Q.32 Cellulose serves as a structural polymer whereas starch does not. This is because cellulose contains
(A) 𝛽1 → 4 linked glucose monomers and inter-chain hydrogen bonds
(B) 𝛽1 → 4 linked glucose monomers and intra-chain hydrogen bonds
(C) 𝛼1 → 4 linked glucose monomers and inter-chain hydrogen bonds
(D) 𝛼1 → 4 linked glucose monomers and intra-chain hydrogen bonds
The correct answer is (A) 𝛽1 → 4 linked glucose monomers and inter-chain hydrogen bonds. Cellulose is a strong structural polymer because its β-1,4 linkages create long, straight chains that form many hydrogen bonds between adjacent molecules, giving high tensile strength to plant cell walls.
Why Cellulose Is Structural and Starch Is Not
Cellulose is a homopolymer of D-glucose with β-1,4 glycosidic linkages, forming long, straight, unbranched chains. These linear chains align parallel and are held together by extensive inter-chain hydrogen bonds, forming rigid microfibrils that provide mechanical strength to plant cell walls.
Starch (amylose and amylopectin) is made of α-glucose units with mainly α-1,4 (and α-1,6 in amylopectin) linkages, which produce coiled and branched structures better suited for energy storage, not rigidity.
Correct Option (A) – β1 → 4 Linked Glucose Monomers and Inter-Chain Hydrogen Bonds
-
In cellulose, each glucose unit is linked by β-1,4 glycosidic bonds, causing alternate glucose residues to flip and form a straight, extended chain.
-
Multiple cellulose chains run parallel and are joined by inter-chain hydrogen bonds between hydroxyl groups, forming strong fibrils that give cellulose its high tensile strength and structural role in plant cell walls.
Because of this combination of β-1,4 linkage and extensive hydrogen bonding between chains, option (A) correctly explains why cellulose serves as a structural polymer.
Why Option (B) Is Incorrect – β1 → 4 and Intra-Chain Hydrogen Bonds
-
It is true that cellulose has β-1,4 linked glucose monomers, so this part of option (B) is correct.
-
However, the major contributor to cellulose’s structural rigidity is the network of inter-chain (between different chains) hydrogen bonds, not primarily intra-chain (within the same chain) hydrogen bonds, which is why this option is incomplete and misleading.
Thus, option (B) does not fully explain the strong, fibrous nature of cellulose.
Why Option (C) Is Incorrect – α1 → 4 and Inter-Chain Hydrogen Bonds
-
α-1,4 linkages are characteristic of amylose, the linear component of starch, not cellulose.
-
α-1,4 linkages cause the polymer to adopt a helical structure, which is compact and suitable for energy storage but does not favor the formation of long, straight, tightly packed fibers with strong inter-chain hydrogen bonding like cellulose.
Therefore, option (C) incorrectly assigns α-1,4 linkages to cellulose.
Why Option (D) Is Incorrect – α1 → 4 and Intra-Chain Hydrogen Bonds
-
As with option (C), α-1,4 linked glucose monomers describe starch (amylose), not cellulose.
-
While any polysaccharide can have some intra-chain hydrogen bonding, α-1,4 linked, helical starch chains do not form the rigid, extended, fibrillar network needed for structural support, so they are not structural polymers like cellulose.
Thus, option (D) is wrong both in linkage type and in the implied structural role.
Key SEO Points to Remember
-
Cellulose structural polymer vs starch: cellulose has β-1,4 linkages and inter-chain hydrogen bonds, making it rigid and supportive, while starch has α-1,4/α-1,6 linkages and is mainly for energy storage.
-
Structural strength in cellulose arises from linear chains + parallel packing + extensive hydrogen bonding between chains, forming microfibrils in plant cell walls.
