Carbohydrates - PowerPoint PPT Presentation

1 / 19
About This Presentation
Title:

Carbohydrates

Description:

... give an aldehyde group on carbon 1; this process is called keto-enol tautomerism. Under basic conditions fructose changes to an aldehyde by keto-enol tautomerism ... – PowerPoint PPT presentation

Number of Views:624
Avg rating:3.0/5.0
Slides: 20
Provided by: joa107
Category:

less

Transcript and Presenter's Notes

Title: Carbohydrates


1
Carbohydrates
  • Compounds containing C,H, and O
  • General formula Cx(H2O)y
  • Contain two functional groups CO -OH
  • Classification based on
  • size of base carbon chain
  • number of sugar units
  • location of CO
  • Stereochemistry

2
Types of Carbohydrates
  • Classification based on the number of sugar units
    in total chain
  • Monosaccharides single sugar unit
  • Disaccharides two sugar units
  • Oligosaccharides 3 to 10 sugar units
  • Polysaccarides more than 10 units
  • Chaining is done through bridging oxygen atoms
    which are called glycoside bonds or glycosidic
    bonds

3
Types of Carbohydrates
  • Based on location of CO
  • Monosaccharides with six carbons (hexoses) They
    cannot be hydrolyzed into smaller units, unlike
    disaccharides and polysaccharides.
  • Aldoses (aldehyde group)
  • Ketoses (ketone group)
  • C6H12O6 Glucose aldehyde group (blood
  • sugar, grape sugar or
    dextrose)
  • Galactose aldehyde group
  • Fructose ketone group

4
Types of Carbohydrates
  • Based on the number of carbons in the chain
    triose, tetrose, pentose, hexose, etc

5
Types of Carbohydrates
  • Disaccharides 2 monosaccharides from an a or ß
    1,4- glycosidic bond with the loss of water.
  • Maltose (glucose glucose)(germinating grains)
  • Lactose (glucose galactose)(milk, yogurt, ice
    cream)
  • Sucrose ( glucose fructose) (table sugar,it is
    found in sugar cane, sugar beets)

6
Types of Carbohydrates
  • Polysaccharides long-chain polymers
  • Starch rice, wheat, beans, potatoes and cereals.
  • Amylose 20 of starch
  • a-D-glucose molecules connected by
    a1,4-glycosidic bonds in a continuous (straight)
    chain.
  • 250-4000 glucose units
  • Amylopectin 80 of starch
  • a-1,4-glycosidic bonds connect most of the
    glucose molecules
  • Every 25 glucose units there are branches of
    glucose attached by a-1,6-glycosidic bonds
    between carbon 1 of the branch and carbon 6 in
    the main chain.
  • Glycogen is found in liver and muscle and is made
    up
  • of glucose units. a-1,4-glycosidic bonds and
    a-1,6-
  • glycosidic bonds

7
Types of Carbohydrates
  • Polysaccharides long-chain polymers
  • Cellulose wood and plants
  • ß-1,4-glycosidic bonds connect the glucose
    molecules to form unbranched chains that align in
    parallel rows held in place by hydrogen bonds
    which makes it more resistant to hydrolysis.

8
Stereochemistry and Stereoisomers
  • Stereochemistry
  • Study of the spatial arrangement of the molecules
  • Stereoisomers
  • Different spatial arrangements
  • Different properties
  • Same order and types of bonds
  • Enantiomers
  • They are mirror images of each other but they
    cannot be overlapped
  • Designated by D- or L- at the start of the name

9
Stereoisomers enantiomers
  • Chiral carbon (asymmetric carbon)
  • a carbon that has 4 different groups
    attached to it
  • You must have at least one asymmetric (chiral)
    carbon in order to have stereoisomers

10
Physical Properties
  • Optical activity
  • ability to rotate plane polarized light
  • Dextrorotatory
  • Rotate to the right
  • Usually D isomers
  • Use symbol
  • Levorotatory
  • Rotate to the left
  • Usually L isomers
  • Use - symbol

11
D-Sugars
  • All monosaccharides have more than one chiral
    carbon, they are classified as
  • D-sugars if the chiral carbon furthest away
    from the carbonyl group has the same
    configuration as D-glyceraldehyde. If they are
    dextrorotatory this is shown by a () after the
    D if laevorotatory by
  • a (-).

12
Fischer Projections
  • A tetrahedral carbon represented by two crossed
    lines
  • A horizontal bond to an asymmetric (chiral)
    carbon designates bonds in the front plane of the
    page
  • Vertical bonds are behind the plane of the page
  • Places the most oxidized group at the top

13
Important Monosaccharides
14
Intramolecular Cyclization
  • In glucose the OH on carbon 5 forms a hemiacetal
    bond with the aldehyde group. The new OH group on
    carbon 1 may be drawn below carbon 1 ---- a form
  • above carbon 1-----ß form
  • Haworth projections can be used to help see the a
    and ß orientations

15
Haworth Structures
  • ß a
  • Change in rotation of solution is called
    mutarotation.
  • The two forms are called anomers and the switch
    is called epimerization. The cyclic structures
    are hemiacetals.

16
Haworth Structures
ß-()-ribose D-()-galactose
a-D-(-)-fructose
17
Reducing Sugars
  • Monosaccharides and most of disaccharides are
    hemiacetals so they can be oxidized to carboxylic
    acids, so they are reducing sugarsglucose,
    galactose, fructose
  • Cu2 from the Benedict reagent is getting reduced
    to Cu(Cu2O a green to red precipitate), so it is
    the oxidizing agent
  • They react with alcohols at C1 forming an ether
    linkage known as a glycosidic bond to form
    disaccharides.

18
Reducing Sugars
  • Ketoses are also reducing sugars, because the
    ketone group on carbon 2 isomerizes to give an
    aldehyde group on carbon 1 this process is
    called keto-enol tautomerism
  • Under basic conditions fructose changes to an
    aldehyde by keto-enol tautomerism
  • Polysaccharides are NOT reducing agents.

19
Disaccharides
Cellobiose ß(1-4)
maltose a(1-4)
Lactose ß(1-4) sucrose ß(1-2) Sucrose has both
sugars as acetals, no Benedicts reaction is not a
reducing sugar.
Write a Comment
User Comments (0)
About PowerShow.com