BLBS102-c05 BLBS102-Simpson March 21, 2012 12:2 Trim: 276mm X 219mm Printer Name: Yet to Come
96 Part 1: Principles/Food AnalysisFigure 5.11.Titration curve of a 0.10 mol/L (or M) weak acid HA
(Ka= 1 × 10 −^5 ) using a 0.10 mol/L strong base NaOH solution.As the H+ions react with OH−,moreH+ions are produced due
to the equilibriumHA=H++A−,Ka(ionization constant of the acid).Before any NaOH solution is added, HA is the dominant species;
when half of HA is consumed, [HA]=[A−], which is called
thehalf equivalence point. At this point, the pH varies the least
when a little H+or OH−is added, and the solution at this point
is themost effective buffer solution,as we shall see later. The
pH at this point is the same as the pKaof the weak acid. When
an equivalent amount of OH−has been added, the A−species
dominates, and the solution is equivalent to a salt solution of
NaA. Of course, the salt is completely ionized.
Polyprotic acids such as ascorbic acid H 2 -(H 6 C 6 O 6 ) (Vitamin
C;Ka1=7.9× 10 −^5 ,Ka2=1.6× 10 −^12 ) and phosphoric acid
H 3 PO 4 (Ka1=6.94× 10 −^3 ,Ka2=6.2× 10 −^8 ,Ka32.1×
10 −^12 ) have more than one mole of H+per mole of acid. A
titration curve of these acids will have two and three end points
for ascorbic and phosphoric acids, respectively, partly due to
the large differences in their dissociation constants (Ka1,Ka2,
etc.). In practice, the third end point is difficult to observe in the
titration of H 3 PO 4. Vitamin C and phosphoric acids are often
used as food additives.
Many food components (e.g., amino acids, proteins, alkaloids,
organic and inorganic stuff, vitamins, fatty acids, oxidized car-
bohydrates, and compounds giving smell and flavor) are weak
acids and bases. The pH affects their forms, stability, and reac-
tions. When pH decreases by 1, the concentration of H+,[H+],
increases 10-fold, accompanied by a 10-fold decrease in [OH−].
The H+and OH−are very active reagents for the esterification
and hydrolysis reactions of proteins, carbohydrates, and lipids,
as we shall see later. Thus, the acidity, or pH, not only affects the
taste of food, it is an important parameter in food processing.Solutions of Amino AcidsAmino acids have an amino group (NH 3 +), a carboxyl group
(COO−), a H, and a side chain (R) attached to the asymmetric
alpha carbon. They are the building blocks of proteins, polymers
of amino acids. At a pH called theisoelectric point, which
depends on the amino acid in question, the dominant species
is azwitterion, RHC(NH 3 +)(COO−), which has a positive and
a negative site, but no net charge. For example, the isoelectric
point for glycine is pH=6.00, and its dominant species is
H 2 C(NH 3 +)COO−. An amino acid exists in at least three forms
due to the following ionization or equilibria:RHC(NH+ 3 )(COOH)=RHC(NH+ 3 )(COO−)+H+,Ka1
RHC(NH+ 3 )(COO−)=RHC(NH 2 )(COO−)+H+,Ka2.Most amino acids behave like a diprotic acid with two dissoci-
ation constants,Ka1andKa2. A few amino acids have a third
ionizable group in their side chains.
Among the 20 common amino acids, the side chains of eight
are nonpolar, and those of seven are polar, containing OH,
>C O, or SH groups. Aspartic and glutamic acid contain
acidic COOH groups in their side chains, whereas arginine,
histidine, and lysine contain basic NH or NH 2 groups. These
have four forms due to adding or losing protons at different pH
values of the solution, and they behave as triprotic acids. For
example, aspartic acid [Asp=(COOH)CH 2 C(NH 3 +)(COO−)]
has these forms:
AspH+=Asp+H+
Asp=Asp−+H+
Asp−=Asp^2 −+H+
Proteins, amino acid polymers, can accept or provide several
protons as the pH changes. At itsisoelectric point(a specific
pH), the protein has no net charge and is least soluble because
electrostatic repulsion between its molecules is lowest, and the
molecules coalesce or precipitate, forming a solid or gel.Solutions of SaltsSalts consist of positive and negative ions, and these ions are
hydrated in their solutions. Positive, hydrated ions such as
Na(H 2 O) 6 +, Ca(H 2 O) 82 +, and Al(H 2 O) 63 +have six to eight wa-
ter molecules around them. Figure 5.12 is a sketch of the inter-
actions of water molecules with ions. The water molecules point
the negative ends of their dipoles toward positive ions, and their
positive ends toward negative ions. Molecules in the hydration
sphere constantly and dynamically exchange with those around
them. The number and lifetimes of hydrated water molecules
have been studied by various methods. These studies reveal that
the hydration sphere is one layer deep, and the lifetimes of these
hydrated water molecules are in the order of picoseconds (10−^12
seconds). The larger negative ions also interact with the polar
water molecules, but not as strongly as do cations. The presence
of ions in the solution changes the ordering of water molecules
even if they are not in the first hydration sphere.
The hydration of ions releases energy, but breaking up ions
from a solid requires energy. The amount of energy needed