Water continuous frying composition

Technical field.

The invention relates to oil-in-water emulsion food products, in particular liquid products with low fat content showing a good spattering behaviour when used in shallow frying.

Background

Frying composition are compositions that are used for frying food. Common frying agents such as butter or margarine are fat continuous. Liquid margarines are popular with consumers due to their easy dosing. Most liquid margarines are also fat continuous. However, these fat continuous often suffer from spattering which is believed to be caused by superheating of the dispersed water droplets. In addition, fat continuous emulsion spreads and liquid products are poor in physical stability at elevated temperatures e.g. above 30 ⁰ C. Another drawback from fat continuous frying compositions is the use of hardstock fat which gives the frying composition a high level of saturated fatty acids which are not desirable from a health perspective. Furthermore, the use of hardstock fat requires high energy processing due to the necessary liquefying of the hardstock fat in the process.

Water continuous frying emulsions are also known e.g. from WO02/45519. However, water continuous frying emulsions often contain salt and lecithin, a high level of emulsifiers and a high fat content (50 to 80 wt% of fat) . The effect of sole lecithin on spattering is small, therefore a substantial amount of salt exceeding 0.3 wt . % should be added to get good spattering behaviour. In current trends in healthy lifestyles,

a lower sodium content for food products is often desired, as high salt levels are associated with high blood pressure. Furthermore the water continuous frying composition often foam considerably which is not desirable from a consumer' s perspective.

Another drawback of the frying compositions of WO02/45519 is the relative high level of emulsifiers needed.

For the consumer it is not always easy to know when the frying composition is ready to use for shallow frying (i.e. when to add the food product to be fried to the heated frying composition) . The changes in the development of foaming when heating water continuous frying compositions provide the consumer with a visual cue when the composition is ready to use for shallow frying. Typically the composition starts foaming after a certain time of heating the composition. When no considerable amount of foaming is seen anymore the composition is ready to use for shallow frying. It is desired that the composition can be used as quick as possible after starting to heat the composition.

A relatively high salt content is typical for most prior art cooking oils which show an improved spattering behaviour. The presently available alternatives for lecithin and cooking salt consist of non-natural substances.

H. Pardun, in Fette, Seifen, Anstrichmittel 79(5), 1977, pp. 195- 203 describes the use of milled soy protein concentrates as antispattering agents in margarines. The antispattering agents proposed by Pardun have the disadvantage that when heated in the pan during shallow frying, they may decompose and give char formation. Moreover, we have found that when margarines of

Pardun are prepared using modern margarine equipment, such as a votator, the antispattering agents are no longer effective.

WO2005/058067 and WO2005/013056 disclose fat continuous frying compositions with improved spattering behaviour that comprise porous powderous vegetable matter made from nuts, seeds kernels, pits and cellulose having a volume weighted mean particle diameter (d ₄ , ₃ ) not exceeding 0.5 mm.

There is therefore a need for a composition that has excellent spattering behaviour also with low fat content. Furthermore nutritional benefits as low salt, and low saturated fatty acid content and low fat are desired. Preferably the composition has less foaming and uses less additives. In addition, ambient stability is also sought after. Moreover a cold processing of the composition has benefits as it uses less energy than high energy processes. Furthermore, the composition preferable provides a visual cue that shows when the composition is ready to use. Preferably the composition is ready to use for frying relatively quick.

Summary of the invention

It is an object to provide a frying product having a good spattering performance in shallow frying. A further object is to provide a frying product having a lower fat content, e.g. around 60 wt . % fat, or even lower, while maintaining good spattering performance. A further object to provide healthy frying product, in particular having a low amount of salt, and a low amount of SAFA. Another object of the invention is to provide a frying product that does not brown or give of-taste or leave a sediment or foams upon heating to high temperatures. In addition, a further object of the invention is to provide a frying product that needs less ingredients, such as

emulsifiers . Moreover, another object of the invention is to provide a frying product that can be made by cold processing using less energy. In addition an object of the invention is to provide ambient stable products. Furthermore it is an object of the invention to provide a frying product that provides a visual cue. It is also an object of the invention to provide a frying product that is ready to use for frying in a shorter amount of time.

One or more of these objects are attained according to the invention which provides an oil-in-water emulsion food product comprising 10 to 90 wt% fat and 0.05 - 5 wt% of a porous powderous vegetable matter made from nuts, seeds, kernels, pits and cellulose having a volume weighted mean particle diameter (d4,3) not exceeding 0.5 mm.

Details of the invention

Suitable composition according to the invention are pourable and have a Bostwick value at 7 cm/30 sec, preferably more than 10 cm/30 sec at 15 ⁰ C.

Preferred compositions comprise 10 to 60 wt% of liquid oil.

Suitably the volume weighted mean particle diameter (d ₄ ,3) of the porous powderous vegetable matter does not exceed 0.1 mm, preferably not 0.04 mm.

Preferably the porous powderous vegetable matter is evenly dispersed throughout one or more phases of the water continuous composition.

Preferred compositions have a pH between 3 and 8.

Preferably the composition according to the invention have the fat is dispersed in a water phase, whereby the average droplet size (d _4/ 3) of the fat is less than 12, preferably less than 8 μm, more preferably less than 6 μm, most preferred from 0.35 to 4 μm.

In a preferred embodiment the compositions comprise at least one emulsifier having a hydrophilic/lipophilic balance value of at least 7. Preferred amounts for emulsifiers are 0.1 to 5 wt%. Suitably the emulsifier is selected from the group comprising di-acetyl tartaric acid esters of monoglycerides and/or diglycerides (DATEM) , polyoxyethylene sorbitan mono stearate (Tween) , sucrose esters, sodium stearoyl lactylate (SSL) , polygycerol esters (PGE) , acetylated pectin, esters of citric acid with monoglycerides and/or with diglycerides, lactic acid esters of mono-and/or diglycerides, succinic acid esters of mono-and/or diglycerides; or combinations thereof.

A preferred emulsifier is DATEM which is suitably used in a amount of from 0.3 to 3 wt%.

In a preferred embodiment the composition according to the invention comprise a biopolymer in an amount of 0.01 to 0.5 wt% on total composition weight, preferably 0.05 to 0.3 wt%.

The composition according to the invention may comprise an additional antispattering agent, such as lecithin an/or salt. Suitably the antispattering agent comprises salt in an amount of from 0.01 to 5 wt% on total weight of the composition. Preferably lecithin is present in an amount of from 0.05 to 2 wt% on total weight of the composition.

Preferably the porous powderous vegetable matter is admixed to the water continuous frying emulsion.

Preferred porous powderous vegetable matter consists of milled kernels of olive oil.

Still other preferred porous powderous vegetable matter consists of milled sunflower seeds or milled linseeds.

Furthermore other preferred porous powderous vegetable matter consists of milled soybeans.

Moreover other preferred porous powderous vegetable matter consists of milled nuts selected from the group consisting of pine tree nuts, almonds, ground nuts, walnuts and cashew nuts.

Suitably the composition according to the invention is substantially free from cooking salt, preferably below 0.9 wt%, more preferably below 0.5 wt%.

The oil-in-water emulsion food products according to the present invention may be produced according to a process which comprises the following steps: a. selecting an oil-in-water emulsion b. selecting emulsion insoluble vegetable matter having a consistency which allows milling to a powder, c. milling the vegetable matter to a powder having an average particle size not exceeding 0.5 mm, d. admixing the resulting powder to the oil-in-water emulsion in an amount of 0.05 - 5 wt . % on product and getting it evenly dispersed throughout the oil-in-water emulsion.

In a preferred embodiment the process for the preparation of a water continuous frying composition according to the invention involves at least one process step in which the pressure is 0.20 MPa or more and wherein the porous powderous vegetable matter is not subjected to any pressure of 0.20 MPa or more.

Preferably the porous powderous vegetable matter is prepared by milling vegetable matter. More preferably the porous powderous vegetable matter is prepared by milling and extracting oil from oil containing vegetable matter. Suitably the porous powderdous vegetable matter is prepared by milling vegetable matter, which has been extracted with an organic solvent.

In a preferred embodiment the vegetable matter is pre-milled, oil-extracted and then the extracted vegetable matter is milled to prepare the porous powdered vegetable matter.

Experimental :

Measuring pourability

Pourability or squeezability is measured according to the standard Bostwick protocol. The Bostwick equipment consists of a 125 ml reservoir provided with an outlet near the bottom of a horizontally placed rectangular tub and closed with a vertical barrier. The tub's bottom is provided with a 25 cm measuring scale, extending from the outlet of the reservoir. When equipment and sample both have a temperature of 15 ⁰ C, the reservoir is filled with 125 ml of the sample after it has been shaken by hand ten times up and down. When the closure of the reservoir is removed the sample flows from the reservoir and spreads over the tub bottom. The path length of the flow is measured after 30 seconds. The value, expressed as cm per 30 seconds is the Bostwick rating, which is used as yard stick for pourability.

The maximum value that can be determined with this measurement is 23.

Example 1

Preparation of an edible oil-in-water emulsion

A pourable margarine was prepared with the composition shown in table.

Tablel: Composition of a 58 wt . % fat pourable margarine

Preparation of pourable margarines

The water phase was prepared by dissolving all water-soluble ingredients in de-mineralised water at 25°C. Firstly the gum's (Xanthan or Guar) are dissolved in the water phase, after this the other water phase ingredients are dissolved. Citric Acid Anhydrate is dissolved in the water phase as the last ingredient while stirring with an Ultra Turrax device or directly in a Colloidmill. The oil phase used for the emulsion was prepared by dissolving the oil soluable components in sunflower oil in a glass beaker. The ingredients are dissolved in sunflower oil at a temperature of approx. 65°C. The oil phase was added to the water phase in the Colloidmill, while stirring intensively, slowly to keep the emulsion water- continuous. After addition of the oil phase the emulsion was stirred for 5 min. at high speed in the Colloidmill.

Example 2 - 3

Example 1 was repeated, but now with 79.5 wt . % sunflower oil (example 2) and 37.5 wt . % sunflower oil (example 3) . The amount of water was adjusted such that the total composition remained 100 wt . % . The spattering values of the liquid margarines are given in table 2.

Comparative experiment A

Example 1 was repeated, but now without soy flour. The spattering values of the liquid margarine are given in table 2.

Determination of spattering value

Primary spattering (SVl) was assessed under standardised conditions in which an aliquot of a food product was heated in a glass dish and the amount of fat spattered onto a sheet of paper held above the dish was assessed after the water content of the food product had been driven off by heating.

Secondary spattering (SV2) was assessed under standardised conditions in which the amount of fat spattered onto a sheet of paper held above the dish is assessed after injection of a quantity of 10 ml water into the dish.

In assessment of both primary and secondary spattering value about 25 g food product was heated in a glass dish on an electric plate to about 205 ⁰ C. The fat that spattered out of the pan by force of expanding evaporating water droplets was caught on a sheet of paper situated above the pan. The image obtained was compared with a set of standard pictures number 0- 10 whereby the number of the best resembling picture was recorded as the spattering value. 10 indicates no spattering and zero indicates very bad spattering. The general indication is as follows .

Score Comments

10 excellent

8 good

6 passable

4 unsatisfactory for SVl, almost passable for SV2

2 very poor

Typical results for household margarines (80 wt% fat) are 8 for primary spattering (SVl) and 5 for secondary spattering (SV2) under the conditions of the above mentioned test.

Table 2: spattering values of frying compositions

Comparative example B: A water continuous frying composition with the following ingredients was prepared.

Table 3 : Ingredients example B

Comparison of example 1 to comparative example B show that example B shows considerably more foaming upon heating than the example 1 according to the invention.

Comparative experiment C

Assessment of foam development

About 25 gram of the water continuous composition was heated in a glass dish on an electric plate of about 205 ⁰ C. The foam development was assessed by visual inspection about every 10 seconds .

For example 1 with and without 0.1 wt% of soy flour the foam development was assessed (see Table 4) .

Table 4: Assessment of foam development

Comparison of example 1 to comparative example A shows that for example A it takes more time for the foam development to start than for example 1 according to the invention.

Comparative experiment D

Measurement of stability The stability of the composition over storage was measured by determining the amount of free water according to the following methodology.

The composition was stored in a plastic bottle in a temperature cabinet at a specific temperature. The free water content was calculated by measuring the height of the separated water phase in mm (A) , measuring the fill height of the bottle in mm (B) and then divide the two according to the following formula: (A/B)*100. The outcome of this calculation is the % of free water.

Pourable water continuous compositions according to Table 5 were prepared using the method of preparation as mentioned above under the header "Preparation of pourable margarines" with the difference that the water when preparing the water phase had a temperature of about 40 ⁰ C.

Table 5

The compositions according to Table 5 were stored at 5 or 30 ⁰ C for a period of 20 weeks. The % of free water was measured (see Tables 6 and 7) .

Table 6: of free water stored at 5 ⁰ C

Comparison of comparative example D and examples 4 and 5 shows that examples 4 and 5 according to the invention have an improved stability upon storage compared to example D.