Carbohydrates 2024 PDF

Summary

This document contains lecture notes on carbohydrates, covering various aspects of carbohydrate chemistry, including classifications, properties, reactions, and biological importance.

Full Transcript

 Generally considered as substances made up of carbon,
hydrogen and oxygen.
 They are aldehyde or ketone derivatives of polyhydric
alcohols and are therefore termed aldoses or ketoses
accordingly.
 Derived from:
hydrate de carbone
 Most are found naturally in bound form rather than as simple
sugars
▪ Polysaccharides (starch, cellulose, inulin, gums)
▪ Glycoproteins and proteoglycans ( hormones, antibodies, blood
group substances)
▪ Glycolipids (cerebrosides, gangliosides)
▪ Mucopolysaccharides (hyaluronic acid)
▪ Nucleic acids
 Green (chlorophyll-containing) plants produce carbohydrates
 Dietary intake of plant materials is the major carbohydrate
source for humans and animals.
 Carbohydrates are defined as aldehyde or keto
derivatives of polyhydric alcohols.
▪ Eg. Glycerol on oxidation is converted to D-glyceraldehyde, which is
a carbohydrate derived\from the trihydric alcohol (glycerol).
1. Physical appearance:
1. Mono- and disaccharides :white, crystalline
2. Starch- amorphous; cellulose- fibrous
2. Solubility in water
1. Mono- & di- readily soluble in water
2. Starch- slightly soluble
3. Other higher CHO- forms colloidal solutions
4. Cellulose- practically insoluble
3. Sweetness
1. Mono- & di- sweet
2. Starch & cellulose – tasteless
 Fructose – 173.3%
 Invert sugar - 127-130%
 Sucrose - 100%
 Glucose - 74.3%
 Maltose - 32.5%
 Lactose - 16%
 Reducing power
 Osazone formation- reaction with phenylhydrazine
 Reaction with acids:
▪ Disaccharides and polysaccharides will decompose into
monosaccharides in the presence of acids.
▪ Pentoses will dehydrate to form furfural, while hexoses will form
hydroxymethylfurfural.
A. Accdg. To molecular size or to the number of
saccharide groups contained in their molecules:
1. Monosaccharides: These are simple sugars
containing 1 saccharide group
1a. SUBCLASSIFICATION (Accdg. To # of C atoms)
▪ a.Trioses (C3H6O3)- glyceraldehydes, dihydroxyacetone
▪ b.Tetroses (C4H8O4)- erythrose and erythrulose
▪ c.Pentoses (C5H10O5)- xylose, ribose, deoxyribose,
arabinose, rhamnose
▪ d.Hexoses (C6H12O6)- glucose, galactose, mannose, fructose
▪ e.Heptoses (C7H14O7)- mannoheptose, mannoheptulose
Monosaccharides
C.Accdg. To the number of carbon atoms and the type of carbonyl group
present
Aldohexose- glucose Ketohexose- fructose
A. Accdg. To molecular size or to the number of
saccharide groups contained in their molecules:
2.Oligosaccharides: composed of 2-10 disaccharide
groups.
▪ -Oligo from Gk word “oligos”-small or few
a. Disaccharides (C12H22O11)- sucrose, lactose, maltose,
isomaltose

b.Trisaccharides (C18H32O18)-raffinose
A. Accdg. To molecular size or to the number of saccharide
groups contained in their molecules:
3.Polysaccharides (glycans): made up of several
saccharide groups.
3.1. Homopolysaccharides (homoglycans): Polymer of
same monosaccharide units.
▪ Examples—Starch, glycogen, inulin, cellulose, dextrins,
dextrans.
3.2. Heteropolysaccharides (heteroglycans): Polymer of
different monosaccharide units or their derivatives.
▪ Example—Mucopolysaccharides (glycosaminoglycans).
 Building blocks of all CHO
 Either polyhydroxy aldehyde (aldose) or polyhydroxy
ketone ketose
 Names composed of a stem denoting the number of
carbon atoms and the suffix –ose
▪ triose, tetrose, pentose, and hexose signify
monosaccharides with, respectively, three, four, five, and six
carbon atoms
 Six carbon sugars: most abundant in nature
 5 carbon sugars: ribose and deoxyribose (RNA, DNA)
 4 carbon & 7 carbon: photosynthesis & metabolic
pathways
 Chiral center is an atom in a molecule that
has four different groups tetrahedrally bonded
to it.
 A chiral molecule is a molecule whose mirror
images are not superimposable. Chiral
molecules have handedness.
 An achiral molecule is a molecule whose
mirror images are superimposable. Achiral
molecules do not possess handedness.
 Stereoisomers are isomers that have the same
molecular and structural formulas but differ in the
orientation of atoms in space.

2 major structural features that generate stereoisomerism:
▪ (1) the presence of a chiral center in a molecule and
▪ (2) the presence of “structural rigidity” in a molecule.
1. D-GLYCERALDEHYDE 2. DIHYDROXYACETONE
 Aldohexose  Normal blood levels: 70-
 Most abundant 100mg/dL
monosaccharide  Regulated by glucagon &
 Aka: dextrose,grape insulin
sugar, blood sugar  ↑ blood glucose level= DM
 25% less sweet than table
sugar
 Optical activity: +52o
 Primary source of energy
of cells
 Seldom encountered as monosaccharide
 Synthesized from glucose in mammary gland for
use in lactose (milk)
 Aka: brain sugar
 Present in chemical markers used to distinguish
blood types
 Found in pectin and gums
 80 % less sweet than sucrose
 Genetic disease- inability of body to metabolize
galactose
 ↑ galactose in blood and urine
 s/s: vomiting, diarrhea, liver enlargement
 Can cause death in days
 Intervention: remove lactose from diet

 http://www.galactosemia.org/galactosemia.html
 Ketohexose
 Aka: levulose & fruit sugar
 Optical activity: -90o
 Found in fruit juice and honey
 175% sweeter than sucrose
 Commercially prepared from inulin
 Fructose corn syrup (HFCS)- from milled corn
▪ Being used to replace sucrose in prepared foods and
beverages
 Aldopentose
 Component of: RNA & ATP
 It does not occur free in nature but is
widely distributed in combination as
the polysaccharide mannan, e.g. in
ivory nut.
 In the body, it is found as a
constituent of glycoproteins.
 The process whereby a reactant in a chemical reaction
loses one or more electrons. (LEORA)

 Redox in monosaccharides involve:
 All mono- & disaccharides (except sucrose)
contains free aldehyde & ketone group (reducing
power)
 They reduce alkaline metals and are themselves
transformed into organic acid
Type of Target Product formed Example of sugar acids
Oxidizing functional (sugar acids)
Agent group
Weak o.a. Aldehyde ALDONIC ACID Glucose → GLUCONIC ACID
Galactose → GALACTONIC ACID
Strong o.a. -Aldehyde ALIDARIC ACID Glucose → GLUCARIC ACID
- 1o alcohol Galactose → GALACTARIC ACID
Enzymes 1o alcohol URONIC ACID Glucose → GLUCURONIC ACID
Galactose → GALACTURONIC ACID
 Carbonyl group (aldehyde or ketone)
▪ : reduced to -OH using Hydrogen as reducing agent

 D-glucitol: aka. Sorbitol
▪ Uses: moisturizing agents (food & cosmetics); sweetening agent in chewing
gum
▪ Also a major factor in formation of cataract due to diabetes
 Dulcitol: toxic metabolite seen in patients with
galactosemia
 Sugar solution when acted upon by
microorganisms produces ethyl alcohol and carbon
dioxide.

 If the process is allowed to continue for some time,
ACID is produced
 Note: cyclic form of monosaccharides = hemiacetal
▪ HEMIACETAL: An organic compound in which a carbon
atom is bonded to both a hydroxyl group (—OH) and an
alkoxy group(—OR)

Hemiacetal + ROH → acetal

GLYCOSIDE: An acetal formed from a cyclic
monosaccharide by replacement of hemiacetal
carbon –OH with an –OR group
 Glucose → glucoside
 Galactose → galactoside
 -OH of a monosaccharide can react with inorganic
oxyacids to form inorganic esters
 -OH of a monosaccharide can react with an amino
group to produce amino sugar
CHITIN HYALURONIC ACID

 N-acetyl-β-D-glucosamine
 Reducing sugars form characteristic osazone
crystals when heated with phenylhydrazine
(C6H5NHNH2)
 Glucose = Glucosazone = needle-shaped
 Fructose= Fructosazone = needle-shaped
 Mannose= Mannosazone = needle-shaped
 Galactose= Galactosazone = fluffy ball
 Lactose= Lactosazone = fluffy ball
 Maltose= maltosazone = sunflower shape
 Carbohydrate in which two monosaccharide units are
bonded together
 Formed thru a DEHYDRATION reaction
 Bond: glycosidic linkage (C – O - C)
 Aka malt sugar
 Product of starch hydrolysis
 Common in baby foods & malted milk
 Monomers: α-D-glucose & D-glucose
 Glycosidic Linkage: α(1→4)
 Starch
Amylodextrin
Erythrodextrin
Achrodextrin
Maltose
2 Glucose units
 Intermediate in the hydrolysis of cellulose
 Monomers: β-D-glucose & D-glucose
 Linkage: β (1→4)

Hydrolysis reaction:
 Aka: milk sugar
 Monomers: β-D-galactose & D-glucose
 Linkage: β (1→4)
 A genetic condition in which people lack the
enzyme lactase thus causes inability of the GIT to
hydrolyze lactose
 Undigested lactose(intestine) → attract water
molecule → s/s: fullness, discomfort, cramping,
N/V, diarrhea→ bacterial fermentation (gas)
 Aka: table sugar
 Monomers: α-D-glucose & β-D-fructose
 Linkage: α,β(1→2)
 Non-reducing sugar
 Optical activity: +66o
 Sources: Sugar cane (20%) & Sugar beets (17%)
 Sucrose rotation: +66o
 Glucose rotation: +52o
 Fructose rotation: -92o
a) Saccharin
b) Cyclamate
c) Aspartame (nutra-sweet)
d) Sucralose
 Contains many monosaccharide units bonded to
each other by glycosidic linkage
 Aka “glycan”
1. The identity of the monosaccharide repeating
unit(s) in the polymer chain
 homopolysaccharide is a polysaccharide in which only one type
of monosaccharide monomer is present.
▪ Examples: starch, glycogen, cellulose, and chitin
 A heteropolysaccharide is a polysaccharide in which more than
one (usually two) type of monosaccharide monomer is present.
▪ Examples: hyaluronic acid and heparin,
2. The length of the polymer chain.

3. The type of glycosidic linkage between monomer
units.

4. The degree of branching of the polymer chain
 is a polysaccharide that is a storage form for
monosaccharides and is used as an energy source
in cells.
 Examples: Starch and glycogen
 Storage form of glucose in plants
 Monomer: α-D-glucose
 Formed by amylose & amylopectin

Iodine test: blue-black coloration
 Amylose Amylopectin
% in starch 15-20% 80-85%
Monomer Up to 1000 units Up to 100‚000; branch 25-
30
Glycosidic linkage α (1→4) α (1→4)
α (1→6)
 Animal starch
 Stored in liver and muscle cells
 Linkages: α (1→4) , α (1→6)
 monomer: up to 1,000,000 units; branch points
every 8-12 glucose units
 is a polysaccharide that serves as a structural
element in plant cell walls and animal exoskeletons.
 Examples: cellulose and chitin.
 the structural component of plant cell walls,
 the most abundant naturally occurring
polysaccharide.
 Monomer: β-D-glucose ( 5000 units)
 Linkage: β (1→4)
 Cellulase, an enzyme that can hydrolyze cellulose
▪ Cotton is almost pure cellulose (95%)
▪ Wood is about 50% cellulose.
 High fiber food may also play a role in weight control.
 MOA: bind lipids such as cholesterol and carry them out of the body
with the feces. This lowers blood lipid concentrations and, possibly,
the risk of heart and artery disease.
▪ About 25–35 grams daily is a desirable intake
 Monomer: N-Acetyl-β -D-glucosamine
 Linkage: β (1→4)\
 Its function is to give rigidity to the exoskeletons of crabs,
lobsters, shrimp, insects, and other arthropods
 It also occurs in the cell walls of fungi.
 Long, unbranched polysaccharides containing
repeating disaccharide unit:
▪ N-acetylgalactosamine or N-acetylglucosamine
▪ Glucoronate or iduronate
 Location: surface of cells or extracellular matrix
 Uses:
▪ Lubricating fluid in the joints
▪ Structural integrity to cells
▪ Passageway between cells for cell migration
 a polysaccharide with a disaccharide repeating unit
in which one of the disaccharide components is an
amino sugar and one or both disaccharide
components has a negative charge due to a sulfate
group or a carboxyl group.
 Examples: hyaluronic acid and heparin,
 N-acetyl-β-D-glucosamine & D-glucuronate
 50,000 disaccharide units per chain
 Linkages: β(1→3) ; β(1 →4)
 Location: Synovial fluid, vitreous humor, ECM of loose connective
tissue,
 a small polysaccharide with only 15–90 disaccharide
residues per chain
 D-glucuronate-2-sulfate & N-sulfo-D-glucosamine-6-sulfate
 Present in mast cells & is released at the site of injury
▪ Blood anticoagulant
 Pharmaceutical anticoagulant
▪ Source: intestinal or lung tissue of pigs & cows
1. Dermatan sulfate
▪ L-iduronate + N-acetyl-D-glucosamine-4-sulfate
▪ Skin, blood vessels & heart valves
2. Chondroitin sulfate
▪ D-glucuronurate + N-acetyl-D-glucosamine-6-sulfate
▪ Cartilage, bone, heart valves
3. Keratan sulfate
▪ D-galactose + N-acetyl-D-glucosamine-6-sulfate
▪ Cornea, bone, cartilage aggregated with choindroitin sufate
 Aka MUCOPOLYSACCHARIDES
 Linkage of GAGs to the protein:
▪ 2 galactose & a xylulose residue
 generally involves the interaction between the
carbohydrate marker of one cell and a protein
imbedded into the cell membrane of another cell
 a protein molecule that has one or more
carbohydrate (or carbohydrate derivative) units
covalently bonded to it.
 Eg: immunoglobulins
 is a lipid molecule that has one or more
carbohydrate (or carbohydrate derivative) units
covalently bonded to it.
 eg: cerebrosides, gangliosides,