Leon
Alizarol Test
1. ALIZAROL TEST
1.1 OBJECTIVE OF THE ALIZAROL TEST
The Alizarol test, due to its simplicity as well as its suitability to point out more than one defect of milk is a practical and well-suited procedure to test raw milk for acceptability, either on the farm or from the tanker at the factory. The main objective of the test is to indicate milk in which an unaccepted level of acidity has developed.
The stability of the protein complex in milk is destabilized by acid and therefore a positive alizarol test is also an indication of the heat stability of milk (i.e. the resistance of the protein complex against the denaturation by heat). The test is therefore also popular where the heat stability of milk proteins is of importance during processing, e.g. during the production of milk powder or UHT milk.
By adding the pH-indicator alizarine to the solution an indication of whether the milk is abnormally sour or alkaline can be obtained.
For an online training course on the alizarol test that you can use forever in your dairy business to re-train and train new employees at $45 go to:
1.2 FACTORS AFFECTING THE TEST
1.2.1 Acidity
The presence of lactic acid is the most important cause of a positive alizarol test. At the higher acid level (lower pH ) the protein suspension in milk will be less stable with the result that protein flocculation (coagulation) will occur when acid milk is mixed with alcohol.
Under normal circumstances and if the concentration of the alcohol is 68% (v/v), acidity will influence the test as indicated in Table 1.
TABLE 1 THE ALIZAROL TEST
TYPE OF MILK |
PH | %TA | FLOCCULATIONPROPERTIES | COLOUR |
Fresh milk | 6.60 – 6.45 | 0.14 – 0.16 | None | Light purple |
Slightly sour | 6.30 – 6.50 | 0.17 | Possibly small flakes | Brownish-pink |
Sour | 6.00 – 6.20 | 0.18 – 0.19 | Small flakes | Brownish-pink |
Very Sour | <6.00 | 0.20 + | Big flakes | Yellow |
Sweet coagulation | 6.60 – 6.75 | 0.14 – 0.16 | Big flakes | Light purple |
Mastitis | 6.80 + | N/A | Small flakes | Violet |
Added alkaline | 6.80 + | N/A | None | Violet |
1.2.2 Mastitis
Mastitic milk differs from normal milk as regards, amongst others, the protein and mineral composition. These differences cause the casein (protein) to flocculate more readily in mastitic milk. As the pH of mastitic milk is normally higher than that of normal milk the alizarine colour will turn violet if such milk is tested.
1.2.3 Sweet curdling
Certain contaminating bacteria are capable of producing rennin like enzymes, which increase the viscosity of the milk and even flocculate casein in the absence of acid. This phenomenon is known as sweet curdling. Such milk can be identified by inoculating aseptically a small quantity there-off into sterilised milk and incubating the inoculated milk at room temperature for a day or more on which the viscosity of the milk will increase at the normal pH of fresh milk.
Large numbers of these bacteria e,g. 800,000 /ml milk was found to create a positive reaction in previously sterilised milk.
1.2.4 Mineral imbalance
Too high or to low a concentration of minerals such as calcium, phosphate and citrate will increase the ease with which casein will flocculate in the presence of alcohol.
This aspect is complex and not well define. It is well known that the addition of very small amounts of Calcium (0.2 ml M/4 Ca-acetate / 25 ml milk = 0.6g / 1 l melk ) and Magnesium (0.1 mlM/4 MgCl2 / /25 mlmilk = 0.95 g / 1l melk ) will normally result in a positive test while the addition of phosphate and citrate salts may alleviate the situation. In more extreme cases excess phosphate and citrate may however be the cause of a positive test.
Small variation e.g. 0.01% in the normal Calcium content of milk may influence the test.
It is claimed that in some instances supplementing a cows ration with mono-calcium phosphate e.g. 20 – 40 g /day / cow may improve the situation.
If a positive reaction is due to mineral imbalance a very slight souring of the milk, causing a portion of the colloidal fraction of the minerals to become soluble, may result in a negative test.
Heating of alizarol positive milk to 60°C for 30 minutes will cause partial precipitation of Ca3(PO4 ) and as result the test may turn negative.
1.2.5 Stage of laction;
The chemical composition of early and late lactation milk differs from that of normal milk
in the sense that it is characterised e,g. by higher levels of albumin, globulin and chloride.
Due to these differences the protein suspension in such milk is usually very
unstable against alcohol
Milk is normally very unstable to alcohol in early lactation, thereafter gradually becoming more stable and remaining at a fairly constant level of stability which is specific for each cow. Towards the end of lactation milks from some cows become more stable but a decrease in stability is more common.
1.2.6. Other factors that may cause alizarol positive reactions include;
- Irritation of the udder tisue.
- Infected uterus and vagina
- Aborsion
For an online training course on the alizarol test that you can use forever in your dairy business to re-train and train new employees at $45 go to:
1.3 PRINCIPLES OF THE TEST
The stability of the protein dispersion in milk is maintained by hydration (combining with water) and by the negative electrical charges on the protein particles. If either of these two factors under goes a change, the proteins will flocculate. Alcohol is a dehydrator and therefore destablises the protein. If the protein is already slightly unstable due to souring of the milk, dehydration with alcohol will lead to the precipitation of the protein in the form of flakes.
1.4 REAGENTS AND APPARATUS:
- Measuring equipment: E.g. 2 – 5ml pippettes, siringes or automatic measuring apparatus for measuring milk and alizarol.
- Test tubes, small containers or other apparatus for mixing milk and alizarol.
- Alizarol-solution: Either 68 % (v/v%) or other specified concentration (see Table 2) of ethanol with alizarin powder dissolved in the alcohol.
Alizarol must be kept in a brown bottle in a cool place.
Either methyl (white spirits ) or ethyl alcohol, standardized with water to specified concentration and containing 0.4g alizarin powder (1.2 – dioxy-anthrquinone – C14H8O4, MM 240.22, colour code: CI 58000, pH-reeks: 11.0 – 13.0). The pH of the mixture should be neutralized to 6.7 and checked regularly.
TABLE 2 APPLICATION OF DIFFERENT ALIZAROL CONCENTRATIONS
Purpose of test | Concentration of alcohol | % Lactic acid for milk to curdle |
To determine if milk will curdle without boiling. | 44 | 0.25 – 0.28 |
Ordinary alcohol test. | 68 | 0.18 – 0.21 |
More sensitive alcohol test. | 70 | 0.16 – 0.18 |
To determine if milk can withstand high temperatures of condensing. | 75 | Milk will endure temperature treatment of 100 °C – 112 °C without curdling. |
1.5 THE PROCEDURE FOR DETERMINING PROTEIN STABILITY (ALIZAROL TEST)
(i) Equal volumes e.g. 2 or 5 ml of milk and alizarol of prescribe concentration, e.g. 70%, is mixed in a suitable container e.g. a test tube. (Equal volumes is critical for the accuracy of the test).
(ii) Mix carefully by inverting the tube once of twice.
(iii) Evaluate: – degree of flocculation, if any
– colour change
(iv) Interpretation
– If the colour remains light purple and no flocculation occurs, accept the milk.
– If the colour remains light purple and slight flocculation occurs, confirm acidity/ bacterial activity by performing one or more of the following tests:
- Clot-on-boiling
- pH and/or titratable acidity
- Resazurin test
– If the colour turns brownish-pink and flocculation occurs, reject the milk.
– If the milk has a brownish-pink colour but no flocculation occurs, determine the pH or %TA. If the results are unacceptable, that is, if they do not fall within the prescribed limits, reject the milk.
– If the colour of the milk varies from brownish-yellow to yellow, reject the milk.
– If the colour of the milk is violet but no flocculation occurs, determine the pH or %TA. If the results are unacceptable, that is, if they do not fall within the prescribed limits, reject the milk.
– NB! Take care not to interpret fat granules in cold milk for protein flocculation.
For an online training course on the alizarol test that you can use forever in your dairy business to re-train and train new employees at $45 go to:
Alizarol Test Kit Video
What is good about this alizarol test kit?
- Very small and handy
- only 400 microlitres of alizarol used per test
- Spring-loaded syringe makes sample taking easy
- Flip-cap bottle, so that cap cannot fall into milk or onto floor
- Can be washed and re-used few times to lower cost
Mozzarella stretching pH
The usual pH for stretching mozzarella curd is between 5 and 5.6, for buffalo mozz aim for 4.8 to 4.9(because of buffer efect from higher protein) and for artificially acidified mozz(like with citric acid) aim for 5.6-5.8
www.cheesemaking.co.za/shop
Summer Cheese
In summer I like to have some fresh cheese, like queso blanco, cottage, feta salad, buffalo mozzarella in caprese and mild slices of gouda 🙂
Twitter Weekly Updates for 2010-06-01
- Check this link with a photo of me as speaking:
http://www.mjmagazine.co.za/acrobat/jun_10/mozzerella_buffulo.pdf #
Powered by Twitter Tools.
Check this link with a photo o…
Check this link with a photo of me as speaking:
http://www.mjmagazine.co.za/acrobat/jun_10/mozzerella_buffulo.pdf
Photo of Leon the Milkman speaking about cheese ripening
Check the link for a pic of me as speaker at the National Society for Dairy Scientists and Technologists
http://www.mjmagazine.co.za/acrobat/jun_10/tenology_forefront.pdf
New Book for Cheese Lovers!
I received this letter and link form a reader of the Milkman’s Blog.
“Pierre Androuet: Cheese is the soul of the soil. It is the purest and most romantic link between humans and the earth.
Inspired by the above I have recently published a book enitled Tasting to Eternity ( www.tastingtoeternity.com) I thought you might enjoy a unique view of these remarkable products.
Enjoy
David Nutt”
Problems and defects of cottage cheese: Draft 1
The majority of quality problems in cottage cheese are caused by the growth of contaminating bacteria in the cottage cheese. Most contamination comes from the following sources:
- Through the lines of plant, equipment, containers
- Through the wash water(pasteurize wash water where possible)
- Through contact with ambient air
- Through the added dressing
- Through personal contact
- Through additives(herbs must be treated with ethylene or radiated)
Final temperatures should be as close to 0 degrees Celsius as possible and definitely under 4 degrees Celsius.
Please note that a product such as cottage cheese, once packaged, tends to warm up and reach dangerous temperatures very quickly if left at room temperature.
To the contrary, it requires considerable time and energy for cooling by only 10 to 4 degrees Celsius.
It is always best to leave the cottage cheese for 24 hours in storage before shipping, to make sure that the core temperature is low enough to prevent contamination growth.
It is generally recommended that the pH of the cottage cheese be in the range of 5. Below pH5 the cheese tends to have a tart taste, above the micro-pollutants grow too quickly.
Because of the high moisture of cottage cheese, care must be taken since high levels of preservatives like sorbic acid will give off-tastes easily.
Off tastes can be minimized by de-airing the milk before cottage cheese making and by applying MAP gasses into the container top space.
Bitter cheese: Might be poor quality microbial rennet(lots of “side reactions”) or proteolysis from psychrotropic bacteria – these bacteria are usually caused by keeping raw milk on the farm or at the factory for extended periods(2-4 days)
Over-Acid cheese: May result from insufficient washing of the curd, or excessively high temperatures during operations, packaging and storage. Make sure dressing is cold enough before adding to chilled curd. Make sure that the culture used has minimum post-acidification.
Oxidised Taste: Watch out for excessive agitation or other means of including air. Beware of any contact with metal, e.g. copper etc. The main remedy is to change defective cultures (producing peroxide), use quality milk, do keep temperatures at optimum levels throughout the process, avoid product contact with air.
Gel-like texture: Wash water pH or dressing pH too high.
Grittiness: This happens when the curd is cooked too rapidly, or when the granules of curd came in contact with too hot surfaces.
Gumminess or excessive toughness: Excessive cooking temperatures or too high pH. When using the titratable acidity to determine the moment of cutting, the same perceived acidity can result in significant difference of the clot, due to different buffering capacity of milk, or the different effects of lacto-fermentation yeast.
Weak granules: Cooking temperature too low or cut at too high acidity (too low pH on cutting).
Lack of creaminess: Too little dressing or insufficient/irregular mixing of the curd and dressing.
Wheying off: Survival and growth of yeasts. Post-acidification by culture. Insufficient dressing. Proteolysis(may be due to excessive psychrotropes in milk, due to raw milk storage of 2-4 days).
Non-uniformity of curd: The presence of grains of unequal size may be the result of mistreatment of the curd, cutting during cooking, breaking on mixing with the dressing, or packaging. This is remedied by using better equipment, more delicate in their functions and practices of working more smoothly.
Colour defects: May be caused by mold or other contaminants, like from Pseudomonas.
Check new stuff at www.cheesemaking.co.za/shop
www.cheesemaking.co.za/shop has lots of cheese and yoghurt making consumables and some equipment – check it out today.