KR102286395B1 - Method for preparing fish sausage and fish sausage prepared thereby - Google Patents

Abstract

The present invention relates to a method for producing a fish meat sausage and to a fish meat sausage prepared by the method. More specifically, the present invention not only has excellent texture without using pork or pork fat, but also can control aging and quality degradation of fish meat sausages due to aging of starch contained in fish meat sausages, unlike existing fish meat sausages. There, it relates to a method for producing fish meat sausage that can increase the storage period, that is, the shelf life.
Specifically, the fish meat sausage manufacturing method includes a fish meat mincing step of mincing fish meat; salt-soluble protein elution step of eluting salt-soluble protein by adding salt to the minced fish meat; a fish meat emulsification step of emulsifying the fish meat by adding soybean oil, soy protein and egg white liquid to the fish meat eluted with the salt-soluble protein; Processed tenderloin manufacturing step of preparing processed tender meat by adding mixed starch, carrageenan, and seasoning ingredients mixed with potato starch, acetic acid modified potato starch and tapioca starch to the emulsified fish meat: Filling the processed tenderloin into a casing through a filling machine and molding a filling step to prepare a molded article; And it may include a heat treatment step of heat-treating the processed meat molded product filled in the casing.

Description

Fish meat sausage manufacturing method and fish meat sausage manufactured by the manufacturing method

The present invention relates to a fish meat sausage manufacturing method and to a fish meat sausage manufactured by the manufacturing method.

Metabolic diseases, including obesity, caused by excessive intake of high-fat diets, are becoming a social problem due to the rapid economic growth and changes in living convenience and dietary habits. In particular, excessive caloric intake and unbalanced diet, such as specific nutritional components, increase the incidence of diseases such as obesity, hyperlipidemia, diabetes, and atopy, and become an issue enough to cause social problems.

In particular, obesity is a disease that occurs as a major cause of consuming more calories than consumed. In the case of modern people, while calorie consumption is reduced due to inactive life such as watching TV or playing computer games, calorie intake is increasing due to intake of high-fat, high-calorie and low-fiber foods, so the population classified as obese is increasing. there is. In particular, if there is obesity in childhood, it is very likely that obesity will continue even in adulthood, so it is urgently required to solve the problem of childhood obesity.

In particular, due to the abundant supply of livestock such as cattle or pigs, commonly called meat meat, due to economic growth and intensive breeding, a problem caused by excessive meat intake has recently been pointed out.

Specifically, it is reported that the risk of premature death increases by about 20% if you eat meat such as red or processed meat every day, which is due to the fact that saturated fatty acid nitrite contained in meat or carcinogens generated during the cooking process of meat, etc. is expected to be the cause.

At the same time, in the case of intensive breeding for meat supply, it induces large-scale and commercialization of livestock farms, causing problems due to an increase in the amount of livestock manure, a high-concentration difficult-to-decomposable pollutant, and ethical problems due to the intensive breeding of livestock. In the case of such livestock manure, dumping at sea is prohibited by recent international treaties, which raises issues related to the treatment method. being pointed out In particular, it is reported that livestock manure accounts for about 37% of the total wastewater treatment load due to difficulties in treatment.

In order to solve these personal health problems and environmental and social problems, there is a recent trend to reduce meat consumption and replace meat with fish, vegetables, or seafood. Nevertheless, the development of various foods to replace meat is limited. In particular, despite the fact that a vegetarian diet is recommended in school lunches to solve the problem of childhood obesity, the development of a convenient food for a low-fat diet including protein for young children who have a strong appetite for meat is insufficient.

In particular, it is a low-fat, high-protein food containing a large amount of unsaturated fatty acids while nutritionally high in protein and low in saturated fat compared to food containing meat. this is being requested

In this regard, there is a growing need for the development of alternative foods that use fish or plants for processed foods, such as processed meat, ham and sausage, that young people like.

In general, ham and sausage, which are processed foods that young people like, are salted with pork, pork fat, sodium nitrite, salt, sugar, preservatives, colorants, spices, seasonings, etc. It is made by heat treatment.

As consumer demand for products with reduced animal fat in these processed meat foods increases, many studies are underway to use vegetable oil or other fat substitutes for animal fat used in the manufacture of sausages. For example, fish meat sausages using fish meat have been developed and distributed in order to meet the consumption patterns of modern people.

The fish meat sausage is a processed fish meat product that is sterilized after casing by mixing fats and oils, seasonings, starch, stabilizers, etc. after cutting the tender meat of fish. is being developed

However, when the fat content is lowered by using an animal fat substitute such as fish meat, not only the flavor is lowered, but also the elasticity of the product is lowered and the texture of the product is lowered. Specifically, when the content of pork fat is lowered, there is a problem that the texture is lowered, so most of the previously developed fish meat sausages use pork fat and pork tenderloin or fish meat together, and the calories are increased due to the added pork fat. Not only does it not have differentiation from existing sausages, but there is also a problem in that the light taste of fish meat is sensually reduced due to fat.

In addition, the normal shelf life of fish meat sausages developed so far is 3 months in Korea, and normal fish meat sausages age as time goes by, moisture is released and hardened, and odors caused by chemical changes (off-odor) It has the disadvantage of rapidly decreasing taste.

For this reason, the export of fish meat sausages is limited to countries with distribution distances such as China, and export is in progress. Recently, as the sales of fish meat sausage in China soared, it is emerging as a major exporting country. In order to expand the export of processed fishery products in Korea, it is necessary to diversify the exporting countries, and at a time when the market needs to be expanded to the Americas and Europe, where the market creation effect is high, it is necessary to extend the shelf life of fish meat sausages and to diversify the distribution temperature. It's time.

10-2012-0078809A 10-1061458B 10-0943422B 10-0350827B 10-0222171B

In order to solve the above problems, the present inventors have developed a fish meat sausage with excellent texture despite the reduction or no use of pork or pork fat, which is a problem of the conventionally known fish meat sausage, and the limited distribution period of the fish meat sausage. In order to increase, it is an object of the present invention to develop a method for producing fish meat sausage that can inhibit the aging of fish meat sausage, and to provide it.

In addition, an object of the present invention is to provide a fish meat sausage prepared by the above fish meat sausage manufacturing method.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art from the description of the present invention. .

In order to achieve the above object, the present invention, in one aspect, without using pork or pork fat, provides a method for producing a fish meat sausage that can control the aging of the fish meat sausage.

Specifically, the fish meat sausage manufacturing method includes a fish meat mincing step; salt-soluble protein elution step; fish meat emulsification step; Processed tenderloin manufacturing step; filling step; and a heat treatment step, and a thickener that is a cause of deterioration of the existing fish meat sausage quality, that is, potato starch, acetic acid-modified potato starch and tapioca starch, preferably potato starch, A mixed starch obtained by mixing acetate-modified potato starch and tapioca starch in a ratio of 7: 2: 1 (potato starch: acetic acid-modified potato starch: tapioca starch) based on the weight is used, and as a stabilizer, it is a stabilizer optimized for the mixed starch. By using karakinan, it relates to a method for producing fish meat sausage that solves the problem of quality deterioration of fish meat sausage.

More specifically, the fish meat sausage manufacturing method includes a fish meat mincing step of mincing fish meat; salt-soluble protein elution step of eluting salt-soluble protein by adding salt to the minced fish meat; a fish meat emulsification step of emulsifying the fish meat by adding soybean oil, soy protein and egg white liquid to the fish meat eluted with the salt-soluble protein; Processed tenderloin manufacturing step of preparing processed tender meat by adding mixed starch, carrageenan and seasoning ingredients mixed with potato starch, acetic acid modified potato starch and tapioca starch to the emulsified fish meat: Filling the processed tenderloin into a casing through a filling machine and molding a filling step to prepare a molded article; And it may include a heat treatment step of heat-treating the processed meat molded product filled in the casing.

The fish meat may preferably be a mixture of pollock and sea bream in a ratio of 6: 4 (pollack: sea bream) based on the weight.

The mixed starch is preferably a mixture of potato starch, acetic acid-modified potato starch, and tapioca starch in a ratio of 7: 2: 1 (potato starch: acetic acid-modified potato starch: tapioca starch) based on the weight.

The seasoning component may be at least one selected from the group consisting of salt, sugar, soy sauce, seasoning (MSG), seasoning, pepper, cheese powder and beet powder.

The heat treatment step may be performed by heat-treating the processed meat molded product filled in the casing at 115 to 125° C. for 5 to 30 minutes.

The heat treatment step may further include a washing process of washing the heat-treated processed meat molded product with washing water for 2 to 3 hours after the heat treatment.

In another aspect, in order to achieve the above object, the present invention provides a fish meat sausage prepared by the method for preparing a fish meat sausage.

The present invention solves the problems of sausages using meat such as pork or previously developed fish sausages, and exhibits excellent texture and flavor due to elasticity comparable to existing pork sausages and unique flavor of fish meat without using pork, as well as, In spite of not using pork or pork fat, it overcomes the short shelf life problem caused by the use of natural starch of existing fish meat sausages. It is a technology with a very high industrial effect as it can contribute to the increase in sales and improvement of profits.

1 shows a schematic diagram for manufacturing fish meat sausage according to an embodiment of the present invention.
2 is a graph showing the change in drip loss (%) according to the preservation conditions of fish meat sausage prepared according to the thickener, that is, the starch type according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat according to the starch type It means sausage, and the vertical axis of each graph means the amount of drip loss (%), Figure 2a shows the change in the refrigeration condition, Figure 2b shows the change in the freezing condition.
3 is a graph showing the change in EM (%) according to the storage conditions of fish meat sausage prepared according to the thickener, that is, starch type according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the starch type , and the vertical axis of each graph means the amount of EM (%), Figure 3a shows the change in the refrigeration condition, Figure 3b shows the change in the freezing condition.
4 is a graph showing the change in hardness according to the storage conditions of fish meat sausage prepared according to the type of thickener, that is, starch according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the type of starch , and the vertical axis of each graph means the hardness value, FIG. 4A shows the change in the refrigeration condition, and FIG. 4B shows the change in the freezing condition.
5 is a graph showing changes in chewiness according to storage conditions of fish meat sausage prepared according to a thickener, that is, starch type according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to starch type , and the vertical axis of each graph means the chewability value, Figure 5a shows the change in the refrigeration condition, Figure 5b shows the change in the freezing condition.
6 is a graph showing changes in shear force according to storage conditions of fish meat sausage prepared according to a thickener, that is, a type of starch according to an embodiment of the present invention. The horizontal axis of each graph is fish meat according to the type of starch. Sausage is meant, and the vertical axis of each graph means shear value. FIG. 6A shows the change in the refrigeration condition, and FIG. 6B shows the change in the freezing condition.
7 is a graph showing the change in drip loss (%) according to the storage conditions of fish meat sausage prepared according to the mixing ratio of mixed starch, that is, starch according to an embodiment of the present invention, and the horizontal axis of each graph is the mixture of starch It means fish meat sausage according to the ratio, and the vertical axis of each graph means the amount of drip loss (%).
8 is a graph showing the change in hardness according to the storage conditions of fish meat sausage prepared according to the mixing ratio of mixed starch, that is, starch according to an embodiment of the present invention, and the horizontal axis of each graph is the mixing ratio of starch means fish meat sausage according to , and the vertical axis of each graph means hardness value.
9 is a graph showing changes in chewiness according to storage conditions of fish meat sausage prepared according to the mixing ratio of mixed starch, that is, starch according to an embodiment of the present invention, and the horizontal axis of each graph is the mixing ratio of starch means fish meat sausage according to , and the vertical axis of each graph means chewiness value.
10 is a graph showing changes in shear force according to storage conditions of fish meat sausage prepared according to a mixing ratio of mixed starch, that is, starch according to an embodiment of the present invention, and the horizontal axis of each graph is the mixture of starch It means fish meat sausage according to the ratio, and the vertical axis of each graph means the shear price value.
11 is a graph showing changes in preference according to storage conditions of mixed starch, that is, fish meat sausage prepared according to the mixing ratio of starch according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat according to the mixing ratio of starch Sausage means sausage, and the vertical axis of each graph means a preference measurement value (sensory evaluation value).
12 is a graph showing the change in drip loss (%) according to the storage conditions of fish meat sausage prepared according to the type of stabilizer according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the type of stabilizer , and the vertical axis of each graph means the amount of drip loss (%).
13 is a graph showing the change in hardness according to the storage conditions of fish meat sausage prepared according to the type of stabilizer according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the type of stabilizer means, and the vertical axis of each graph means the hardness value.
14 is a graph showing changes in chewiness according to storage conditions of fish meat sausage prepared according to the type of stabilizer according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the type of stabilizer Meaning, the vertical axis of each graph means the chewability value.
15 is a graph showing changes in shear force according to storage conditions of fish meat sausage prepared according to the type of stabilizer according to an embodiment of the present invention, and the horizontal axis of each graph is fish meat sausage according to the type of stabilizer , and the vertical axis of each graph means the shear value.

Numerous citations are referenced throughout and the citations of which are indicated throughout this specification. The disclosures of the cited documents are incorporated herein by reference in their entirety to more clearly describe the level of the art to which the present invention pertains and the content of the present invention.

Examples of the present invention will be described below. The following examples are only for illustrating the present invention, and the scope of the present invention is not limited by the following examples.

The present invention relates to a method for producing fish meat sausage, which does not use pork or pork fat, and can control aging of fish meat sausage, thereby increasing the storage period.

Specifically, the fish meat sausage manufacturing method includes a fish meat mincing step; salt-soluble protein elution step; fish meat emulsification step; Processed meat production step; filling step; and a heat treatment step.

Unless otherwise specified in this specification, sausage is a processed food that mainly uses meat such as beef or pork, or uses plants such as fish meat or beans as an alternative material. Of course, it means a representative food that can be used as a simple meal replacement for adults. The sausage is prepared by adding seasonings and spices to edible meat such as beef, pork or fish meat, filling the casing, and then aging and drying, or general sausages smoked or heat-treated and the beef, pork or fish meat, etc. It is a concept that includes all kinds of mixed sausages that are ground or ground without salting or salting, seasonings, spices, etc. added to the casing, then aged and dried, or smoked or heat-treated.

Unless otherwise specified herein, pollack (Walleye pollock, Alaska pollack, Theragra chalcogramma ) is a fish of the Hallyu species belonging to the cod family. The pollock is distributed in the East Sea of Korea, Japan, the Northern Sea of Okhotsk, the Bering Sea, Alaska, and the North Pacific Ocean across the northern United States, and mainly inhabits the coast, continental shelf and continental slope. The spawning of pollock is made at a sea temperature of 1 to 5 ℃, and the spawning season is mainly from December to April. The pollock has a long and slender body, a peculiar pattern is covered throughout, and a large head. The pollock has large eyes, and the lower jaw protrudes forward compared to the upper jaw, and the lower jaw has one short whisker, three dorsal fins and two anal fins, and the rear end edge of the caudal fin is vertical. On the dorsal side of the body of the pollack, about 3 rows of dark brown vertical bands with narrow wavy patterns on a light brown or blue background extend from the back of the head to the tail, and the belly is white and the pectoral fins are black. The pollock mainly floats to the surface at night and eats plankton during the frying period, and when it becomes an adult, it mainly eats small crustaceans (copepods, prawns, amphipods, etc.) or small fish. It is known that there is almost no difference between the male and female pollocks in terms of morphology. The male and female pollock live in groups and start mating between the ages of 3 and 5. After the female lays an egg, in vitro fertilization occurs in which the male sprays sperm and fertilizes it. The pollock moves and lives in groups, and the lifespan is about 12 to 16 years, and there is a report that the longest lived up to 31 years.

The pollack is called ecology, Dongtae, Bukeo (Geontae), Hwangtae, Kodari, Baektae, Heuktae, Kantae, etc. depending on the state. The ecology refers to a fresh biological state, and the dongtae is frozen, and the dried bukeo (dried fish). The term "Hwangtae" refers to a pollack that has turned yellow in one winter by hanging pollack on a deokjang with a large daily temperature difference, and freezing and thawing in the cold wind more than 20 times. The above-mentioned nose bridge is made by inserting 4 to 5 animals through one nose, excluding the intestines and gills, and drying them. In addition, there are white tae, which means dried white, heuktae, which means dried black, and kantae, which means hard dried. Depending on the growth state, young pollack is also called Aegitae, Aetae, or Nogari.

Unless otherwise specified herein, golden-thread/red coat ( Nemipterus virgatus ) is a saltwater fish of the perch family, also called Itoyoridai. The sea bream is distributed in Taiwan, the East China Sea, southern Japan, and the coastal waters of Korea, and is a temperate fish that inhabits the muddy bottom at a depth of 40 to 100 m. The spawning period of the sea bream is from April to August. The caudal fin is deeply dug at the distal end and deep at the upper end, and the upper end extends like a long thread, so it is called a 'single-tailed sea bream'. The body and head of the sea bream are slightly flat to the side, the body is long, the body shape is fusiform, and the rain scales that do not easily fall off the body are covered. The head of the sea bream is small, the eyes of the sea bream are large and are biased toward the back of the head, the mouth of the sea bream is large, and there are four sharp and strong fangs in front of the upper jaw, and the inner and lower jaws of the upper jaw are It has one row of small, sharp teeth. The body of the sea bream is red as a whole and becomes softer toward the belly, 6 to 7 yellow vertical bands are extended on the side of the body, and the front edge of the eyes and the lips are yellow. The sea bream is carnivorous and mainly eats benthic organisms such as shrimp, crabs, midges, and small fish. The sea bream is in season from winter to spring of the following year, and the taste is comparable to that of red sea bream.

Unless otherwise specified herein, surimi is a food made by heating mashed fish meat as a main ingredient, adding salt, forming a dough, and heating it, and is mainly manufactured using pollock (pllock). The tender meat (Surimi) is manufactured through a conventional washing method, specifically, deboning, washing and mincing of fish meat. Among the tender meat, after dehydration through the washing method, sugar and phosphate are added, mixed, and rapidly frozen is called frozen surimi.

The frozen tenderloin is a food material developed in the 1960s at a fishery test site in Hokkaido, Japan, in the process of developing a value-added technology for improving the added value of pollock resources with weak freezing resistance. The frozen meat is marketed according to quality, but evaluation standards are not uniform. The inspection items for the quality evaluation are mainly the elasticity forming ability of the product, moisture content, whiteness, and the like.

The inventor of the present invention solves the problem of poor elasticity and flavor in order to overcome the problems of fish sausage, that is, when using fish meat instead of meat, especially pork, and moisture is released due to aging of starch added to fish meat sausage While research was being conducted to solve the shortcomings of hardening and rapid decrease in texture such as off-flavor due to chemical changes, fish meat used as a pork substitute for fish meat sausage was mixed with pollock and sea bream in a weight ratio of 6: 4 It was confirmed that it is preferable to use one in terms of improvement in texture and elasticity, and based on this, in using fish meat mixed with pollock and sea bream in a weight ratio of 6: 4, the starch used as a thickener In this case, it was confirmed that potato starch, acetic acid modified potato starch and tapioca starch were excellent. When flour, acetic acid-modified potato starch, and tapioca starch are mixed in a ratio of 7: 2: 1 (potato starch: acetic acid-modified potato starch: tapioca starch) based on the weight, the texture and physical properties of the prepared fish sausage are resolved and the starch when stored It has been confirmed that the deterioration of quality due to aging can be suppressed as much as possible, and furthermore, when using a mixed starch obtained by mixing the potato starch, acetic acid modified potato starch and tapioca starch in a ratio of 7: 2: 1 by weight, It was confirmed that the use of carrageenan as a stabilizer is most preferable for maintaining quality during long-term storage by refrigeration or freezing, thereby completing the present invention.

Hereinafter, the present invention will be described in more detail.

The fish meat sausage manufacturing method of the present invention includes a fish meat mincing step; salt-soluble protein elution step; fish meat emulsification step; Processed meat production step; filling step; and a heat treatment step.

In the fish meat chopping step, thawed pollock and thread-tailed sea bream or frozen pollack and thread-tailed sea bream are mixed at a ratio of 6: 4 (Pollack: pollock) based on the weight, and then mixed with an emulsifier or a silent cutter. ) can be used to shred fish meat or to black and white. Mixing using the emulsifier may be performed for 1 minute to 10 minutes or 2 minutes to 5 minutes under conditions of 2,000 rpm to 4,000 rpm or 2,500 rpm to 3,500 rpm. In this aspect, the fish meat may be SURIMI.

The emulsifier is a machine used to more finely chop the pulverized meat for sausages to increase the binding force and at the same time uniformly mix additives such as seasonings, spices, thickeners or stabilizers.

The salt-soluble protein elution step may be performed by adding salt to the minced fish meat to elute the salt-soluble protein. Specifically, in the salt-soluble protein elution step, salt is added to the minced fish meat, and the conditions of 2,000 rpm to 4,000 rpm or 2,500 rpm to 3,500 rpm are 1 to 30 minutes or 2 to 15 minutes or 3 to 10 minutes. It can be carried out by mixing for minutes to elute salt-soluble protein.

The fish meat emulsification step may be performed by adding soy protein, frozen egg white and sweetener to the fish meat eluted with the salt-soluble protein to emulsify the fish meat.

The fish meat emulsification step is performed by adding soy protein, frozen egg white and sweetener to the fish meat from which the salt-soluble protein has been eluted, and under the conditions of 2,000 rpm to 4,000 rpm or 2,500 rpm to 3,500 rpm for 1 minute to 30 minutes or 1 minute 30 seconds to It can be carried out by mixing for 15 minutes or 2 to 10 minutes to emulsify the fish meat.

The sweetener may be salt, for example refined salt, sugar, for example refined sugar, soy sauce, seasoning liquid, seasoning, seasoning, or the like.

The process of preparing the processed meat may be performed by adding an extender to the emulsified fish meat, and mixing it to prepare the processed meat.

The thickener is also called an extender, and may preferably be starch, and more preferably may be mixed starch.

The starch may be at least one selected from the group consisting of potato starch, tapioca starch, sweet potato starch, corn starch, wheat starch, pea starch, and modified starches thereof, preferably consisting of potato starch, tapioca starch and modified potato starch. It may be at least one selected from the group. The modified potato starch may be acetic acid modified potato starch.

The mixed starch may be a mixture of potato starch, acetic acid modified potato starch and tapioca starch, preferably potato starch, acetic acid modified potato starch and tapioca starch 7: 2 : 1 (potato starch: acetic acid modified potato starch) It may be a mixed starch mixed in a ratio of flour: tapioca starch).

In the process of preparing the processed meat, a stabilizer or seasoning component is further added to the extender to the emulsified fish meat, and mixed to prepare the processed meat.

The stabilizer may be karakinan, which is a stabilizer optimized for the mixed starch, in order to suppress the problem of deterioration of fish meat sausage quality.

The seasoning component may be at least one selected from the group consisting of salt, sugar, soy sauce, seasoning (MSG), seasoning, pepper, cheese powder and beet powder.

The filling step may be performed by filling the casing through a filling machine and molding the processed meat to prepare a molded product.

The heat treatment step may be performed by a method of heat-treating the processed meat molded product filled in the casing. Specifically, the heat treatment step may be performed by heat-treating the processed meat molded product filled in the casing at 115 to 125° C. for 5 to 30 minutes.

In addition, the heat treatment step may further include a washing process of washing the heat-treated processed meat molded product with washing water for 2 to 3 hours after the heat treatment.

The following Preparation Examples and Examples are merely exemplified to help the understanding of the present invention, and may be modified in various other forms, and the scope of the present invention is not limited to the following examples.

Statistical analysis of the results measured by the embodiment of the present invention was expressed by means ± standard deviation (SD), the difference between the means of individual experimental groups SPSS version 9.1 analysis system (Statistical Analysis) System, SPSS version 9.1 (SPSS Inc., Chicago, IL, USA) using the with Duncan's multiple range test), was performed by ANOVA (one-way analysis of variance), and in case of P < 0.05, statistical significance was analyzed as having .

Example 1. Preparation and experimental conditions of fish meat sausage according to each condition

As for the tender meat used in the present invention, a mixture of pollock and sea bream purchased from a company in Busan was used in a ratio of 6: 4 (Pollack: sea bream) based on the weight. The thickeners include a total of 9 types of thickeners: wheat starch, potato starch, corn starch, alpha corn starch, tapioca modified starch (Sunmix NA), acetic acid modified potato starch (Sunmix PA), tapioca starch (Sunmix T), pullulan, Acetyl adipic acid was used, respectively, or a thickener of mixed starch obtained by mixing starch at the mixing ratio of starch shown in Table 1 was used. The units in Table 1 below mean the weight % (w/w) of each starch relative to the total weight of the composition.

starch type Mixing conditions One 2 3 4 5 6 7 8 9 10 11 12 potato starch 70 70 70 70 30 0 20 10 0 30 10 20 tapioca starch 30 0 20 10 70 70 70 70 30 0 20 10 Acetate Modified Potato Starch 0 30 10 20 0 30 10 20 70 70 70 70

The fish meat sausage manufacturing method was prepared in the following way.

First, frozen pollock (Frozen Pollock Surimi, A grade) and frozen sea bream (Frozen ITOYORI Surimi KA) were stored in a freezer at -18℃ to maintain freshness, and stored in a refrigerator (below 10℃) before use. It was used after thawing for 20 hours.

5.9 kg of fish meat, which is a mixture of the thawed pollack tenderloin and sea bream tenderloin in a ratio of 6: 4 based on the weight, is placed in a silent cutter, and ground at 3,000 rpm for 2 minutes and 30 seconds to shred the fish meat. did. 120 g of refined salt and 20 g of acidity regulator (sodium phosphate) were added to the minced fish meat, and ice was added to suppress temperature rise, followed by eluting salt-soluble protein at 3,000 rpm for 4 minutes (salt grinding) that is , the first mixing step was performed.

598 g of soybean oil (soybean oil), 190 g of soybean protein, and 733 g of whole egg (egg white liquid) were added to the dough after the first mixing, and ice was added to suppress the temperature rise, followed by an emulsification process at 3,000 rpm for 3 minutes was performed.

After the emulsification process, 279 g of D-sorbitol solution, 44 g of seasoning, 48 g of Miwon (MSG) and 90 g of sugar are added, and 1.5 kg of one or more selected from several types of starch or any one of several types of stabilizers 10 g, and then ice was added to suppress the temperature rise, and then the processed meat production step, that is, the second mixing step, was performed at 3,000 rpm for 2 minutes.

After performing the process for preparing the processed meat, 280 g of cheese is added to the processed meat, blended at 600 rpm for 20 seconds, filled in a casing, and then heated at 115 to 121° C. for 15 minutes, followed by washing water Washed for 2 hours and cooled for 15 minutes.

The cooled fish meat sausage was stored refrigerated or frozen. Specifically, the fish meat sausage samples prepared for each type of starch or stabilizer are stored for 30 days by dividing them into refrigeration (10 ℃ or less) or freezing (-18 ℃ or less) conditions, and the samples are taken on days 0, 7, and 30. And an experiment to evaluate the preference was performed. For the above evaluation, the frozen samples were thawed in refrigeration conditions for 20 hours and then used for the test.

The evaluation of the physical properties and acceptability was performed in the following way.

First, the drip loss (%) measurement was performed in the following way. The amount of drip was measured by Equation 1 below based on the sample weight before and after thawing measured after the frozen sample was stored at 10° C. or lower for 20 hours. In Equation 1 below, W1 means the weight of the sample before thawing, and W2 means the weight of the sample after thawing.

[Formula 1]

Drip(%) = (W1 - W2) / W1 × 100

In addition, expressible moisture (EM, %) was measured in the following way. First, prepare 4 sheets of filter papers (Whatman) for each condition (2 sheets below, 2 sheets above sandwich shape), cut each sample 10 mm thick, measure the weight, and place a flat plate weighing 1 kg on top. After lifting and holding for 2 minutes, the weight was measured and the amount of EM (%) was measured by Equation 1 below. In Equation 2 below, W1 means the weight of the sample before thawing, and W2 means the weight of the sample after thawing.

[Formula 2]

EM(%) = (W1 - W2) / W1 × 100

In addition, the texture analysis of fish meat sausage was performed in the following way. First, a sample for measuring physical properties was prepared by cutting it into 10 mm (L) × 10 mm (W) × 10 mm (H), and for the sample, using a texture analyzer (BROOKFIELD, CT3 Texture Analyzer, USA), the following table Under the conditions of 2, hardness and chewiness were measured.

In addition, the shear force measurement of fish meat sausage was performed in the following way. First, a sample for shear cost measurement was prepared by cutting it into 10 mm (L) × 10 mm (W) × 10 mm (H), and for the sample, using a texture analyzer (BROOKFIELD, CT3 Texture Analyzer, USA), the following table Shear force (Fracturability, Shear force) was measured under the conditions of 3.

Example 2. Confirmation of experimental results according to the type of thickener (starch)

When storing fish meat sausage samples according to the types of the 9 kinds of thickeners (starch) prepared in Example 1 under refrigeration (10 ° C or less) or freezing (-18 ° C or less) conditions to check the optimal thickener , Drip loss (%), EM (%) and changes in physical properties (Texture and Shear force) were confirmed for 30 days, and the results are shown in FIGS. 2A to 6B and Tables 4 to 7 below.

2 and Table 4, as a result of measuring the change in drip loss (%) when storing fish meat sausages prepared with 9 different starches under refrigeration and freezing conditions for 30 days, The average drip loss (%) was 0.94 ± 0.11% on the 0th day, 1.13 ± 0.17% on the 7th day, and 1.01 ± 0.29% on the 30th day. became

Specifically, in the case of comparison according to the type of starch in refrigeration, corn, alpha corn and pullulan showed a higher drip loss (%) than the average value, whereas wheat, potato, tapioca modified starch (Sunmix NA), and acetic acid modified potato pancake. Minute (Sunmix PA), tapioca starch (Sunmix T), and acetyladipic acid showed drip loss (%) values lower than the average value.

In addition, the average drip loss (%) in frozen storage is 1.18 ± 0.24% on the 7th day and 1.19 ± 0.37% on the 30th day, with an average difference of 0.25% on the 0th and 30th days, which is about 3 times higher than the average value of refrigeration. became

In detail, in the case of comparison according to the type of starch in the frozen storage, corn, alpha corn and pullulan were higher than the average value in the comparison according to the type of starch, and wheat, potato, tapioca modified starch (Sunmix NA), acetic acid modified potato pancake Flour (Sunmix PA), tapioca starch (Sunmix T), and acetyladipic acid showed drip loss (%) lower than the average value.

From the above results, it was judged that corn, alpha corn, and fullulan were not appropriate in terms of moisture escape of fish meat sausages according to the temperature difference.

In addition, the change in expressible moisture (EM, %) was measured when fish meat sausages prepared by using 9 different starches were stored in refrigeration and freezing conditions for 30 days, and the results are shown in FIG. 3 and Table 5 below. Since the EM (%) is a value that flows out of the food when a weight is applied differently from the drip loss, which is the juice that naturally flows out from the food when thawing the refrigerated or frozen product, compared to the drip loss (%), EM ( %), there was a clear difference according to the type of starch.

As shown in FIGS. 3 and 5, the average EM (%) of fish meat sausages refrigerated was 2.88 ± 1.40% on day 0, 2.81 ± 1.31% on day 7, and 3.55 ± 2.44% on day 30, with similar differences until 7 days. However, it was found that on the 30th day, the percentage increased by 23% and the quantitative increase by 0.67%.

In detail, in comparison according to starch type, corn, alpha corn and pullulan showed higher than average values, and wheat, potato, tapioca modified starch (Sunmix NA), acetic acid modified potato starch (Sunmix PA), and tapioca starch (Sun). Mix T), acetyladipic acid showed a lower EM (%) than the average value.

In the case of frozen storage, the average EM (%) was 3.17 ± 1.45% on the 7th day and 3.53 ± 1.74% on the 30th day.

In detail, in the comparison according to the type of starch, corn, alpha corn and pullulan showed higher than average values, while wheat showed a gradual increase over time. Also, wheat, potato, tapioca-modified starch, acetate-modified potato starch, tapioca starch, and acetyladipic acid showed lower EM (%) than the average value.

Wheat, corn, alpha corn, and pullulan were judged to be inappropriate in terms of moisture loss in fish sausages according to temperature differences, and potato starch, tapioca starch and acetic acid-modified potato starch were judged to be appropriate.

In addition, the results of measuring the changes in the hardness (Hardness, g) and chewiness (chewiness, gcm) of the texture (Hardness, g) and chewiness (gcm) of fish sausages prepared by using 9 different starches when stored under refrigeration and freezing conditions for 30 days are shown in Table 6 and Fig. 4 and 5 are shown.

First, as shown in Table 6 and FIGS. 4 and 5, the average hardness (Hardness, g) of fish sausages when refrigerated was 617.97 ± 273.79 g on the 0th day, 865.33 ± 344.25 g on the 7th day, and 998.28 ± 286.07 on the 30th day. In terms of g, the hardness increased over time, and in the correlation between hardness and drip loss (%), on day 0, the hardness decreased as the drip loss (%) increased. In particular, corn (494.4 g), alpha The hardness of corn (201.4 g) and pullulan (173.2 g) was low overall, and it was judged that the starch was unsuitable for sausage, as water loss significantly increased. In addition, when comparing the hardness of the 30th day and the 0th day, the change in starch was the lowest in potato (219.1 g), acetic acid modified potato starch (Sunmix PA, 265.5 g), and tapioca starch (Sunmix T, 266.0 g). On the other hand, acetyladipic acid (393), tapioca-modified starch (Sunmix NA, 406 g), and wheat (615.8 g) were judged to have large quality changes as their width increased.

Also, in the case of frozen storage, the average hardness of fish meat sausages with different starch was 910.6 ± 404.9 g on the 7th day and 933.9 ± 394.9 g on the 30th day, which was slightly higher than that of the refrigerated fish meat sausage, but the overall trend was similar. When the hardness of the 30th day and the 0th day were compared, as in the case of refrigerated storage, it was confirmed that potato (148.2 g), tapioca starch (291.9 g), and acetic acid-modified potato starch (330.9 g) had the lowest change in starch.

In addition, the average chewiness (g cm) of fish meat sausages when refrigerated was 159.02 ± 80.24 g cm on the 0th day, 189.07 ± 101.38 g cm on the 7th day, and 216.69 ± 106.86 g cm on the 30th day, as time passed. In particular, on day 0, wheat, corn, alpha corn, and pullulan showed a trend lower than the overall average value.

In addition, when comparing the hardness of the 30th day and the 0th day, the change in starch was the lowest in tapioca starch (Sunmix T, 8.0 g cm) and acetic acid-modified potato starch (Sunmix PA, 8.6 g cm) and was stable. , followed by potato starch (55.6 g·cm), tapioca modified starch (Sunmix NA, 73.8 g·cm), and acetyladipic acid (118 g·cm) in that order, and it was confirmed that chewiness increased somewhat.

In addition, in the case of frozen storage, the average chewiness (g cm) of fish meat sausages with different starch was 192.78 ± 101.17 g cm on the 7th day and 204.78 ± 94.54 g cm on the 30th day. A similar trend was shown. When the hardness of the 30th day and the 0th day were compared, the range of change by starch decreased in the case of potatoes as in the case of refrigerated storage, and acetic acid modified potato starch (Sunmix PA, 22.9 g cm), tapioca starch (Sunmix T, 38.2 g ·cm) was the lowest, and was stable, followed by acetyladipic acid (72.0 g·cm) and tapioca-modified starch (Sunmix NA, 118.5 g·cm) with slightly increased chewiness.

In addition, the results of measuring the change in shear force when storing fish sausages prepared with 9 different starches under refrigeration and freezing conditions for 30 days are shown in Tables 7 and 6 below.

As shown in Table 7 and Figure 6, the average shear price when refrigerated fish meat sausage was 154.53 ± 83.34 g on the 0th day, 222.23 ± 123.65 g on the 7th day, and 308.10 ± 129.13 g on the 30th day, showing a tendency to increase with time. seemed In addition, in the case of frozen storage, the average shear price of fish meat sausages with different starch was 335.73 ± 138.74 g on the 7th day and 418.83 ± 157.51 g on the 30th day, which was 1.5 times higher than the value during refrigeration.

Specifically, in comparison according to starch, the shear values of corn, alpha corn, and pullulan were 4.8 to 120 g on day 0, lower than the average value, whereas potatoes, wheat, and acetyladipic acid were found to be high at 196 to 296 g. and tapioca-modified starch, acetic acid-modified potato starch, and tapioca starch were found to be 130 to 166 g.

From the above results, when examining the experimental results based on potato starch, corn, alpha corn, and pullulan showed higher water loss, significantly lower hardness, and greater change over time compared to potato starch. It was judged that it was difficult to apply to sausage, and wheat, tapioca modified starch, and acetyladipic acid showed less water loss over time compared to potato starch, but showed relatively high values in hardness and chewiness to maintain their inherent elasticity. found to be difficult to do. On the other hand, acetic acid-modified potato starch and tapioca starch, similar to potato starch, have less moisture loss, maintain their intrinsic elasticity, and show relatively stable changes in physical properties compared to other starches when stored in refrigeration and freezing even over time. It was judged to be suitable for manufacturing.

Example 3. Confirmation of experimental results according to the mixing ratio of the thickener (starch)

In the production of fish meat sausage in Example 2, mixed starch was prepared from three starches confirmed as suitable as thickeners, namely potato starch, acetic acid-modified potato starch, and tapioca starch. The mixing ratio of specific mixed starch that can solve the problem of using each starch alone was confirmed. Specifically, in order to solve the problem of potato starch, which has an effect as a thickener in terms of stability of physical properties and is economically inexpensive, but easily aging, acetic acid-modified potato starch (Sunmax PA) and tapioca at the mixing ratio shown in Table 1 above. Starch (Sunmix T) was added, and the physical properties according to the addition ratio of the added starch were confirmed.

Conditions and methods for preservation and thawing of sausages for carrying out the experiment, and measurement of drip loss (%), texture, specifically hardness and chewiness were performed by the methods of Examples 1 and 2 above.

In addition, sensory evaluation (score) was additionally performed to confirm the optimal conditions for manufacturing fish meat sausage according to the optimal addition ratio. For the sensory evaluation, items of appearance, flavor, taste, texture, and overall preference were measured through 10 well-trained panel members. 9 points were the strongest, and the higher the preference, the higher the score.

Specifically, fish meat sausages were prepared by varying the mixing ratio of each of the three types, potato starch, acetic acid modified potato starch and tapioca starch, and preserved in cold sugar and frozen conditions, drip loss (%), texture, shear cost Changes in (shear force) and sensory evaluation were confirmed for 30 days, and the results are shown in FIGS. 7 to 11 .

As shown in FIG. 7, the overall drip loss (%) was 0.92 ± 0.15% on the 0th day average, 1.75 ± 0.13% on the 7th day, 1.91 ± 0.18% on the 30th day when refrigerated, and 1.31 ± 0.18% on the 7th day when cryopreserved. 0.15%, 1.96 ± 0.16% on the 30th day, showing an overall tendency to increase over time.

The drip loss (%) of 1.5% or less on the 30th day was confirmed as the lowest in the experimental group of condition 4 in refrigeration and the experimental group of condition 2 or 4 in freezing. From the above results, it was determined that acetic acid-modified potato starch was significant in stably maintaining the bond between fish meat and starch and lowering water loss. On the other hand, it was confirmed that moisture loss was increased in the mixing ratio maintained at 70% of acetic acid-modified potato starch and tapioca starch. Therefore, it was confirmed that the combination with the best effect of preventing moisture escape during refrigeration and cryopreservation was condition #4.

In addition, the three types of starch, specifically potato starch, tapioca starch, and acetic acid modified potato starch, were prepared by varying the ratio of the added starch according to the respective mixing ratios in Table 1, and then preserved for 30 days and stored for 30 days. Changes in hardness and chewiness were confirmed and shown in FIGS. 8 to 10 .

As a result of the measurement of hardness (Hardness, g) shown in FIG. 8, the average of 682.82 ± 43.68 g on the 0th day was 816.12 ± 61.48 g on the 7th day, 825.89 ± 49.36 g on the 30th day, and 784.27 ± 66.23 g on the 7th day when refrigerated. , 904.88 ± 63.27 g on the 30th day, and an overall tendency to increase over time was confirmed.

Specifically, the hardness of the 30th day under freezing conditions was increased by 1.3 to 1.7 times compared to the 0th day when 80 wt% or more of tapioca starch or acetic acid-modified potato starch was used in conditions 5 to 12, whereas the hardness was increased by 70 % (w/w) or more, it was confirmed that the range of change was low by 1.1 to 1.2 times when the hardness value was expressed as a ratio with the 0 day in Conditions 1 to 4, which were mixed. In addition, when the hardness value on the 30th day was compared even in the refrigerated condition, the lowest increase was confirmed in the case of condition 4, about 1.1 times.

From the above results, in terms of hardness of fish sausage prepared by adding the three starches as a thickener at different mixing ratios, the most stable conditions during storage temperature and storage period are 70% potato starch, 10% tapioca starch, and acetic acid modified potato pancake. It was found to be No. 4 formulated at a rate of 20% per minute.

As a result of the measurement of the chewiness (gcm) shown in FIG. 9, the chewiness changed from an average of 184.40 ± 11.46 g cm on the 0th day to 212.95 ± 23.93 g cm on the 7th day and 199.00 ± 21.02 g cm on the 30th day when refrigerated. In cryopreservation, it changed to 179.95 ± 22.60 g cm on the 7th day and 190.85 ± 20.83 g cm on the 30th day, and overall, as time elapsed, the chewiness compared to the day 0 was about 4% and 8% on average when refrigerated and frozen. % showed a tendency to increase.

Specifically, Conditions 1 and 4, in which the potato starch was blended at 70% level, and Condition 11, in which the acetic acid-modified potato starch was blended at 70% level, had a low change in chewiness during storage for 30 days under refrigeration and freezing conditions, resulting in high stability. It was judged that, in the case of challenge 4, the change in chewability was the lowest, and thus the stability was judged to be the highest.

From the above results, in terms of chewing properties of fish sausages prepared by adding the three starches as a thickener at different mixing ratios, the most stable conditions during the storage temperature and storage period are 70% potato starch, 10% tapioca starch, and acetic acid modified potato pancakes. It was found to be No. 4 formulated at a rate of 20% per minute.

As a result of the measurement of the shear force shown in FIG. 10, the shear value changed from an average of 124.20 ± 54.27 g on the 0th day to 267.62 ± 28.61 g on the 7th day and 294.92 ± 21.87 g on the 30th day when refrigerated. It was found to be 506.00 ± 47.40 g and 577.97 ± 31.60 g on the 30th day, and it was confirmed that the average value of the shear price during refrigeration and cryopreservation increased by 2.6 times and 5.1 times, respectively, when compared with the day 0 based on 30 days.

From the above results, in terms of the shear price of fish sausage prepared by adding the three starches as a thickener at different mixing ratios, No. 4 was formulated with 70% potato starch, 10% tapioca starch, and 20% acetate-modified potato starch. In the case of refrigeration and cryopreservation, the increase was 1.5 and 2.7 times on the 30th day compared to the 0th day, and the change was the lowest. The most stable conditions during the storage temperature and storage period were 70% potato starch, 10% tapioca starch, It was found to be No. 4 formulated at a rate of 20% per minute.

As a result of the sensory evaluation shown in FIG. 11, the overall acceptability was confirmed as 7.40 ± 0.38 points on the 7th day and 6.54 ± 0.35 points on the 30th day when refrigerated from an average of 7.55 ± 0.31 points on day 0, and 7.33 ± 0.35 points on day 7 when cryopreserved. It was confirmed as 0.35 points, 6.21 ± 0.29 points on the 30th day. In addition, as a result of comparing the overall acceptability values up to 30 days, it was confirmed that the preference change was small in the order of condition 4, condition 11, condition 5 or condition 6 under the refrigerated condition, and condition 4, condition 6, condition 5 and condition under the frozen condition. In the order of condition 12, it was confirmed that there was little change in the degree of preference.

Specifically, in Conditions 1 to 4, which is a formulation in which 70% of potato starch was added, the overall acceptability value on the initial 0 day was 7.78 ± 0.25 on average, 70% of tapioca starch (7.62 ± 0.19 points) or acetate modified potato starch. It was confirmed that the degree of acceptance was higher than that of 70% formulation (7.25 ± 0.04 points), and the overall acceptability of condition 4 was 7.40 ± 0.18 points in the case of refrigerated conditions and 7.10 ± 0.17 points in the case of frozen conditions on the 30th day from the initial 8.07. It was evaluated as the best compared to other mixing conditions.

From the above results, as a result of examining the overall acceptability of fish sausages prepared with different mixing ratios for the three starches, the most appropriate conditions were 70% potato starch, 10% tapioca starch, and 20% acetic acid-modified potato starch. Formulated condition 4 was identified.

Characteristics of fish meat sausage prepared on the basis of 12 conditions with different mixing ratios for preparing mixed starch using potato starch, tapioca and acetic acid-modified potato starch, which are starches suitable for fish meat sausages for each starch identified in Example 1 As a result of confirming the results, there was no increase or fluctuation on the 30th day compared to the 0th day according to the lapse of time in refrigeration and cryopreservation in No. 4, which is 70% potato starch, 10% tapioca starch, and 20% acetic acid-modified potato starch. The least stable condition for the storage temperature and storage period was condition No. 4, in which 70% of potato starch, 10% of tapioca starch, and 20% of acetic acid-modified potato starch were mixed.

Example 4. Confirmation of experimental results according to the type of stabilizer

In Example 3, it was confirmed that the optimal thickener, specifically, mixed starch mixed with 70% potato starch, 10% tapioca starch, and 20% acetate-modified potato starch, was found to be the most preferable as the manufacturing conditions for preparing the optimal mixture starch. . Based on the results of Example 3, an optimal stabilizer was identified when mixed starch mixed with 70% potato starch, 10% tapioca starch, and 20% acetic acid-modified potato starch was used.

The stabilizer uses a total of 11 kinds of stabilizers, specifically, carrageenan SP-100, carrageenan BF-100, kappa-carrageenan, locust bean gum, xanthan gum, guar gum, gellan gum, gum arabic, pectin, powder agar and sodium alginate. did.

In the production of fish meat sausage in Example 3, using mixed starch mixed with 70% potato starch, 10% tapioca starch, and 20% acetic acid-modified potato starch as a thickener, each physical property was checked according to the type of stabilizer did. Conditions and methods for preservation and thawing of sausages for carrying out the above experiment, and measurement of drip loss (%), texture and sensory evaluation results were performed by the methods of Examples 1 to 3 above.

Specifically, using mixed starch mixed with 70% potato starch under Condition 4, 10% tapioca starch, and 20% acetic acid-modified potato starch in a ratio of 70%, and adding different types of stabilizers, prepare fish sausage, Preserved under frozen conditions, drip loss (%), texture, shear force and changes in sensory evaluation were confirmed for 30 days, and the results are shown in FIGS. 12 to 15 .

12, the overall drip loss (%) is 1.30 ± 0.24% on the 7th day when refrigerated and 1.54 ± 0.11% on the 30th day at an average of 1.18 ± 0.21% on the 0 day, and 1.22 ± 0.23% on the 7th day when cryopreserving 1.54 ± 0.11%, It was confirmed that the overall increase over time was 1.79 ± 0.48% on the 30th day. During cryopreservation, the deviation of drip loss was increased in guar gum, gellan gum, gum arabic, pectin, powder agar and sodium alginate on the 30th day. became In addition, in the results of refrigeration, it was confirmed that the amount of carrageenan and powdered agar increased in moisture loss with the increase of time. From the above results, it was confirmed that locust bean gum, xanthan gum, and kappa-carrageenan, which are stabilizers overall, had a high effect of preventing moisture loss during refrigeration and cryopreservation.

In addition, according to the type of the starch stabilizer, each stabilizer was added to prepare the fish meat sausage, and then stored for 30 days, and changes in the hardness (hardness) and chewiness (chewiness) of the texture were confirmed and shown in FIGS. 13 to 15 .

As shown in FIG. 13, the hardness (Hardness, g) was measured at an average of 664.68 ± 92.27 g on the 0th day, 749.66 ± 158.79 g on the 7th day, and 787.12 ± 194.06 g on the 30th day when cryopreserved at 763.51 ± on the 7th day. 206.51 g, 769.06 ± 203.37 g on the 30th day, it was confirmed that the overall increase over time. In particular, carrageenan, sp-100, carrageenan, and BF-100 increased significantly with the increase of time during refrigeration and cryopreservation, and agar and alginic acid showed a large increase under refrigeration conditions. In addition, kappa-carrageenan, locust bean gum, xanthan gum, guar gum, gellan gum, gum arabic and pectin did not show a significant increase over time in refrigerated and frozen conditions, and were evaluated as stable.

From the above results, it was confirmed that kappa-carrageenan, locust bean gum, xanthan gum, guar gum, gellan gum, gum arabic and pectin were stable during the storage temperature and storage period in terms of hardness of fish sausage according to the stabilizer.

As shown in FIG. 14, as a result of measurement of chewiness (g·cm), when refrigerated at an average of 167.46 ± 31.87 g·cm on day 0, 179.69 ± 25.25 g·cm on the 7th day, 194.73 ± 30.95 g·cm on the 30th day and 129.10 ± 22.59 g cm on the 7th day and 117.15 ± 23.92 g cm on the 30th day during cryopreservation. . Carrageenan sp-100, agar, xanthan gum, and locust bean gum were confirmed as stabilizers with little variation in chewiness between refrigeration and freezing.

From the above results, it was confirmed that kappa-carrageenan, xanthan gum, and locust bean gum were stable during the storage temperature and storage period in terms of the chewiness of the fish sausage according to the stabilizer.

As shown in FIG. 15 , as a result of the measurement of shear force, it was confirmed that the average of 224.28 ± 64.29 g on the 0 day was 303.35 ± 56.44 g on the 7th day, 391.96 ± 104.80 g on the 30th day, and 391.96 ± 104.80 g on the 7th day when refrigerated. It was found to be 467.57 ± 118.87 g and 583.89 ± 141.58 g on the 30th day, and as time passed, the shear price increased by 1.82 times and 2.77 times during refrigeration and cryopreservation, respectively. It was confirmed that kappa-carrageenan was the stabilizer with the least variation in chewiness between refrigeration and freezing.

From the above results, it was confirmed that kappa-carrageenan was the most stable during the storage temperature and storage period in terms of shear price of fish meat according to the stabilizer.

Claims (7)

fish meat mincing step of mincing fish meat; salt-soluble protein elution step of eluting salt-soluble protein by adding salt to the minced fish meat; a fish meat emulsification step of emulsifying the fish meat by adding soybean oil, soy protein and egg white liquid to the fish meat eluted with the salt-soluble protein; Processed tenderloin manufacturing step for preparing processed tenderloin by adding mixed starch, carrageenan and seasoning ingredients mixed with potato starch, acetic acid modified potato starch and tapioca starch to emulsified fish meat: Filling the processed tenderloin into a casing through a filling machine and molding Filling step to prepare a molding; And a heat treatment step of heat-treating the processed meat molded product filled in the casing
Fish meat sausage manufacturing method comprising a. According to claim 1,
The fish meat is a method for producing fish meat sausage, characterized in that it is mixed with pollock and sea bream in a weight ratio of 6: 4 (Pollock: sea bream). According to claim 1,
The mixed starch is potato starch, acetic acid modified potato starch and tapioca starch based on the weight of 7: 2 : 1 (potato starch: acetic acid modified potato starch: tapioca starch) fish meat sausage manufacturing method, characterized in that it is mixed. According to claim 1,
The seasoning ingredients are salt, sugar, soy sauce, seasoning (MSG), seasoning, pepper, cheese powder and beet powder, characterized in that at least one selected from the group consisting of fish sausage manufacturing method. According to claim 1,
The heat treatment step is a fish meat sausage manufacturing method, characterized in that performed by heat-treating the processed meat molded material filled in the casing at 115 to 125 ° C. for 5 to 30 minutes. According to claim 1,
The heat treatment step is a fish meat sausage manufacturing method, characterized in that it further comprises a washing step of washing the heat-treated processed tender meat molded product with washing water after the heat treatment for 2 to 3 hours. A fish meat sausage prepared by the fish meat sausage manufacturing method of claim 1.

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