapidly cooled
OSMIUM (Os)
17. Gray Cast Iron (Graphite Scales) – formed when
liquid iron is run into sand molds and allowed to Heaviest and densest metal
cool Osmic Acid
Osmium Tetroxide – used in staining
18. Wrought Iron
specimens for electron microscopy
Obtained from removing most of the
impurities from the cast iron PALLADIUM (Pd)
Contains 99.8 – 99.9% of pure Fe
Very malleable and ductile, very tough, Catalyst in finely divided steel
and possesses a high tensile strength PLATINUM (Pt)
19. Reduced Iron – Ferric oxide + Hydrogen Noble metal – low oxidation and reactivity
COBALT (Co) Cisplatin (Cis-diaminedichloroplatinum)
o Aka Platinol
(+) Permanent magnets, Vit B12 o Platinum complex
(Cyanocobalamin, as Co2+) o Antineoplastic agent prepared by
Enhances beer’s foam quality – Colt 45 treating K Chloroplatinate +
Essential in the development of Ammonia
erythrocyte and hemoglobin o Used in the tx of prostate CA
Pink in appearance
Vogel’s Reaction (Test for Cobaltous ions WATER
w/ Ammonium Thiocyanate) – (+)
Beautiful blue Universal solvent
Def: Megaloblastic and Pernicious Anemia High dielectric constant
– Test: Schilling’s Test Water Vapor – best expectorant
Natural / Mineral / Well Water
IMPORTANT COMPOUNDS OF COBALT o Not fit for drinking
1. Cobalt Chloride o Contents: Dissolved minerals,
Lover’s Ink, Sympathetic Ink atmospheric gases, suspended
organic matter
Indicator in silica gel beads (desiccator)
Hard Water – (+) dissolved minerals (Ca,
2. Cobalt Zincate Mg)
Rinmann’s Green
Test for Zn ion (causes Metal Fume Fever) WATER
TEMPORARY PERMANENT
HARDNESS
Sulfide and
Ca and Mg Salt Bicarbonate
Chloride

33 | @blueveetriol | PhLE MODULE 1
 PhLE MODULE 1 – PHARMACEUTICAL CHEMISTRY
INORGANIC CHEMISTRY
TRANS BY MLVGA, RPh

Water Softening Boiling (CaCO3 Ion exchange MONOPROTIC DIPROTIC TRIPROTIC
Method ppt) + Ca(OH)2 resins ACIDS (BAHN) ACIDS (COCHS) ACIDS (PC)
Carbonic Acid
HARD WATER (H2CO3)
Benzoic Acid
Oxalic Acid
(+) NaHCO3, Na2SO4, MgSO4 (C6H5CO2H)
Alkaline Water (H2C2O4) Phosphoric Acid
(appreciable qqty) Acetic Acid
Chromic Acid (H3PO4)
Saline / Purgative (CH3CO2H / HOAc)
(+) NaCl, Na2SO4, MgSO4 (high qtty) (H2CrO4) Citric Acid
Water Hydrochloric Acid
Hydrogen (C6H8O7)
Carbonated (+) Ca and Mg carbonates – (+ acid) → (HCl)
Sulfide (H2S)
Water CO2 (effervescence) Nitric Acid (HNO3)
Sulfuric Acid
Chalybeate (+) Fe (soln/susp; ferruginous state – (H2SO4)
Water (air) → forms ferric oxide/hydroxide
Lithia Water (+) Li carbonate/ chloride
(+) H2S and → deposit S upon atm
Sulfur Water
exposure HYDROCHLORIC ACIDS AND SALTS
Siliceous Water (+) Soluble alkali silicates
Baryta Water (+) Ba(OH)2 salt solution
HYDROCHLORIC ACID (HCl)
POTABLE WATER Muriatic Acid
USP Methods: Distillation, reverse (+) Gastric Juice: Chief cells secretes
osmosis, ion exchange pepsinogen –(HCl)→ Pepsin
Treated water (fit to drink) HCl – secreted by parietal cells
Insoluble Matter Removal: coagulation,
DILUTED HCl (10% w/v solution)
settling, filtration
Microorganism (Coliform) Destruction: Used in the treatment of gastric achlorhydria – low
Aeration, chlorination, etc. HCl in stomach
Palatability Improvement: Aeration,
filtration with charcoal SODIUM CHLORIDE (NaCl)

WATER FLUORIDATION Dentritic / rock / table / sea / solar salt
Na+ replenisher
(+) Na fluorosilicate – Anticariogenic property (parts Tonicity adjusting agent, condiment,
per billion) preservative
PURIFIED WATER (NP) If acid dissociate in water = Na+ + C-
Oral Rehydration Salt (ORS)
Ingredients of official preparations, tests, o NaCl + KCl + Na citrate + glucose
assays (unless specified) o Diarrhea, Dehydration
Can be parenteral if stated “water for
ISOTONIC SOLUTIONS
injection” Normal Saline
0.9% NaCl in water
Solution (NSS)
STRONG ACIDS AND BASES Ringer’s Solution NaCl + KCl + CaCl2
Lactated Ringer’s /