Abstract
Depending upon the physicochemical structure and properties of starch, the rate and extent of starch digestion can vary significantly from being very rapid to a much slower process and in some cases being virtually indigestible. The purpose of this mechanistic research project is to produce kinetic and structural data that provides an improved understanding of the interaction between porcine pancreatic α-amylase (PPA) and starch structures.Native, gelatinised and retrograded starch samples (stored between 0-96h) were digested with PPA to produce digestibility plots from which Michaelis-Menten kinetic parameters were determined. Logarithm of slope (LOS) plots of digestibility curves for prolonged incubations were also constructed to allow the rate constant (k) and the total digestible starch (C∞) to be calculated.
Following gelatinisation, the kcat/Km ratio increased drastically compared with native samples. For retrograded starches, the kcat/Km decreased relative to the non-retrograded samples, with the biggest difference being noticed in wheat, potato and high amylose maize starches. Surprisingly, the binding facility of α-amylase to starch did not change over 96h, indicated by the Km values. The LOS plots showed no change in k but a decrease in C∞ when gelatinised starch was stored at room temperature. The LOS plots also revealed a single rate constant for processed starches with only native starches being digested in distinct rapid and slower phases.
Evidence for the structural changes that occur during starch processing was
obtained using Fourier transform infrared spectroscopy (FTIR), differential
scanning calorimetry (DSC) and X-ray diffraction (XRD). The results showed
that the degree of crystalline/ordered structure increased upon storage.
Isolated retrograded starch from high amylose maize was harvested and
physically and chemically characterised. The results indicate that retrograded
starch material is mainly amorphous with small amounts of crystallinity. Upon
digestion with α-amylase however, no starch products were detected indicating
that the mainly amorphous retrograded starch material is resistant to digestion.
The inhibition studies showed that retrograded starch acts as a non-competitive
inhibitor of PPA and can therefore still bind to the enzyme but no amylolysis
occurs.
| Date of Award | 2015 |
|---|---|
| Original language | English |
| Awarding Institution |
|
| Supervisor | Peter Ellis (Supervisor) & Peter Butterworth (Supervisor) |