QBManager

CHXII14:BIOMOLECULES

324627 The two forms of D-glucopyranose are called

1 diastereomers

2 anomers

3 epimers

4 enantiomers.

Explanation:

$α$ and $β$ -glucose differ in $C_{1}$ -carbon and are called Anomers

KCET - 2018

CHXII14:BIOMOLECULES

324628 Number of chiral carbon atoms in $β - D (+)$ -glucose is

1 five

2 six

3 three

4 four

Explanation:

The number of chiral carbon atoms in $β$ -D (+)- glucose is five.
supporting img

CHXII14:BIOMOLECULES

324629 Optical rotation of a freshly prepared solution of $α$ -D-glucopyranose is $+ 111^{\circ}$ while that of $β$ - D-glucopyranose is $+ {19.2}^{\circ}$ . In solution, an equilibrium mixture of these two anomers is ${52.5}^{\circ}$ . The percentage of $α$ -form in the equilibrium mixture is

1

36 %

2

64 %

3

52.5 %

4

19.2 %

Explanation:

$α - D - Glucopyranose ⇌ Equilibrium$
$mixture {+ 111}^{\circ} + 52 . 5^{\circ}$
$⇌ β$ -D-Glucopyranose
$+ {19.2}^{\circ}$
Ratio of $α : β -$ form $= (52.5 - 19.2) : (111 - 52.5)$
$= 33.3 : 58.5$
$∴ %$ of $α$ -D-glucopyranose
$= \frac{33.3}{(33.3 + 58.5)} \times 100 = 36.27 %$

CHXII14:BIOMOLECULES

324630 The beta and alpha glucose have different specific rotations. When either is dissolved in water, their rotation changes until the same fixed value results. This is called

1 Epimerisation

2 Racemisation

3 Anomerisation

4 Mutarotation

AIIMS - 2008

CHXII14:BIOMOLECULES

324627 The two forms of D-glucopyranose are called

1 diastereomers

2 anomers

3 epimers

4 enantiomers.

Explanation:

$α$ and $β$ -glucose differ in $C_{1}$ -carbon and are called Anomers

KCET - 2018

CHXII14:BIOMOLECULES

324628 Number of chiral carbon atoms in $β - D (+)$ -glucose is

1 five

2 six

3 three

4 four

Explanation:

The number of chiral carbon atoms in $β$ -D (+)- glucose is five.
supporting img

CHXII14:BIOMOLECULES

324629 Optical rotation of a freshly prepared solution of $α$ -D-glucopyranose is $+ 111^{\circ}$ while that of $β$ - D-glucopyranose is $+ {19.2}^{\circ}$ . In solution, an equilibrium mixture of these two anomers is ${52.5}^{\circ}$ . The percentage of $α$ -form in the equilibrium mixture is

1

36 %

2

64 %

3

52.5 %

4

19.2 %

Explanation:

$α - D - Glucopyranose ⇌ Equilibrium$
$mixture {+ 111}^{\circ} + 52 . 5^{\circ}$
$⇌ β$ -D-Glucopyranose
$+ {19.2}^{\circ}$
Ratio of $α : β -$ form $= (52.5 - 19.2) : (111 - 52.5)$
$= 33.3 : 58.5$
$∴ %$ of $α$ -D-glucopyranose
$= \frac{33.3}{(33.3 + 58.5)} \times 100 = 36.27 %$

CHXII14:BIOMOLECULES

324630 The beta and alpha glucose have different specific rotations. When either is dissolved in water, their rotation changes until the same fixed value results. This is called

1 Epimerisation

2 Racemisation

3 Anomerisation

4 Mutarotation

AIIMS - 2008

CHXII14:BIOMOLECULES

324627 The two forms of D-glucopyranose are called

1 diastereomers

2 anomers

3 epimers

4 enantiomers.

Explanation:

$α$ and $β$ -glucose differ in $C_{1}$ -carbon and are called Anomers

KCET - 2018

CHXII14:BIOMOLECULES

324628 Number of chiral carbon atoms in $β - D (+)$ -glucose is

1 five

2 six

3 three

4 four

Explanation:

The number of chiral carbon atoms in $β$ -D (+)- glucose is five.
supporting img

CHXII14:BIOMOLECULES

324629 Optical rotation of a freshly prepared solution of $α$ -D-glucopyranose is $+ 111^{\circ}$ while that of $β$ - D-glucopyranose is $+ {19.2}^{\circ}$ . In solution, an equilibrium mixture of these two anomers is ${52.5}^{\circ}$ . The percentage of $α$ -form in the equilibrium mixture is

1

36 %

2

64 %

3

52.5 %

4

19.2 %

Explanation:

$α - D - Glucopyranose ⇌ Equilibrium$
$mixture {+ 111}^{\circ} + 52 . 5^{\circ}$
$⇌ β$ -D-Glucopyranose
$+ {19.2}^{\circ}$
Ratio of $α : β -$ form $= (52.5 - 19.2) : (111 - 52.5)$
$= 33.3 : 58.5$
$∴ %$ of $α$ -D-glucopyranose
$= \frac{33.3}{(33.3 + 58.5)} \times 100 = 36.27 %$

CHXII14:BIOMOLECULES

324630 The beta and alpha glucose have different specific rotations. When either is dissolved in water, their rotation changes until the same fixed value results. This is called

1 Epimerisation

2 Racemisation

3 Anomerisation

4 Mutarotation

AIIMS - 2008

CHXII14:BIOMOLECULES

324627 The two forms of D-glucopyranose are called

1 diastereomers

2 anomers

3 epimers

4 enantiomers.

Explanation:

$α$ and $β$ -glucose differ in $C_{1}$ -carbon and are called Anomers

KCET - 2018

CHXII14:BIOMOLECULES

324628 Number of chiral carbon atoms in $β - D (+)$ -glucose is

1 five

2 six

3 three

4 four

Explanation:

The number of chiral carbon atoms in $β$ -D (+)- glucose is five.
supporting img

CHXII14:BIOMOLECULES

324629 Optical rotation of a freshly prepared solution of $α$ -D-glucopyranose is $+ 111^{\circ}$ while that of $β$ - D-glucopyranose is $+ {19.2}^{\circ}$ . In solution, an equilibrium mixture of these two anomers is ${52.5}^{\circ}$ . The percentage of $α$ -form in the equilibrium mixture is

1

36 %

2

64 %

3

52.5 %

4

19.2 %

Explanation:

$α - D - Glucopyranose ⇌ Equilibrium$
$mixture {+ 111}^{\circ} + 52 . 5^{\circ}$
$⇌ β$ -D-Glucopyranose
$+ {19.2}^{\circ}$
Ratio of $α : β -$ form $= (52.5 - 19.2) : (111 - 52.5)$
$= 33.3 : 58.5$
$∴ %$ of $α$ -D-glucopyranose
$= \frac{33.3}{(33.3 + 58.5)} \times 100 = 36.27 %$

CHXII14:BIOMOLECULES

324630 The beta and alpha glucose have different specific rotations. When either is dissolved in water, their rotation changes until the same fixed value results. This is called

1 Epimerisation

2 Racemisation

3 Anomerisation

4 Mutarotation

AIIMS - 2008