(1) Technology Transfer from the Food Industry Research and Development Institute, Taiwan :

The optimum cleaning and sterilization technique for fresh oysters and fillets

Cooperation model: technology transfer

Background introduction: ( Note; Chinese Version only)

  As the core elements of a seafood factory, both sanitary safety and superb product quality enhance a company’s competitive advantages compared with the same trades. In this regard, the introduction of modernized health control equipment for promotion of health management technologies improves an enterprise’s competitive advantages.

  The weak-acid sterilizing water with the sterilization effect 50 times as much as sodium hypochlorite for instant sterilization is reduced to ordinary water after sterilization and characteristic of the pH value between 4.0 and 6.5. Based on hypochlorous acid (HOCl) as the major ingredient for sterilization in sodium hypochlorite, the technique of acidic sterilizing water is to produce stable and qualified acidic sterilizing water from the sterilizing water generator in which the concentration is configured. The acidic sterilizing water, which is effective in sterilization and safer than sodium hypochlorite and features less adverse effect (corrosive effect) on food materials (equipment), practicability and low costs, has been widely used in various industries or institutes for sterilization such as food industry, hospital, stock farming, hospitality industry and public places in Japan, Korea, Europe and America.

  The high-concentration electrolyzed ozone water generator is a high-tech product developed in recent years. Based on PEM (Proton Exchange Membrane) electrolysis, the ozone generator, which electrolyzes pure water for production of ozone, is able to manufacture ozone water directly with proprietary filtering and air-water mixing techniques integrated. Featuring fast oxidation and decomposition, the high-concentration electrolyzed ozone water is effective in deodorization and sterilization of foods and utensils, oxidation and decomposition of residual pesticides on vegetables and fruits, and removal and deodorization of chlorine remained in water for various commercial applications such as vegetable & fruit processing center, food factory, seafood processing center, laundry, pool, cooling tower, stock farming and aquaculture.

  To obey standards of food & sanitation laws for microbes, the optimized method of cleaning and sterilizing oysters and fillets uses both weak-acid sterilizing water and high-concentration electrolyzed ozone water.

 

Technologies to be transferred:

  1. Evaluations of sterilization effects of newly-developed weak-acid sterilizing water and high-concentration electrolyzed water on microbes according to consumption, pH value, stability, concentration, temperature and time
  2. Evaluations of sterilization effects of newly-developed weak-acid sterilizing water and high-concentration electrolyzed water on fresh fillets according to consumption, pH value, stability, concentration, temperature and time

 

Contact window:

Please refer to Super Aqua

 

Technology Transfer Survey

Title The optimized method to clean and sterilize seafood including fresh oysters and fillets
Item No.  
Description Control of microbes and extension of shelf lives by cleaning and sterilization techniques
Applicable industry Fishery and other food industries
Applicable products Fresh oysters and fillets
Technical specifications Evaluations of sterilization effects of weak-acid sterilizing water and high-concentration electrolyzed ozone water on fresh fillets according to concentration, temperature, pH value and time consumption
Features Acidic sterilizing water with neither trichloromethane nor toxic gases such as high-concentration electrolyzed ozone and nitric oxide (NOx)
Granted patent  
Benefit
(output value)
Promotion of sanitary safety and product quality
Recommendation for technology-transfer applicants Cleaning and sterilization of equipment and workplaces
Contact window for techniques  
Contact window for technology transfer  
Costs and methods for technology transfer  
For more detailed information, please refer to Super Aqua:

 

 

(2) Notice for employment of hypochlorous acid liquids issued by the Ministry of Health and Welfare,R.O.C.( Taiwan ):

Appendix1. The substances which used to disinfect food-contact surfaces shall apply to:

NO CAS Reg. No. Substance Use limitation*
1 64-19-7 Acetic acid 686 ppm
2 98-55-5 Alpha-terpineol None (Note 2)
3 12125-02-9 Ammonium chloride 48 ppm
4 10043-52-4 Calcium chloride 17 ppm
5 7778-54-3 Calcium hypochlorite 200 ppm as total available chlorine (Note 2)
6 1592-23-0 Calcium stearate None
7 3347-48-5 Decanoic acid Dairy processing equipment: 90 ppm
Other food-contact surfaces: 234 ppm
8 7173-51-5 Didecyldimethylammonium chloride Active quaternary compound: 200 ppm (Note 2)
9 139-33-3 Disodium ethylenediaminetetraacetate 1400 ppm
10 27176-87-0 Dodecyl-benzenesulfonic acid Dairy processing equipment: 5.5 ppm
Other food-contact surfaces: 400 ppm
11 64-17-5 Ethanol None
12 111-76-2 Ethylene glycol monobutyl ether None (Note 2)
13 7790-92-3
Hypochlorous acid
200 ppm as total available chlorine
14 10034-85-2 Hydriodic acid 25 ppm of titratable iodine
15 7722-84-1 Hydrogen peroxide Dairy processing equipment: 465 ppm
Other food-contact surfaces: 1100 ppm
16 7553-56-2 Iodine 25 ppm of titratable iodine
17 13840-33-0 Lithium hypochlorite 200 ppm as total available chlorine and 30 ppm lithium (Note 2)
18 50-21-5 Lactic acid Dairy processing equipment: 138 ppm
Other food-contact surfaces: None
19 1309-48-4 Magnesium oxide None
20 7558-80-7 Monosodium phosphate 350 ppm
21 26896-20-8 Neo-decanoic acid 174 ppm (Note 2)
22 7697-37-2 Nitric acid 1000 ppm
23 112-05-0 Nonanoic acid 90 ppm
24 7378-99-6 N,N-dimethyloctanamine 113 ppm
25 124-07-2 Octanoic acid Dairy processing equipment: 176 ppm
Other food-contact surfaces: 234 ppm
26 3944-72-7 1-Octanesulfonic acid 172 ppm (Note 2)
27 28805-58-5 Octenyl succinic acid 156 ppm
28 90-43-7 ortho-Phenylphenol 400 ppm (Note 2)
29 None Oxychloro species (predominantly chlorite, chlorate and chlorine dioxide in an equilibrium mixture) generated either (i) by directly metering a concentrated chlorine dioxide solution prepared just prior to use, into potable water, or (ii) by acidification of an aqueous alkaline solution of oxychloro species (predominately chlorite and chlorate) followed by dilution with potable water 200 ppm as total available chlorine
30 None Oxychloro species (including chlorine dioxide) generated by acidification of an aqueous solution of sodium chlorite. 200 ppm as total available chlorine
31 79-21-0 Peroxyacetic acid 315 ppm
32 33734-57-5 Peroxyoctanoic acid 122 ppm
33 2809-21-4 1-hydroxyethylidene-1 1- diphosphonic acid (HEDP) 34 ppm
34 7664-38-2 Phosphoric acid None
35 7758-02-3 Potassium bromide Dairy processing equipment: 46 ppm total available halogen
Other food-contact surfaces: 200 ppm total available halogen
36 7681-11-0 Potassium iodide 25 ppm of titrateble iodine
37 7778-66-7 Potassium hypochlorite 200 ppm as total available chlorine (Note 2)
38 79-09-4 Propionic acid 297 ppm
39 499-83-2 2,6-Pyridinedicarboxylic acid 1.2 ppm
40 8001–54–5 (Quaternary ammonium compounds, including cetylpyridinium chloride)
1.alkyl (C12-C18) benzyldimethyl, chlorides
the end-use concentration of all quaternary chemicals in the solution is not to exceed 200 ppm of active quaternary compound
41 68424–85–1 2.n-alkyl (C12-18) dimethyl benzyl ammonium chloride the end-use concentration of all quaternary chemicals in solution is not to exceed 400 ppm of active quaternary compound
42 85409–23–0 3.n-alkyl (C12-14) dimethyl ethylbenzyl ammonium chloride, average molecular weight (in amu), 377to 384. the end-use concentration of all quaternary chemicals in solution is not to exceed 400 ppm of active quaternary compound
43 None 4.n-alkyl (C12-18) dimethyl ethylbenzyl ammonium chloride, average molecular weight (in amu) 384. the end-use concentration of all quaternary chemicals in the solution is not to exceed 400 ppm of active quaternary compound
44 None 5.di-n-Alkyl(C8-10) dimethyl ammonium chloride, average molecular weight (in amu) 332 to 361. the end-use concentration of these specific in quaternary ammonium compounds is not to exceed 240 ppm of active quaternary ammonium compound; the end-use concentration of all quaternary chemicals in the solution is not to exceed 400 ppm of active quaternary compound
45 148788–55–0
/148812–654–1
6.didecyl dimethyl
ammonium carbonate /didecyl dimethyl
ammonium bicarbonate
the end-use concentration of these specific ammonium compounds is not to exceed 240 ppm of active quaternary ammonium compound
46 5324-84-5 Sodium 1-octanesulfonate 312 ppm (Note 2)
47 7647-15-6 Sodium bromide 200 ppm total available halogen (Note 2)
48 527-07-1 Sodium gluconate 760 ppm
49 7681-52-9
1310-73-2
Sodium hypochlorite 200 ppm as total available chlorine
50 7681-82-5 Sodium iodide 25 ppm of titratable iodine (Note 2)
51 7775-19-1 Sodium metaborate None (Note 2)
52 68309-27-3 Sulfonated tall oil fatty acid 66 ppm (Note 2)
53 7664-93-9 Sulfuric acid 228 ppm (Note 2)
54 64-02-8 Tetrasodium ethylenediamine tetraacetate None

*”Limitations” means the end-use concentration maximum limits, when ready for use.

  • Note 1. In composite formulation's product, each single component's concentration limits shall apply this table.
  • Note 2. Not apply to dairy processing equipment.
  • Note 3. Used to the cleanser substances in this table, should adequate draining or dried volatile to avoid detergent residue on food contact surfaces.

 

Appendix2. The substances which used to disinfect food shall apply to:

NO CAS Reg. No. Substance Residue Limit
1 None Acidified sodium chlorite solutions (ASC)
(Note 2)
Not more than 1 ppm as total available chlorine.
2 10049-04-4 Chlorine dioxide Not more than 1 ppm as total available chlorine.
3 7790-92-3 Hypochlorous acid Not more than 1 ppm as total available chlorine.
4 7681-52-9 Sodium hypochlorite Not more than 1 ppm as total available chlorine.
  • Note 1. After used for the compounds listed in the table, shall be followed by a potable water rinse or by blanching or cooking, the final food contains no more than the limitations specified in the Table.
  • Note 2. Acidified sodium chlorite solutions (ASC): The substance is produced by mixing an aqueous solution of sodium chlorite (CAS Reg. No. 7758-19-2) with any generally recognized as safe (GRAS) acid; achieve a pH of 2.3 to 2.9.
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