IES930298A2 - Products derived from whey and their use in foodstuffs - Google Patents

Abstract

A process for the manufacture of a whey protein concentrate (WPC) from whey comprises the steps of reducing the pH of the whey 5 to a pH in the range 2.5-3.5, followed by ultrafiltration. Either acid whey or sweet whey can be used as a starting material. The process can be used to manufacture WPCs with consistent specific functional properties for use in a variety of foodstuffs. If it is desired to obtain a low fat WPC or a defatted WPC, tlie whey is subjected to microfiltration prior to the pH reduction step. WPCs having a protein content of the order of 80-90% by weight are obtainable.

Description

Products derived from whey and their use in foodstuffs ?98J —__-Thisjn^ention relates to a process for the manufacture of whey protein concentrates (WPCs) with improved functional properties and to the use of such WPCs in the manufacture of various foodstuffs.

WPCs are produced by subjecting whey to ultrafiltration. The WPCs obtained have a protein content in the range 35-80% by weight. WPCs with a protein content of the order of 35% by weight currently sell for ~IR£800 per tonne, whereas WPCs with a protein content of the order of 80% by weight currently sell for ~IR£4,000 per tonne.

Whey proteins, which constitute ~20% by weight of milk protein, have a high nutritional value and thus WPCs are suitable for use as, or in, foodstuffs. Whey protein has a nutritional value which is comparable to that of egg protein.

However, proteins also have functional properties which are important in the manufacture of foodstuffs, especially bakery, confectionery, dairy and meat products. These functional properties, which affect texture, include inter alia emulsifying, foaming, gelling and water binding properties.

Whereas one can heat whey and cause the precipitation of nutritionally valuable protein, such protein loses its functionality due to denaturation. For optimal functionality the tertiary structure of the whey protein must be maintained.

Developments in membrane filtration technology, especially ultrafiltration, have enabled one to obtain WPCs in essentially their natural state with good functional properties. Conventionally diafiltration has been used as an adjunct to remove lactose.

To date it has not been possible to achieve a good level of consistency in the production of WPCs, which has limited their S5S50S Έ930298 application in, and general acceptance by, the food manufacturing sector.

Also to date it has not been possible to consistently obtain WPCs with functionality equivalent to that of egg white for example, especially in terms of its gelling properties in both aqueous and saline media.

The use of ultrafiltration leads to protein enriched whey fractions. However, such protein enrichment also leads to enrichment of the fat content which has an adverse effect on the functionality, especially on foaming and gelling properties. For example, a WPC obtained by ultrafiltration with an 80% by weight protein content would typically have a fat content in excess of 8% by weight.

However, the use of microfiltration before the protein extraction by ultrafiltration enables one to obtain a WPC with a low fat content.

Thus it is possible to obtain a WPC with 90% protein and less than 1 % fat using a combination of microfiltration and ultrafiltration. In theory such a product should have excellent properties. Such defatted WPCs show improved gelling properties in aqueous media but give similarly poor gelling performance in saline media, relative to WPCs with a normal fat content. At present low fat WPCs are used mainly for their nutritional properties.

Ion exchange chromatography, especially cation exchange chromatography, can be used to produce whey protein isolates with good functional properties, especially the ability to gel in saline media.

However, the use of ion exchange chromatography is expensive and thus cannot be used to produce WPCs for use in foodstuffs at a price generally acceptable to the consumer.

Various modified WPCs are produced. Such modified WPCs are modified, for example, chemically by addition of salts such as polyphosphates and citrates, so as to give particular functional properties.

IE 930298 There is a need for a process which results in the production of WPCs witli consistent specific functional properties for use in a variety of foodstuffs, in particular, a WPC is often sought which has a functionality comparable to that of egg white.

There is also a need for a process which can use either acid whey or sweet whey as a starting material and which results in the production of WPCs with consistently desired functionality.

The invention provides a process for the manufacture of a whey protein concentrate from whey, which comprises the steps of reducing the pH of the whey to a pH in the range 2.5-3.5, followed by ultrafiltration.

The process according to the invention results in the production of WPCs with consistently improved functional properties as hereinafter described and which can be incorporated in a variety of foodstuffs. Furthermore, the reduction of pH prior to ultrafiltration relative to conventional processing does not adversely affect flux rates.

Preferably, the pH of the whey is reduced to a pH in the range 2.8-3.2, more especially 3.0, before ultrafiltration.

Preferably, the pH of the whey is reduced by the addition of a 20 food grade acid, more especially hydrochloric acid.

The starting whey may be acid whey (pH ~ 4.0-5.0) or sweet whey (pH ~ 5.8-6.8).

Acid whey is conventionally used in the manufacture of acid casein which in turn is used to produce caseinates which are typically used in the manufacture of, for example, meat products, coffee whiteners, low fat products and cheese substitutes. Sweet whey on the other hand is the normal by-product of cheese and rennet casein manufacture following the separation of the curds.

IE 930298 Ultrafiltration in accordance with the invention is preferably carried out using a 1,000-50,000 molecular weight cut-off (MWCO) membrane. In a particularly preferred embodiment of die invention the membrane will have a MWCO less than 15,000, especially of the order of 5.000.

Preferably, the whey is held for a period of time, suitably circa 1 hour, before being subjected to ultrafiltration.

Tlie ultrafiltration may be carried out at the reduced pH or. alternatively, following upward pi 1 adjustment to a more neutral pH, for example pH 6.3.

If it is desired to obtain a low fat WPC or defatted WPC, the whey is subjected to microfiltration prior to the pH reduction step. Preferably, the microfiltration is carried out using a microfiltration membrane with a porosity in the range 0.05-1.0 pm, suitably 0.1 μπι.

Tlie product obtained in accordance with the invention, which is subjected to a combination of microfiltration and ultrafiltration, would typically have a fat content of the order of 0.5% and, therefore, it is more specifically defined as a 'defatted’ WPC.

Following the ultrafiltration step, the retentate is optionally subjected to diafiltration for further removal of lactose.

Following the ultrafiltration step or the diafiltration step, as appropriate, the pH of the retentate is preferably raised to a pH in the range 6.0-7.5. followed by spray drying. Tlie pH adjustment is preferably carried out using a food grade alkali, such as sodium hydroxide, potassium hydroxide or calcium hydroxide. Alternatively, as indicated above, the pH adjustment may be carried out before ultrafiltration, in which case the whey product still retains the desired gelling characteristics, but has the additional advantage of a reduced mineral content, due to subsequent partial removal of the added alkali mineral during ultrafiltration/diafiltration.

IE 930298 It will be appreciated that drying of the product can be carried out by any suitable means, in addition to spray drying.

Idle invention also provides a WPC whenever manufactured by a process as hereinbefore specified.

The WPC manufactured by the process according to the invention preferabiy has a protein content greater than 50% by weight, more especially of the order of 80-90% by weight. ?\ccording to one aspect of the invention, there is provided a whey protein concentrate having a gel strength greater than 275g in aqueous media and a gel strength greater than 275g in 0.2M saline media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens’ LFRA Texture Analyser at a compression setting of 47%, and at a temperature of 20°C. Such a WPC has excellent functionality and thus a wide application in foodstuffs, for example in bakery, confectionery and meat products.

According to a further aspect of the invention there is provided a defatted whey protein concentrate having a gel strength greater than 525g in aqueous media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens' LFRA Texture Analyser at a compression setting of 47%, and at a temperature of 20°C. Such products have particular application in bakery, confectionery and dairy products.

According to a still further aspect of the invention there is provided a defatted whey protein concentrate having a gel strength greater than 400g in 0.2M saline media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens' LFRA Texture Analyser at a compression setting of 47%, and at a temperature of 20°C. Preferably, said product has a gel strength greater than 500g under the specified conditions.

Such products have particular application in meat products.

IE 930298 Examples of meat products containing tlie gelling agents according to the invention are cooked meats, hamburgers, pates and sausages.

Gel strengths as hereinbefore defined are determined in accordance with a modification of a method described by Mulvihill, D.M. and Kinseila, J.E. ((1988) Journal of Food Science, 53, No. 1. 231) as hereinafter described.

Tlie Stevens' LFRA Texture Analyser is manufactured by Mechtric Stevens. U.K.

The invention will be further illustrated by die following Examples.

EXAMPLE 1 2,000 1 of clarified, cooled, rennet casein whey (pH 6.6, % total solids (T.S.) 6.0, temperature 6°C) was used for the production of a high gelling, defatted WPC product in the following manner.

The whey was first microfi ltered to remove residual fat present in clarified whey. Microfiltration was carried out on an Alfa Laval MFS - 7 (Trade Mark) microfiltration plant, incorporating uniform transmembrane pressure (UTP) design, fitted with 0.1 pm ceramic membranes, with an overall membrane area of 1.4 m2. Microfiltration was operated on a continuous basis, with a permeate flux of 100 l/m2/h, at a lOx concentration factor and a temperature of 50°C.. The whey was heated to 50°C. by pumping to the microfiltration plant via the heating section of a heat exchanger. The defatted permeate was cooled to 6°C., as it came off the microfiltration plant by pumping through the cooling section of the heat exchanger.

Approximately 1,800 1 of defatted whey permeate was collected. This was heated up to 55°C., on a heat exchanger and held at this temperature for 30 min., before ultrafiltration. Also, before IE 930298 ultrafiltration, the pH was adjusted downward to pH 3.0, by the addition of 10% hydrochloric acid.

Ultrafiltration was carried out on a Romicon (Trade Mark) hollow fibre system (6.9 ητ membrane area), using a modified batch mode. Ultrafiltration was carried out to a concentration factor of 40x and a 4x diafiltration step was also incorporated, resulting in a concentrate product with a protein dry matter content of greater than 85.0% by weigin.

The pH of the concentrated product was adjusted upwards to pH 10 6.5 - pH 7.0, by the addition of 10% sodium hydroxide solution.

Finally, the product was spray dried to a powdered form.

Tire product obtained had a protein content of greater than 85.0%, as stated, a fat content of 0.2%, and had high gel strength characteristics when tested under both aqueous and saline conditions as follows.

Preparation of aqueous gel.

A quantity of the product obtained above equivalent to lOg protein is added gradually to 60 ml,, of distilled water in a 150 ml., beaker on a magnetic stirrer and stirred continuously for 30 min., or until the protein is fully dispersed. 'Hie pH of the solution is adjusted, if necessary, to 7.0 with 0.1M HCI or 0,1 M NaOH. The solution is transferred to a 100ml., volumetric flask and the contents of the beaker carefully washed out witii distilled water and the solution diluted to the mark with distilled water. The contents of the flask are mixed thoroughly. Tlie solution is then centrifuged at 500 r.p.m. for 10 min., at 20°C.. Approximately 14ml., of tlie solution are poured into each one of a series of prepared gelation tubes which are stoppered and clamped in a test tube rack. Tlie rack is transferred to a water bath at 50°C., and the tubes heated for 30 min,, at 50°C.. The temperature of the water is then increased to 90°C., at a rate of 2°C., per min. and held at 90°C.. for 30 min.. The rack is removed from the water bath IE 930298 and immersed in water at 4°C., and maintained at this temperature overnight.

The following day the rack is placed in a water bath at 20°C for 30 min., to allow tlie gels to equilibrate before removal from tlie tubes and cutting prior to tensile assessment.

Preparation of saline gel.

Tire above procedure is repeated except that the gels are made up using 0.2M NaCI instead of distilled water.

The gel strength or tensile assessment is carried out on a Stevens' LFRA Texture Analyser in accordance with the manufacturers’ instructions and using distance of test - 3, 7 or 9 mm., for 20%, 46.7% (hereinafter 47%) and 60% compression, respectively.

In each case a 15mm height of gel is tested. Nine gels are cut for each sample to be tested - three at 20% compression, three at 47% compression and three at 60% compression. The results at 47% compression were selected as being the most representative for the products produced in accordance with the invention.

Thus for the product obtained in Example 1, the results were as follows: Gel type Aqueous gel Saline gel Average gel strength (g) 755 650 IE 930298 EXAMPLE 2 Tlie procedure of Example I was repeated using acid whey at pH ~4.6. Average gel strengths for aqueous and saline gels were as follows: Gel type Aqueous gel Saline gel Average gel strength (gj 560 440 EXAMPLE 3 Example 1 was repeated except that the microfiltration step was 10 omitted. The gel strengths for aqueous and saline gels prepared in accordance with the procedure of Example 1 were as follows: Gel type Aqueous gel Saline gel Average gel strength (g) 300 300 EXAMPLE 4 Example 1 was repeated except that following downward pH adjustment to pH 3.0 the product was held at 50°C. for 1 h., after which the pH was readjusted to pH 6.3 before ultrafiltration. Average gel strengths for aqueous and saline gels were as follows: Gel type Average gel strength (g) Aqueous gel Saline gel 570 250 IE 930298 EXAMPLE 5 Preparation of meringues A batch of meringues was prepared using the product of Example i as a substitute for dried egg albumen using the following ingredients: Ingredient Weight (g) Product of Example 1 12.50 Caster sugar 200.00 Water 87.50 The product of Example I was mixed to a paste first with an equal volume of water, followed by addition of the remaining water and mixing until full dissolution. Tlie solution was transferred to the mixer bowl of a Hobart Kitchen Aid Food Mixer (Trade Mark) fitted with a balloon whisk attachment and whipped at speed 8 for 5 min.

The sugar was then added gradually to the foamed solution over a period of 3 min.. The speed was reduced to 4-5 after half of the sugar had been added. Mixing was continued for a further 5 min., at speed 4. Using a piping bag and nozzle, the mixture was piped out on to a nonstick silicone paper into tall conical meringues. All utensils were kept completely free from fats and oils. Tlie meringues were baked at 100°C., in a Chandley Bakery Oven (Trade Mark) or until fully baked.

Control meringues were prepared using dried egg albumen instead of the product of Example 1.

IE 930298 SENSORY EVALUATION RESULTS.

Characteristic Dried Leg Albumeh Defatted WPC Colour Off white Off white. 5 Taste Clean Very slight whey after taste. Texture Soft, sticky centre with crisp outer shell Soft sticky centre with crisp outer shell. Shape Holds shape during Did not hold shape and 10 cooking with firm peaks. peaks sagged. However, inclusion of acid (citrate, lactate) overcame this.

Overall, the defatted WPC in accordance with the invention gave 15 acceptable meringues at 100% replacement level of dried egg albumen.

EXAMPLE 6 Preparation of nougat Nougat was prepared using the product of Example 1 as a substitute for egg albumen using the following ingredients: IE yjuzao Inc redient Weight (s) A. Product of Example 1 7.50 Water 15.00 B. Liquid Glucose 42DE 'Trade Mark) 62.50 C. Sucrose 380.00 Liquid Glucose 262.50 Water 95.00 D. Chopped Hazelnuts 75.00 Diced Glace Cherries 50.00 Icing Sugar 17.50 E. Hydrogenated palm kernel oil (HPKO) 22.50 F. Vanilla Flavour 0.75 Ingredients A were mixed and left aside to dissolve. B was then added to A in a Hobart (Trade Mark) mixer and beaten to a stiff foam (frappe) at high speed. Ingredients C were boiled to 94.5% solids (132°C) and added to the frappe in a thin stream, using the mixer at a lower speed. Ingredients D were added to the mixture, followed by the melted HPKO. The latter was added last to avoid foam breakdown.

The vanilla flavour was added and the final mixture beaten for a further 15 sec., before depositing in a tray. Tlie nougat was left to grain for approximately 12 h., and then cut into pieces.

Control nougat was prepared using egg albumen in place of the product of Example 1.

The nougat containing tlie product of Example 1 compared favourably as regards texture and flavour with the control.

IE 930298 EXAMPLE 7 Pork sausage product A pork sausage product was prepared using the product of Example 1 as a partial replacer of lean meat using the following ingredients: Ingredient Weight (g) Sow meal (90% lean) 16.65 Young pork meat (80% lean) 18.75 Pork fat 19.05 Rusk 14.05 Spice 2.50 Salt 1.00 Product of Example 1 5.00 Water/ice 23.00 100.00 A combination of prechopped lean, young pork meat and sow meat and pork fat was added to a bowl chopper and chopped to uniform meat matrix. A blend of the dry ingredients (product of Example 1, spice, rusk and salt) was slowly added to the fast rotating bowl chopper. The water/ice mix was then added and the blend comminuted to a fine 'emulsion' i.e. until all the fat and water were completely absorbed.

The emulsion was then placed in a hydraulic stuffer (Mainca, Barcelona, Spain) and extruded into DEVRO (Trade Mark) dry casings and hand linked. Tlie sausages were held overnight at 9°C., prior to evaluation inter alia for % cook loss, % fat loss, sensory and textural attributes relative to both unsupplemented and soya (5%) supplemented products. lE 930298 The product of Example 6 and the soya supplemented product each has a partial (15%) replacement of lean meat relative to the unsupplemented product.

The results are shown in Table 1.

TABLE 1.

Comparison of product of Example 6 with unsupplemented control and soya (5%) supplemented product Product Emulsion* % Cook Loss Fat Loss Sensory Comments Unsupplemented Control Good firm emulsion (score 8) 16.5 1.9 Good flavour Succulent mouthfeel. Soya supplemented product Very stiff over dry emulsion (score 1) 21.2 5.6 Slight after taste, rubbery texture. Product of Example 6 Smooth emulsion slightly soft (score 5) 12.4 1.6 Very slight after taste, succulent mouthfeel.

* Emulsion scored on a scale of 1-10.

This invention is not limited to the embodiments described above which may be modified and/or varied without departing from the scope of the invention.

Claims (5)

CLAIMS:
1. J. Λ process for die manufacture of a whey protein concentrate from whey, which comprises the steps of reducing the pH of the whey to a pH in the range
2. 2.5-3.5, followed by ultrafiltration. 5 2. A whey protein concentrate having a gel strength greater than 275g in aqueous media and a gel strength greater than 275g in 0.2M saline media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens' LFRA Texture Analyser at a compression setting of 47%, and at a 10 temperature of 20°C.
3. 3. A defatted whey protein concentrate having a gel strength greater than 525g in aqueous media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens' LFRA Texture Analyser at a compression 15 setting of 47%. and at a temperature of 20°C.
4. 4. A defatted whey protein concentrate having a gel strength greater than 400g in 0.2M saline media when a gel containing 10% w/v protein at pH 7.0 formed after heating to 90°C for 30 min., is measured in a Stevens' LFRA Texture Analyser at a compression 20 setting of 47%, and at a temperature of 20°C.
5. 5. A process according to Claim 1, substantially as hereinbefore described with particular reference to Examples 1-4 of the accompanying Examples.