chemical properties of sugar
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Transcript chemical properties of sugar
MONOSACCHARIDES
SUGAR:
Simple sugars include
monosaccharides and
disaccharides. The
chemical names of the
six sugars to be
discussed, end in "ose" which means
sugar.
DISACCHARIDES
POLYSACCHARIDES
MONOSACCHARIDES
Are linked by glycosidic bonds (joining of 2 hydroxyl groups of sugars by splitting out
water molecule) to create larger structures.
The monomers of carbohydrates are called monosaccharides and are also called simple
sugars.
Monosaccharides include these simple sugars : Glucose, Fructose, Galactose
The prefix mono means "one" these sugars consist of a single ring of atoms.
Monosaccharides are the building blocks of other carbohydrates, such as disaccharides
and starch.
Glucose is the most abundant sugar in nature. Fructose is the sweetest natural sugar. it
is about 1.3 times as sweet as white sugar. Galactose is almost always linked to glucose to
make milk sugar which is a disaccharides.
DISACCHARIDES
Contains two or more monosaccharides units linked together. They are also
called double sugars which includes : Sucrose, Maltose, Lactose
Sucrose (GFS) is commonly two simple sugar joined together (Glucose and fructose).
Sucrose is the chemical name which is called table sugar, white sugar, granulated sugar or
simply sugar.
Maltose (G²M) is simply two glucose units connected together. It is fairly abundant in
germination of seeds and is produced in the manufacturing of beer.
Lactose (GLUGALALA) is called milk sugar which is present in milk and milk products.
As per the sweetness is considered lactose is ranked as the lowest sugar. Most
carbohydrates are considered as plant products, lactose is one of the few considered
exclusively from the animal products.
POLYSACCHARIDES
Are made up of many monosaccharides bonded together
by glycosidic bonds. The type and the arrangements of
sugar molecules determine the shape and form of the
polysaccharides.
Some polysaccharides have an orderly linear appearance,
whereas others are shaped like branches. The three most
common polysaccharides are starch, glycogen, fiber.
Furfural formation
Enolization
Oxidation
Reduction
Osazone formation
A reducing sugar is a carbohydrate that is oxidized by a weak oxidizing agent (an oxidizing agent capable of
oxidizing aldehydes but not alcohols such as the Tollen’s test) in basic aqueous solution. The characteristic
property of reducing sugars is that, in aqueous medium, they generate one or more compounds containing
an aldehyde group.
eg. 1: α-D-glucose, which contains a haematical group and, therefore, reacts with water to give an open-
chain form containing an aldehyde group.
FURFURAL FORMATION
When treated with concentrated sulfuric acid glucose
undergoes dehydration and results in the formation of
hydroxy methyl furfural.
Monosaccharides are normally stable to dilute acids, but are dehydrated by
strong acids. D-ribose (Pentoses) when heated with concentrated HCl yields
furfural (cyclic anhydride). D-glucose(Hexoses) under the same conditions
yields 5-hydroxymethyl furfural
The furfural derivatives can condense with phenolic compounds to give colored
products. This forms the basis for Molisch test. This test is a sensitive test but it
is nonspecifically given by all carbohydrates. Alpha nephthol is used in this test.
A purple colored ring develops if carbohydrate is present.
Similar to this Seliwanoff Test is undertaken with Resorcinol, a cherry red color
is produced if fructose is present.
The other tests are Anthrone test and Bial’s test.
Sugars are weak acids and can form salts at high pH. A1,2-enediol salt is formed as
the result. This allows the interconversion of D-mannose, D-fructose and D-glucose.
The reaction is known as the Lobry de Bruyn-Alberta von Eckenstein reaction.
Enediols obtained by the action of base are quite susceptible to oxidation when
heated in the presence of an oxidizing agent. Copper sulfate is frequently used as the
oxidizing agent and a red precipitate of Cu2O is obtained. Sugars which give this
reaction are known as reducing sugars. Some of the frequently used solutions for
detecting the presence of reducing sugars in biological fluids are as follows-
1) Fehling’s solution: KOH or NaOH andCuSO4
2) Benedict’s solution: Na2CO3 and CuSO4
3) Clinitest tablets are used to detect urinary glucose in diabetics
oxidation is the loss of electrons. It happens when an
atom or compound loses one or more electrons. Some
elements lose electrons more easily than others. These
elements are said to be easily oxidized.
When an atom or compound is oxidized, its properties
change. For example, when an iron object undergoes
oxidation, it is transformed because it has lost
electrons.
REDUCTION (sugar alcohol formation)
Sugar alcohol are produced by the reduction of of the carbonyl group (Aldehye/Ketone group) of monosaccharides.
The reaction can be represented as follows :
a) Reduction of aldoses take place at C-1 to form sugar alcohol.
b) Reduction of Ketone sugars takes place at C-2 to form sugar alcohol.
Under specific conditions of temperature and pressure, sugars can be reduced in the presence of hydrogen. The resultant
product a polyol or sugar alcohol (alditol) but reduction of ketose sugar produces a new asymmetric carbon atom (See figure),
thus two types of sugar alcohols can be produced, which are epimer of each other.
Examples
1) Glucose form Sorbitol (glucitol)
2) Mannose forms mannitol
3) Fructose forms a mixture of mannitol and sorbitol
4) Galactose forms Dulcitol
5) Glyceraldehyde gives glycerol
6) Ribose forms Ribitol
Structure and Significance of some Sugar alcohols1) Sorbitol- In Diabetes Mellitus excess of Glucose is converted to Sorbitol. The osmotic effect of Sorbitol is responsible for many
of the complications of diabetes mellitus e.g. Cataract formation in lens. Clinically sorbitol is dehydrated and nitrated to form
Isosorbide mono and dinitrate, both of which are used for the treatment in Angina.
2) Mannitol- Mannitol is also osmotically active and is used as an infusion to lower the intracranial tension by producing forced
diuresis.
3) Dulcitol- excess of galactose in galactosemia is converted to Dulcitol. The osmotic effect of Dulcitol is similar to Sorbitol and is
responsible for premature cataract formation in affected patients of galactosemia.
4) Xylitol- is produced in Uronic acid pathway of Glucose utilization; it is subsequently oxidized to produce D- Xylulose.
5) Glycerol- is produced from Glyceraldehyde. Glycerol is used for the formation of Triglycerides and phospholipids. Clinically
glycerol is nitrated to form Nitroglycerine , that is used for the treatment of angina.
6) Myo- Inositol- It is hexahydroxy alcohol, also considered a vitamin It is present in the plasma membrane and acts as a second
messenger for the action of hormones.
7) Ribitol- is used in the formation of vitamin B2- (Riboflavin
Osazones are a class of carbohydrate formed when sugars are reacted with
excess of phenylhydrazine.the reaction to identify sugars
whose stereochemistrydiffered by only one chiral carbon.
The reaction involves formation of a pair of phenylhydrazone functionalities,
concomitant with the oxidation of the hydroxymethylene group adjacent to the
formyl center. The reaction can be used to identify monosaccharides. It
involves two reactions.
Firstly glucose with phenylhydrazine gives glucosephenylhydrazone by
elimination of a water molecule from the functional group. The next step
involves reaction of one equivalent of glucosephenylhydrazone with two
equivalents of phenylhydrazine (excess).
First phenylhydrazine is involved in oxidizing the alpha carbon to a carbonyl
group, and the second phenylhydrazine involves in removal of one water
molecule with the formyl group of that oxidized carbon and forming the
similar carbon nitrogen bond. The alpha carbon is attacked here because its
more reactive than the others.
Osazones are highly coloured and crystalline compounds and can be easily
detected. Glucose gives broomstick or needle shaped crystals with this whereas
maltose gives sunflower shaped crystals.
Acetal or ketal derivatives formed when a monosaccharide reacts with an alcohol are called glycosides. They are formed by the
reaction of the hydroxyl group of anomeric carbon (hemiacetal or hemiketal)of monosaccharide with hydroxy group of second
molecule with the loss of an equivalent of water.
The second molecule may be1) Another sugar (Glycon)- e.g. formation of disaccharides and polysaccharides.
2) Non Carbohydrate (Aglycon)- such as Methanol, Glycerol, Sterol or Steroids etc.
In naming of glycosides, the” ose” suffix of the sugar name is replaced by “oside”, and the alcohol group name is placed first. For
example, D-glucose reacts with methanol in an acid-catalyzed process: the anomeric carbon atom reacts with the hydroxyl group of
methanol to form two products, methyl α -D-glucopyranoside and methyl β -D-glucopyranoside. These two gluco pyranosides differ in
the configuration at the anomeric carbon atom. The new bond formed between the anomeric carbon atom of glucose and the hydroxyl
oxygen atom of methanol is called a glycosidic bond specifically, an O-glycosidic bond. See figure below.
Showing Methyl Glucopyranoside
The anomeric carbon atom of a sugar can be linked to the nitrogen atom of an amine to form an N-glycosidic bond. Nucleosides are
adducts between sugars such as ribose and amines such as adenine (the linkage between them is N-Glycosidic linkage).
Examples of Glycosides-Glycosides are present in many drugs, spices and in the constituents of animal tissues. Glycosides comprise
several important classes of compounds such as hormones, sweeteners, alkaloids, flavonoids, antibiotics, etc. The glycosidic residue can
be crucial for their activity or can only improve pharmacokinetic parameters.
1) Cardiac Glycosides
Cardiac glycosides all contain steroids or genin component as aglycone in combination with sugar molecules. These include
derivatives of digitalis and strophanthus such as oubain.
2) Other glycosides such as streptomycin are used as antibiotics. Phloridzin is another glycoside which is obtained from the root and
bark of apple tree. It blocks the transport of sugar across the mucosal cells of small intestine and also renal tubular epithelium. It
displaces Na+ from the binding site of “carrier protein” and prevents the binding of sugar molecule and produces Glycosuria.
3) Glycosides of vitamins, both hydrophilic and lipophilic often occur in nature. Glycosylated vitamins have an advantage over the
respective aglycone in their better solubility in water (especially the lipophilic ones), stability against UV-light, heat and oxidation,
reduction of the bitter taste and odor(e.g., thiamine), and resistance to an enzymatic action. Some of the vitamin glyco conjugates have
altered or improved Pharmacokinetic properties.