Category: Other

Experiments to measure starch yield (III)

100g of each type of rice was mixed with 200g of distilled water at room temperature. The slurries were vacuum packed using a Sammic Vacuum Sealer V410 and heated for 15h at 35ºC in a water bath. Together with the rice and water one magnetic stirring bar was placed inside each vacuum sealed bag to stir the samples during 3min at 1000rpm at room temperature. Then, the sealed bags were opened and sieved during 2min more. Each water-starch solution and sample of sieved rice was weighted separately. After that, the rice grains were washed with 50g of distilled water, stirred at 1000rpm during 2min and sieved.

Experiments to measure starch yield (II)

100g of each type of rice was mixed with 200g of distilled water at room temperature. The slurries were vacuum packed using a Sammic Vacuum Sealer V410 and heated for 20 h at 35 ºC in a water bath. Together with the rice and water one magnetic stirring bar was placed inside each vacuum sealed bag to stir the samples during 3min at 1000rpm at room temperature. Then, the sealed bags were opened and sieved mixing manually during 2min more. Each water-starch solution and sieved rice was weighted separately. After that the rice grains were washed two times with 80g of distilled water and mixed manually during 2min.

First Experiments to measure starch yield

We used five types of rice: arborio, carnaroli, basmati, bomba and sushi rice. 50g of each type was mixed with 100g of distilled water at room temperature. The slurries were vacuum packed using a Sammic Vacuum Sealer V410 and heated for 2.5hat 40ºC in a water bath. Then, the samples were manually mixed during 2min and sieved during 2min more. The water-starch solutions and sieved rice were weighted separately for each genotype. After that, the rice grains were washed with 10g of distilled water and mixed during 2min more. Each of this water-starch solutions was added to the  initial solutions obtained after sieving.

Creaminess: viscosity and friction

Creaminess is the term used for the velvety coating sensation normally assessed in the tongue and palate. It is one of the most relevant textural properties of risotto. Understanding creaminess requieres a multidisciplinary effort: from physical and chemical techniques to sensory perception studies and human-food interaction knowledge. After a review of the literature, we can conclude that it is undoubtedly related to thickness and smoothness. Other factors such as flavour or surface properties may also contribute to the perceived creaminess. An attempt to quantify creaminess was proposed by Kokini and Cussler1:

Creaminess = (Thickness)a(Smoothness)b

where a = 0.54 ± 0.1, b = 0.84±0.1.

Amylose content measures

Amylose content (AC) in rice grains is a relevant parameter for predicting pasting properties of cooked rice as it is often used for  a tenderness prediction. We will perform experiments to measure the AC in different types of rice grains commonly used in risottos, such as carnalori, arborio or vialone nano. For that purpose  we will:

1. Isolate starch

A wide range of methods are available for isolation of starch from rice. They are grouped into three categories: alkali isolation, acid isolation and water isolation. The main objective of the alkali and acid methods is to separate proteins and lipids from starch.

Understanding rice gelatinisation to cook the perfect risotto (Introduction)

The process of cooking risotto is sometimes confusing and several procedures have been proposed to be the key to cook the real risotto, which requires ‘al dente’ rice grains and the adequate creamy texture.

If we want to prepare the ultimate risotto recipe we will have to answer some questions: what type of rice should we use?, should we stir while cooking the rice? , what is the cooking time?

Starch plays a vital role in achieving the desired consistency. Starch is a polysaccharide mainly composed by amylose, fundamentally linear, and amylopectin, highly branched. It presents a semi-crystalline structure. 

Reproducing Pringles Crispness Force Data under different Conditions

Two weeks ago I described the general trends we saw when analysing the force-displacement data from breaking Pringles that had been left unsealed for a varying number of days. I stated that the feature that showed most correlation with the age and hence the crispness was the amount of force peaks after the major force drop. We have since produced a graph showing this trend. The graph is displayed below, we used the standard error derived from the three sets of measurements at each age for the error bars.

To be absolutely sure that we found a trend we decided to redo the measurements under different conditions.

Update on our Progress – Automated Analysis Methods

In my last post I outlined our measuring equipment. We have since attached microphones to the equipment and have measured and recorded data for crisps. We started off looking at normal potato crisps, however, we soon realised that they were all different and it was impossible to get fair samples that only differed in age. We therefore, resorted to Pringles as they all have the same shape, texture and thickness.

We did measurements of singe Pringles to get a clear profile of the breaking but also did measurements with three Pringles stacked on top of each other to simulate a more realistic texture.

Trial Measurements and Data Handling

Our measuring instrument is a guillotine like device that we can use to break chips. For now we practiced with dry spaghetti as they are less messy and easily accessible. The two sensors we use are a load cell at the tooth of our guillotine to measure the force and a potentiometer to measure the displacement change as we move down. We filter the signal from the load cell using a self-made instrumentational amplifier and measure the voltages with an oscilloscope.

The photo of the oscilloscope output below shows a typical measurement outcome when breaking the spaghetti. The blue channel is proportional to the displacement while the yellow channel represents the force on the spaghetti.