JP2004161600A - Hollow carrier, functional particle and manufacture method of the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hollow carrier composed of basic magnesium carbonate having a tubular structure, a functional particle in which an effective component is incorporated inside the tubular structure of the hollow carrier and which has excellent controlled release property, masking effect and leakage preventing property and a method of manufacturing the same. <P>SOLUTION: The hollow carrier composed of a tubular aggregated particle of basic magnesium carbonate by preparing the basic magnesium carbonate under a specific condition and the functional particle is manufactured by bringing the hollow carrier into contact with one or more kinds of the effective components to include the components. The manufactured functional particle exhibits excellent characteristics such as stable controlled release effect, deterioration preventing effect, masking effect or protective effect because of the peculiar structure that the compounds are included inside the tubular structure. Particularly in the controlled release effect, an excellent characteristic that the release rate is controlled by controlling the length, the inside diameter or the thickness of the tube is attained. <P>COPYRIGHT: (C)2004,JPO

Description

【０１５３】
[防黴性の評価]
応用実施例２及び応用比較例２で製造した塩酸アルキルポリアミノエチルグリシンを含浸させた機能性粒子、並びに塩酸アルキルポリアミノエチルグリシンを含浸していない製造比較例１の塩基性炭酸マグネシウム粒子の防黴性を評価するため以下の試験を行った。
【０１５４】
すなわち、ガラス製のデシケータの下部に水をはり、中段に置いたシャーレに上記粒子を敷き、その上にＮｏ．５Ｃのろ紙をのせ、さらにその上に３ｃｍ角で厚さ１．２ｃｍの食パンを置いた。また蓋は１０％の開放状態とし、２８℃に設定したインキュベーター内に保管した。その後、３０日後、９０日後、１２０日後の食パンに生えたカビの発生の有無を調べた。
【０１５５】
その結果は表２に示すとおりであり、応用実施例２で製造した管状構造を有する塩基性炭酸マグネシウムを中空担体として使用した機能性粒子は１２０日後もカビの発生は認められなかった。一方、製造比較例１〜３の塩基性炭酸マグネシウムを使用した応用比較例２の機能性粒子については、９０日後からカビの発生が認められた。また塩酸アルキルポリアミノエチルグリシンを含浸していない塩基性炭酸マグネシウムでは、３０日後には多量のカビが発生していた。
【０１５６】
【表２】

【０１５７】
[鰹フレーバーのマスキング効果の評価]
応用実施例３及び応用比較例３で製造した鰹フレーバー内包機能性粒子を２００ｍｌのビーカー６個にそれぞれ１０ｇづつ、また別の２００ｍｌのビーカー６個に市販の鰹フレーバーをそれぞれ６．２ｇづつ量り取り、室温２３℃で湿度５０％の恒温恒湿室に保管した。試験開始日、３日後、１週間後、２週間後、１ヵ月後、２ヵ月後に、１００ｍｌの熱湯をビーカーに注ぎ、香気の強さを調べた。
【０１５８】
その結果は表３に示すとおりであり、応用実施例３の鰹フレーバー内包機能性粒子では、２ヵ月後でも強い香気を発することを確認した。一方、製造比較例１〜３の塩基性炭酸マグネシウムを使用した応用比較例３のものでは、１週間後には香気が弱くなり、２週間後には香気はほとんど感じられなかった。また市販の鰹フレーバーは、３日後には香気は弱くなり、１週間後には香気は殆ど感じられない状態であった。
【０１５９】
【表３】

【０１６０】
以上の結果から、すなわち表１〜３より明らかなように、応用実施例の機能性粒子は、塩基性炭酸マグネシウムの薄片状微細結晶の管状凝集粒子からなる中空担体という独特の形状に由来して、高い徐放性やマスキング効果を有していることがわかる。
【０１６１】
【発明の効果】
本発明の機能性粒子は、塩基性炭酸マグネシウムの薄片状微細結晶の管状凝集粒子からなる中空担体を各種の有効物質と接触させ管状構造の内部に内包させることにより、比較的簡便な手法により製造できる。そしてこの管状という独特の形状は、長期にわたる安定した徐放効果、特定環境下で内包物を放出する放出制御性、変質防止効果、マスキング効果、保護効果などという優れた特性を発現する。
【０１６２】
特に、徐放効果においては、管の長さ、内径や厚みを制御することにより、その放出速度を制御できるという優れた特性をも備えるものである。
さらに、上記の機能性粒子は、必要に応じて表面を有機高分子により被覆し、内包した物質の漏洩を防止したり、保護効果を高めることにより、多様な用途に対応できる。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a novel and specially shaped hollow carrier made of basic magnesium carbonate, functional particles using the hollow carrier, and methods for producing the same. More specifically, a hollow carrier composed of tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate, and functional particles containing aroma substances, nutrients, food additives, medicines, agricultural chemicals, fertilizers and the like in the hollow carrier, And their production methods.
[0002]
[Prior art]
[Patent Document 1] Japanese Patent No. 1207124
[Patent Document 2] JP-A-61-31314
[Patent Document 3] Japanese Patent Application Laid-Open No. 2-208220
[Patent Document 4] JP-A-3-97618
[Patent Document 5] Japanese Patent No. 1635418
[Patent Document 6] Japanese Patent No. 2602444
[Patent Document 7] JP-A-6-285358
[Patent Document 8] JP-A-7-196305
[Patent Document 9] JP-A-7-196314
[Patent Document 10] JP-A-10-5577
[Patent Document 11] JP-A-10-202093
[Patent Document 12] JP-T-2000-500113
[0003]
Magnesium carbonates include magnesium carbonate (rhamite, magnesite), dolomite (dolomite, dolomite), basic magnesium carbonate, and magnesium orthocarbonate. Magnesium carbonate is MgCO _Three Dolomite is a double salt with calcium carbonate, CaMg (CO _Three ) _Two It has the composition of Both of these produce as natural ores, but basic magnesium carbonate does not occur naturally.
[0004]
Basic magnesium carbonate is industrially used in large quantities, and its chemical formula is mMgCO _Three ・ Mg (OH) _Two ・ NH _Two It is represented by O. The values of m and n in this chemical formula vary depending on the manufacturing conditions and the like, and are not constant. However, m is generally 3 to 5, and n is generally 3 to 8. Magnesium carbonate is MgCO _Three ・ NH _Two It is said to have a composition of O (n = 3).
[0005]
Basic magnesium carbonate is usually obtained as irregular aggregated particles of flaky fine crystals, and has a low bulk density of 0.2 to 0.3 g / mL and a relatively high specific surface area of 10 to 40 m2 / g. Has characteristics. Utilizing such characteristics, basic magnesium carbonate is used in fields such as rubber, paint, papermaking, pharmaceuticals, cosmetics, building materials, and ceramic raw materials. In particular, the rubber filler has properties such as imparting a sense of transparency to the compounded natural rubber and improving the strength of the rubber.
[0006]
Examples of the method for producing basic magnesium carbonate include a soda ash method using a reaction between a soluble magnesium salt such as magnesium chloride and sodium carbonate, a charcoal method using a reaction between a soluble magnesium salt and ammonium carbonate, and magnesium hydroxide. A gas method utilizing a reaction with carbon dioxide is known. In any method, magnesium orthocarbonate (chemical formula MgCO 2) obtained as an intermediate product by the reaction of a magnesium source and a carbon dioxide source _Three ・ NH _Two O, and n = 3 is common) or magnesium bicarbonate (Mg (HCO _Three ) _Two ) For a long time to produce basic magnesium carbonate.
[0007]
Research and development on basic magnesium carbonate have been carried out for a long time. For example, in Patent Document 1, a suspension containing orthomagnesium carbonate is aged at an appropriate temperature to obtain a rubber in a short time. Patent Document 2 discloses a method for producing a basic magnesium carbonate having excellent performance as a filler for a synthetic resin by reacting a water-soluble magnesium source with a water-soluble carbonate in the presence of a water-soluble sulfate. A method for producing a basic magnesium carbonate having excellent performance as a filler has been proposed.
[0008]
Patent Document 3 discloses a basic magnesium carbonate having a specific oil absorption and a specific surface area obtained by heating while circulating an aqueous magnesium bicarbonate solution. There has been proposed a basic magnesium carbonate showing a specific X-ray diffraction pattern obtained by heating in the co-presence of. Further, those focusing on the particle shape of basic magnesium carbonate include Patent Document 5 and Patent Document 6, which include spherical porous particles obtained by aggregating primary particles and having a specific bulk density and Basic magnesium carbonate having properties such as specific surface area has been proposed.
[0009]
On the other hand, as a hollow carrier, a porous body, a microcapsule, a hollow body and the like are known. Among these, the carrier utilizing a hollow body includes inorganic hollow fine particles made of silica or the like and organic hollow polymer fine particles. Among them, the inorganic hollow carrier and the functional particles utilizing the same carrier as in the present invention include metal oxide hollow fine particles having a porous and hollow structure described in Patent Document 7 first.
[0010]
Further, a hollow composite space has a hollow space in Patent Literatures 8 and 9, and has a tubular composite synthetic inorganic fine particle satisfying the shape factor defined by the formula, and has a porous calcium hollow shell of Patent Literature 10. There is a method for producing core substance-containing calcium fine particles, and an inorganic hollow capsule having a wall material made of a calcium phosphate crystal disclosed in Patent Document 11.
[0011]
To describe these in more detail, the porous metal oxide hollow fine particles having a hollow structure described in Patent Document 7 are solutions containing one or more kinds of metal salts and having an average droplet diameter of 0.1 to 500 μm. The droplets are sent to a high-temperature reactor in a gas-liquid mixed phase using a carrier gas, and the metal salts contained in the droplets are thermally decomposed inside the reactor to form a porous and hollow structure. To produce metal oxide hollow fine particles.
[0012]
The tubular composite synthetic inorganic fine particles disclosed in Patent Literatures 8 and 9 refer to a needle-like and / or columnar particle composed of a substance X as a core, the surface of which is coated with a substance Y different from the core, and a needle. A substance Y treated substance X (a substance X coated with a substance Y), which is a shape and / or a columnar particle, is prepared. There is a method of removing the whole or a part of the substance X serving as the core of the prepared substance Y, which is the prepared needle-like and / or columnar particles, and preparing a hollow space therein. It is described that the substance Y coated by the above method is preferably generated by a reaction between the substance X and the additive substance Z.
[0013]
Patent Literature 10 discloses a method for producing core substance-containing calcium fine particles having a porous calcium hollow shell, in which an edible oil and a calcium shell-forming substance are added to water and stirred at high speed to form an O / W emulsion, A step of forming and solidifying a calcium shell on the surface of the oil droplet by static electricity generated by friction between the oil droplet and the water droplet, and a step of obtaining an edible oil-containing calcium shell by separating and drying a solid substance by centrifugation or filtration, It comprises a step of replacing the edible oil in the calcium shell with an alcohol or a polar solvent and drying.
[0014]
In the inorganic hollow capsule having a wall material composed of a calcium phosphate crystal disclosed in Patent Document 11, an aqueous suspension of calcium carbonate is reacted with an aqueous solution of a water-soluble phosphoric acid or a water-soluble salt thereof to form tribasic calcium phosphate and / or hydroxyapatite. A crystal layer is formed on the surface of the calcium carbonate particles, and then a water-insoluble calcium phosphate salt or an aqueous suspension thereof is reacted to elute the internal calcium carbonate, thereby forming a wall material of the tricalcium phosphate and / or hydroxyapatite crystal layer. Is formed and the center of the particle is hollow.
[0015]
Further, Patent Document 12 also discloses a method for producing hollow silica particles, in which active silica is precipitated on a support made of a material other than silica, and the formed silica slurry is separated. Then, the recovered silica suspension is dried and the support is removed to obtain a dense silica shell.
[0016]
[Problems to be solved by the invention]
The conventional inorganic hollow fine particle carrier and functional particles containing various substances include various types as described above, the functions thereof are as described above, and the production method is complicated and complicated as described above, There are many problems, such as the need for special processing steps and the use of expensive drugs. For this reason, inorganic hollow carriers and functional particles which can be produced by simpler processes and have excellent functions are desired.
[0017]
Under such circumstances, the present inventors have succeeded in developing a novel shape, that is, tubular aggregated particles composed of flaky fine crystals of basic magnesium carbonate, and have already applied for a patent (Japanese Patent Application No. 2002-179462; Application 2002-220768). The present inventors have paid attention to this tubular structure, and have attempted to solve the above problem by using tubular aggregated particles composed of flaky fine crystals of basic magnesium carbonate as a carrier for functional particles. .
[0018]
As a result, it is possible to gradually release the inclusions over a long period of time, control the release rate, release the inclusions in a specific environment, control the deterioration of the inclusions, and exhibit the masking effect The present invention has found that functional particles can be produced and succeeded in development. That is, an object of the present invention is to provide a hollow carrier comprising tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate having a unique and novel shape, functional particles utilizing the shape of the hollow carrier, and production thereof. It is to provide a method.
[0019]
[Means for Solving the Problems]
The present invention provides a novel and specially shaped hollow carrier made of basic magnesium carbonate, functional particles using the hollow carrier, and methods for producing the same, in order to solve the above problems. . Among them, the hollow carrier is characterized by being composed of tubular aggregated particles of flaky fine crystals of basic magnesium carbonate, and the functional particles are those in which one or more substances are included in the hollow carrier. .
[0020]
In addition, there are two methods for producing the hollow carrier. The first is to mix a water-soluble magnesium salt and a water-soluble carbonate, at a temperature of 25 to 55 ° C., a diameter of 0.5 to 10 μm, and a length of 0.5 to 10 μm. A first step of generating columnar particles of magnesium orthocarbonate having a particle size of 5 to 500 μm, and a temperature higher than a temperature at which the suspension of the columnar particles of magnesium carbonate is generated in the first step, And a second step of performing a heat treatment at a temperature of 40 to 70 ° C. and a pH of 9.5 to 11.5 in the form of tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate. Is what you do.
[0021]
Second, a first step of preparing a magnesium bicarbonate solution by introducing a carbon dioxide-containing gas into the magnesium hydroxide suspension, and adjusting the magnesium bicarbonate solution to a pH of 7.5 to 11.0 to correct the magnesium bicarbonate solution. A second step of forming columnar particles of magnesium carbonate, and maintaining the temperature range after adjusting the suspension of the columnar particles of magnesium carbonate to pH 9.0 to 12.0 and a temperature of 30 to 75 ° C. And a third step of producing a basic magnesium carbonate thereby producing a tubular agglomerated particle of flaky fine crystals of the basic magnesium carbonate. Further, the method for producing functional particles is characterized in that one or more substances are brought into contact with the hollow carrier so that the substance is included in the hollow carrier.
[0022]
The present invention, in particular, the hollow carrier is made of tubular aggregated particles of flaky microcrystals, and it comprises an aromatic substance, a nutrient, a food additive, a medicament, an agricultural chemical or a fertilizer. It can be included inside the structure. In addition, the unique shape of a tube and the inclusion of an effective substance in the interior, including a long-term stable and sustained release effect, as well as a controlled release that releases inclusions under a specific environment, prevention and protection of alteration of inclusions Excellent characteristics such as a masking effect can be obtained. Furthermore, by controlling the length, the inner diameter, and the thickness of the tube, it also has the characteristic that the release speed and the like can be controlled.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail. However, it is needless to say that the present invention is not limited thereto, and is specified by the description of the claims. The present invention provides a novel shaped hollow carrier comprising tubular aggregated particles of basic magnesium carbonate, functional particles containing an effective substance in the hollow carrier, and methods for producing the same.
[0024]
More specifically, a hollow carrier of a novel shape, which is a tubular aggregated particle composed of flaky fine crystals of basic magnesium carbonate, and encapsulating various active substances in the hollow carrier, a sustained release effect, release controllability, It is an object of the present invention to provide a functional particle having excellent properties such as prevention of deterioration, protection, and masking effect of an inclusion substance, and a method for producing the same. The basic magnesium carbonate referred to herein has the chemical formula mMgCO _Three ・ Mg (OH) _Two ・ NH _Two It is represented by O, and the values of m and n are not particularly limited, but usually, the value of m is in the range of 3 to 5, and the value of n is in the range of 3 to 8.
[0025]
The tubular agglomerated particles of basic magnesium carbonate which the present inventors have already filed are flake-like fine crystals having a thickness of 0.005 to 0.5 μm and a diameter of 0.1 to 10 μm which are assembled in a card house structure. Which is suitable as the basic magnesium carbonate used as the hollow carrier of the present invention.
[0026]
The tubular agglomerated particles of the basic magnesium carbonate are not agglomerated such that the flaky fine crystals are easily dispersed due to mechanical stirring or environmental changes such as temperature and pH. Although it is not clear, the flaky fine crystals of basic magnesium carbonate are aggregated and physically fixed. The tubular aggregated particles of basic magnesium carbonate used as a hollow carrier in the present invention have an outer diameter of 1 to 20 μm, a length of 5 to 200 μm, a length / outer diameter ratio of 2 to 50, and an inner diameter of 2 to 50. It is desirable that the ratio is 0.5 to 5 μm and the ratio of the inner diameter to the outer diameter is 0.1 to 0.95. By adopting this shape, it is possible to exhibit more excellent properties as a hollow carrier.
[0027]
And the specific surface area by the BET method is 70 to 200 m ^Two / G, or a pore distribution measured by a mercury intrusion method, a pore volume (A) having a pore diameter of 0.01 to 100 μm is 5000 to 12000 mm. ^Three / G, and B / A, which is the ratio to the pore volume (B) having a pore size of 0.5 to 5 μm, is preferably 0.45 to 0.85. It is more preferable that both the specific surface area and the pore distribution are within the above ranges, whereby the effect as a hollow carrier of the functional particles derived from the tubular shape is more effectively exhibited. .
[0028]
The functional particle of the present invention is a hollow carrier having the above-mentioned characteristics, which is composed of basic magnesium carbonate, and further, inside the tubular structure of the hollow carrier, an aroma substance, a nutrient, a food additive, a medicine, a pesticide. And functional particles containing an effective substance such as fertilizer. The functional particles have a sustained release property in which the inclusions are gradually released when the active ingredient is encapsulated in the tubular structure of the hollow carrier, a controlled release property in which the inclusions are released under specific conditions, and an inclusion. It exhibits excellent characteristics such as prevention of deterioration, protection and masking effect.
[0029]
For example, if a sustained release property is utilized, a material that normally releases an active ingredient for a long period of time can be obtained by enclosing a substance that easily volatilizes or sublimates. As for the use of release controllability, a material capable of releasing inclusions under conditions such as acidic conditions and pressurizing conditions under which basic magnesium carbonate is decomposed or a tubular structure collapses can be used. Furthermore, by incorporating a substance or the like which is usually decomposed easily by contact with air or the like, it is possible to obtain a material in which contact with the external environment is suppressed and decomposition of the active ingredient is suppressed.
[0030]
In addition, by masking the surface with an organic polymer, a fatty acid or a fatty acid salt as required, the masking effect and the sustained release effect of the contained substance can be further enhanced.
Furthermore, in addition to the action of the encapsulated active ingredient, the properties of the tubular agglomerated particles of basic magnesium carbonate used as a hollow carrier itself, such as the ability to neutralize acidic substances and the high adsorption performance derived from porosity, are used in combination. By doing so, it can be used as a multifunctional material.
[0031]
Next, a method for producing the hollow carrier of the present invention and functional particles containing an active substance in the hollow carrier will be described. The method for producing the hollow carrier is characterized by producing the basic magnesium carbonate having the tubular structure of the flaky fine crystals described above. In addition, the method for producing functional particles of the present invention is characterized in that the hollow carrier is contacted with one or more active substances, whereby the substance is included in the tubular structure of the hollow carrier. . That is, the method for producing functional particles in the present invention includes a step of preparing a hollow carrier having a novel shape of a tubular structure, and two steps of including a specific substance in the hollow carrier.
[0032]
The method for producing the hollow carrier of the present invention comprising the tubular aggregated particles of the flaky fine crystals of basic magnesium carbonate is not particularly limited, as long as the basic magnesium carbonate having the tubular structure described above can be produced. As described above, the hollow carrier can be preferably produced by, for example, the methods proposed by the present inventors in Japanese Patent Application Nos. 2002-179462 and 2002-220768. The method described in both applications was used.
[0033]
The former production method of Japanese Patent Application No. 2002-179462 refers to a method in which a water-soluble magnesium salt and a water-soluble carbonate are mixed in an aqueous solution, the diameter is 0.5 to 10 μm, and the length is 25 to 55 ° C. A first step of forming columnar particles of magnesium orthocarbonate having a diameter of 5 to 500 μm, and a temperature higher than the temperature at which the suspension of the columnar particles of magnesium carbonate was generated in the first step, and The second step of heat treatment at a temperature of 35 to 80 ° C. and a pH of 9.5 to 11.5 can produce basic magnesium carbonate of tubular aggregated particles composed of flaky fine crystals.
[0034]
As the water-soluble magnesium salt used in the first step, various water-soluble magnesium salts can be used without any particular limitation, and examples thereof include magnesium chloride, magnesium sulfate, magnesium nitrate and magnesium acetate. The water-soluble carbonate can also be used without any particular limitation, and examples thereof include sodium carbonate, potassium carbonate, and ammonium carbonate. Use of strong alkali carbonates, specifically, sodium carbonate and potassium carbonate However, it is preferable because the tubular aggregated particles of basic magnesium carbonate can be prepared more efficiently.
[0035]
In the first step, the water-soluble magnesium salt and the water-soluble carbonate as described above are reacted in an aqueous solution to precipitate columnar particles of magnesium orthocarbonate. Water-soluble magnesium salt and water-soluble carbonate are mixed in a solution, such as a method of adding an aqueous solution of magnesium chloride to an aqueous solution of magnesium carbonate and a method of adding ammonium carbonate to an aqueous solution of magnesium sulfate, so that magnesium ions and carbonate ions react. Should be fine. In the reaction at that time, it is preferable to stir the reaction solution in order to ensure the uniformity of the reaction.
[0036]
Regarding the shape of the orthomagnesium carbonate generated in the first step, it is preferable that the shape is columnar, the diameter is 0.5 to 10 μm, and the length is 5 to 500 μm. The reason is that it is presumed that the generation of basic magnesium carbonate from the surface of the columnar particles of magnesium orthocarbonate forms a unique tubular shape. In other words, it can be said that the shape of the intermediate magnesium orthocarbonate greatly affects the shape of the basic magnesium carbonate as the final product.
[0037]
Therefore, it is important to adjust the synthesis conditions of orthomagnesium carbonate according to the desired shape of the basic magnesium carbonate, particularly the diameter and length, to obtain an orthomorphic magnesium carbonate having an appropriate shape. Furthermore, in the case of orthomagnesium carbonate having a shape other than the above, when the basic magnesium carbonate is generated in the second step, the time required for the generation is extremely long, and the production efficiency is reduced. May not be obtained.
[0038]
In such a case, in order to generate columnar particles of magnesium orthocarbonate having a desired shape and capable of efficiently obtaining tubular aggregated particles of basic magnesium carbonate in the second step, it is necessary to use an aqueous solution in an aqueous solution. The temperature at which the soluble magnesium salt is reacted with the water-soluble carbonate is preferably in the range of 25 to 55C, more preferably 28 to 50C.
[0039]
If the temperature at that time is lower than 25 ° C., the production rate of the intermediate magnesium orthocarbonate becomes extremely slow, and the production efficiency is lowered, which is not practical. On the other hand, when the temperature exceeds 55 ° C., a magnesium orthocarbonate having a desired shape cannot be obtained, or in the subsequent second step, tubular aggregated particles of basic magnesium carbonate cannot be obtained. The magnesium orthocarbonate generated in the first step is represented by the chemical formula MgCO _Three ・ NH _Two It is a hydrate of magnesium carbonate represented by O and generally has n = 3, but other than n = 3 is not limited as long as it has the shape described above.
[0040]
When the shape of the magnesium magnesium carbonate generated in the first step is adjusted to control the shape of the tubular aggregated particles of the basic magnesium carbonate generated in the second step, the reaction conditions of the first step are appropriately controlled. By doing so, the shape of the magnesium orthocarbonate can be adjusted within the above range. For example, with respect to the diameter of the columnar particles of magnesium carbonate, it is possible to make the columnar particles smaller in diameter when the temperature at the time of forming the magnesium carbonate is relatively high. Regarding the pH, the higher the pH at the start of the production of magnesium carbonate in the first step, the more the columnar particles of magnesium carbonate having a smaller diameter can be produced.
[0041]
The suspension of columnar particles of orthomagnesium carbonate having a diameter in the range of 0.5 to 10 μm and a length of 5 to 500 μm obtained in the first step may be subjected to the second step as it is. However, when it is desired to recover the anionic component of the soluble magnesium salt and the cation component of the soluble carbonate dissolved in the suspension as impurities, or when these impurities are contained in the basic product basic magnesium carbonate. When it is not preferable that the residue remain, the liquid may be replaced with water or the like to remove impurities.
[0042]
Subsequently, in a second step, the suspension of columnar particles of magnesium orthocarbonate obtained in the first step is desirably at a temperature of 40 to 70 ° C, more preferably 45 to 65 ° C, and at a temperature higher than that of the first step. To produce basic magnesium carbonate. It is important that the heat treatment temperature in the second step is higher than the temperature at which the normal magnesium carbonate is generated in the first step, and the temperature difference between the first step and the second step is desirably 2 to 2. The temperature is preferably 35 ° C., more preferably 2 to 25 ° C., and still more preferably 2 to 20 ° C.
[0043]
The temperature difference has a more appropriate range depending on the temperature at which the columnar particles of magnesium orthocarbonate are generated in the first step and the pH at which the magnesium carbonate is heat-treated in the second step. When the pH of the second step is set to 10.5, the temperature difference is 20 to 35 ° C when the first step is 25 to 35 ° C, and the temperature difference is 5 to 35 ° C when the first step is 35 to 45 ° C. When the temperature of the first step is 25 ° C. and the temperature of the first step is 45 to 55 ° C., the temperature difference is preferably 2 to 15 ° C.
[0044]
If the temperature is lower than the first step or lower than 40 ° C., the desired tubular aggregated particles of basic magnesium carbonate cannot be obtained, or the reaction time becomes extremely long, and the production efficiency is lowered, which is not practical. . At a temperature exceeding 70 ° C., the uniformity of the generated basic magnesium carbonate particles deteriorates, and the mixing of irregular to spherical aggregated particles becomes remarkable.
[0045]
Also in the second step, it is preferable to stir the reaction solution in order to ensure the uniformity of the reaction, as in the case of the first step. Further, the pH of the orthomagnesium carbonate suspension during the heat treatment is desirably 9.5 to 11.5, and more desirably 10.0 to 11.5. If the pH is less than 9.5, the rate of production of basic magnesium carbonate from magnesium orthocarbonate will be slowed down, not only the production efficiency will decrease, but also magnesium orthocarbonate may remain in the final product. From. If the pH exceeds 11.5, the uniformity of the particles of the final product is impaired, and irregular or spherical particles tend to be mixed.
[0046]
In order to adjust the pH to this range, the amount ratio of the water-soluble magnesium salt to the water-soluble carbonate in the first step may be adjusted, or an acidic substance or an alkaline substance may be added and adjusted in the second step. . In the former case, it can be adjusted to an acidic side by increasing the amount of the water-soluble magnesium salt, and conversely to an alkaline side by increasing the amount of the water-soluble carbonate. In the latter case, hydrochloric acid, sulfuric acid, nitric acid and the like can be used as acidic substances to be added, and sodium hydroxide, potassium hydroxide, aqueous ammonia and the like can be used as alkaline substances.
[0047]
In the second step, it is preferable to continue heating and stirring until the generation of the basic magnesium carbonate is completed. The end of the generation of the basic magnesium carbonate can be determined by measuring the pH, the conductivity, and the like of the suspension. For example, regarding the pH, while the production of the basic magnesium carbonate is continued, the pH of the suspension gradually decreases, while the pH is kept almost constant when the production is completed.
[0048]
Then, in the latter production method of Japanese Patent Application No. 2002-220768, a first step of preparing a magnesium hydrogencarbonate solution by introducing a carbon dioxide-containing gas into a magnesium hydroxide suspension, and the step of preparing the magnesium hydrogencarbonate solution at pH 7.0. A second step of adjusting the temperature to 5 to 11.0 to form columnar particles of magnesium orthocarbonate, and adjusting the suspension of the columnar particles of magnesium carbonate to pH 9.0 to 12.0 and a temperature of 30 to 75 ° C. A third step of generating basic magnesium carbonate by maintaining the above temperature range after the adjustment.
[0049]
The first step is a step of preparing a magnesium hydrogen carbonate solution by introducing a carbon dioxide-containing gas into a suspension of magnesium hydroxide, and the raw material magnesium hydroxide used here is not particularly limited. Instead, magnesium hydroxide produced by the so-called seawater method, in which calcium hydroxide is added to seawater to precipitate magnesium hydroxide, can be used, and various other materials can be used. There is no particular limitation on the carbon dioxide-containing gas, and carbon dioxide supplied from a cylinder or the like, one obtained by diluting it with air or the like, and one containing carbon dioxide such as combustion exhaust gas can be used.
[0050]
In the first step, 90% or more, desirably, the entire amount of magnesium hydroxide used as a raw material is changed to magnesium bicarbonate. The reason is that when the amount of magnesium hydroxide that has not changed to magnesium bicarbonate is large, a uniform reaction is inhibited in the subsequent second and third steps, and a tubular product of basic magnesium carbonate as a final product is formed. This is because the uniformity of the particle shape of the aggregated particles may deteriorate.
[0051]
The change from magnesium hydroxide to magnesium hydrogen carbonate can be confirmed by measuring the pH, conductivity, and the like of the liquid. For example, regarding the pH of the solution, the pH of the magnesium hydroxide suspension before the introduction of the carbon dioxide-containing gas is about 9 to 11, whereas the entire amount of magnesium hydroxide is changed to magnesium hydrogen carbonate. In this case, the pH of the solution becomes almost neutral. In the first step, it is desirable to introduce the carbon dioxide-containing gas until the pH of the liquid becomes 8 or less, and more desirably until the pH becomes 7.5 or less.
[0052]
There is no particular restriction on the liquid temperature when introducing the carbon dioxide-containing gas into the magnesium hydroxide suspension, but if the liquid temperature is too high, the solubility of magnesium hydrogen carbonate decreases, and as a result, the liquid is prepared. Not only the amount of unreacted magnesium hydroxide remaining in the magnesium hydrogen carbonate solution becomes large, but also a phenomenon in which magnesium hydrogen carbonate is decomposed before the completion of the reaction in the first step is observed. Therefore, when introducing the carbon dioxide-containing gas into the magnesium hydroxide suspension, the liquid temperature is desirably maintained at 35 ° C or lower, and more desirably at 30 ° C or lower.
[0053]
In addition, after introducing the carbon dioxide-containing gas into the suspension of magnesium hydroxide, it is more preferable to remove unreacted residues such as unreacted magnesium hydroxide and other impurities, and by doing so, , A basic magnesium carbonate having high purity and high particle uniformity can be obtained in the third step.
[0054]
In the subsequent second step, the magnesium bicarbonate solution prepared in the first step is adjusted to pH 7.5 to 11.0 to generate columnar particles of normal magnesium carbonate. In the second step as well, it is preferable to stir the reaction solution in order to ensure the uniformity of the reaction as in the first step. In the second step, it is necessary to adjust the pH shifted to the neutral region in the first step to the alkali side, and therefore, an appropriate amount of an alkaline substance is added to the magnesium hydrogen carbonate solution prepared in the first step. Adjust the pH by addition. After the adjustment, the pH needs to be in the range of 7.5 to 11.0.
[0055]
The reason why the pH needs to be adjusted in the second step as described above is that if the pH is less than 7.5, tubular aggregated particles of basic magnesium carbonate cannot be obtained in the subsequent third step. is there. Conversely, if the pH exceeds 11.0, the magnesium orthocarbonate becomes unstable, and basic magnesium carbonate is formed before the formation of the normal magnesium carbonate is completed. Magnesium carbonate is generated, which not only deteriorates the uniformity of the basic magnesium carbonate particles of the final product, but also increases the required amount of alkaline substance used for pH adjustment, which is economically favorable. Absent.
[0056]
In order to form columnar particles of magnesium orthocarbonate in the second step, the magnesium bicarbonate solution prepared in the first step is adjusted to pH 7.5 to 11.0, and the reaction is continued until the production of magnesium orthocarbonate is completed. It is preferable to continue. The end of the production of magnesium orthocarbonate can be confirmed by measuring the pH or conductivity of the solution and observing that the value has stabilized.
[0057]
The temperature at that time is desirably 20 to 55 ° C, and more desirably 30 to 55 ° C. When the temperature is lower than 20 ° C., in the subsequent third step, in addition to the tubular agglomerated particles of basic magnesium carbonate, amorphous agglomerated particles are likely to be mixed. Conversely, even when the temperature exceeds 55 ° C., the uniformity of particles tends to deteriorate in the third step.
[0058]
In the second step, the pH is adjusted as described above, preferably the temperature is also adjusted as described above, and the reaction is continued until the formation of magnesium carbonate is completed, thereby forming columnar particles of magnesium carbonate. However, the shape of the columnar particles is preferably 0.5 to 10 μm in diameter and 5 to 500 μm in length. In particular, when the diameter of the columnar particles is less than 0.5 μm or more than 10 μm, in the subsequent third step, the tubular aggregated particles of the basic magnesium carbonate intended in the present invention may not be obtained.
[0059]
In addition, the shape, particularly the diameter and length, of the tubular aggregated particles of basic magnesium carbonate produced in the third step are affected by the diameter and length of the columnar particles of normal magnesium carbonate produced in the second step. It is desirable to adjust the diameter and length of the normal magnesium carbonate produced in the second step according to the shape of the tubular aggregated particles of basic magnesium carbonate, which is the purpose of production. In order to adjust the diameter and length of the columnar particles of magnesium orthocarbonate, in the second step, the pH and the temperature at the time of generating magnesium orthocarbonate may be appropriately controlled.
[0060]
For example, with respect to the pH in the second step, a columnar particle of orthomagnesium carbonate having a small diameter can be obtained by setting the pH to a higher value within the above-described range. Large columnar particles of magnesium orthocarbonate can be obtained. Furthermore, as for the temperature in the second step, within the above-mentioned range, by setting the temperature higher, columnar particles of orthomagnesium carbonate having a small diameter can be obtained. Conversely, by setting the temperature lower, the temperature can be reduced. Large columnar particles of magnesium orthocarbonate can be obtained.
[0061]
Further, the formed columnar particles of magnesium orthocarbonate may be once filtered and washed, whereby the alkaline substance added in the second step can be removed, and the impurities contained in the product can be removed. This is preferable in that the amount can be further reduced. Thus, in the second step, columnar particles of normal magnesium carbonate are generated from the magnesium hydrogen carbonate solution.
[0062]
In the third step which is the last step following the second step, the suspension of columnar particles of magnesium orthocarbonate obtained in the second step is subjected to pH 9.0 to 12.0 at a temperature of 30 to 75 ° C. To produce basic magnesium carbonate. Also in the third step, it is preferable to stir the reaction solution in order to ensure the uniformity of the reaction, as in the case of the first step and the second step.
[0063]
It is necessary and important that the temperature at which the basic magnesium carbonate is formed in the third step be 30 to 75 ° C. If the temperature is lower than 30 ° C., the desired tubular basic magnesium carbonate cannot be obtained, or the reaction time becomes extremely long, and the production efficiency is lowered, which is not practical. At a temperature exceeding 75 ° C., the uniformity of the formed basic magnesium carbonate particles is deteriorated, and the mixing of irregular to spherical aggregated particles becomes remarkable.
[0064]
The pH in this step needs to be 9.0 to 12.0. The reason is that when the pH is less than 9.0, not only does the rate of production of basic magnesium carbonate from magnesium carbonate become slow, the production efficiency decreases, but also the magnesium magnesium carbonate remains in the final product. Because there is. Conversely, if the pH exceeds 12.0, the uniformity of the particles of the final product is impaired, and irregular or spherical particles tend to be mixed.
[0065]
Further, the pH in the third step is desirably higher than the pH at the time of forming columnar particles of orthomagnesium carbonate in the second step, and more desirably 0.3 or more. By doing so, it becomes possible to more efficiently produce tubular agglomerated particles of basic magnesium carbonate having high uniformity and excellent various powder properties. In order to adjust the pH to this range, an acidic substance or an alkaline substance may be added and adjusted in the third step.
[0066]
The temperature and pH in the third step are desirably adjusted according to the shape, particularly the diameter and length, of the orthomagnesium carbonate generated in the second step. Tubular aggregated particles of magnesium carbonate can be obtained. Specifically, when the diameter of the orthomagnesium carbonate is small, the pH and the temperature in the third step are preferably lower, and conversely, when the diameter of the magnesium carbonate is large, the pH and the temperature in the third step are higher. Is preferred.
[0067]
In the third step, it is preferable to continue stirring while maintaining the temperature in the above-mentioned range until the generation of the basic magnesium carbonate is completed. In this case, it is not necessary to continuously maintain the temperature immediately after the temperature is adjusted to 30 to 75 ° C., and the temperature may fluctuate in the temperature range, but it is preferable that the fluctuation is as small as possible. is there. The completion of the generation of the basic magnesium carbonate can be confirmed by measuring the pH, conductivity, and the like of the suspension. For example, regarding the pH, while the production of the basic magnesium carbonate is continued, the pH of the suspension is decreased, but the pH is kept almost constant after the production is completed.
[0068]
Basic magnesium carbonate used as a hollow carrier in the present invention is prepared by the method as described above, but originally, basic magnesium carbonate exhibits an alkalinity of pH 10 to 11 in the presence of water, and also has an acid Are relatively weak substances. Depending on the application, it may be necessary to be neutral at around pH 7, or acid resistance may be required. In this case, by coating the surface of the tubular aggregated particles of basic magnesium carbonate with a metal oxide such as silica or alumina, it is possible to lower the pH or impart acid resistance.
[0069]
In particular, when a neutral region is required for the hollow carrier, it is desirable that the basic magnesium carbonate surface-coated with a metal oxide has a pH value of 9.5 or less according to JIS K5101. As the metal oxide to be coated on the surface, silica, alumina, titania, zirconia, iron oxide, zinc oxide, and the like can be used. Among them, silica or alumina is most preferable because it can lower the pH value more efficiently. is there. Here, the metal oxide may be a hydrated oxide such as a hydroxide or a hydrate in addition to the anhydrous oxide.
[0070]
The method of coating the tubular agglomerated particles of basic magnesium carbonate with a metal oxide comprises, in the suspension of the basic magnesium carbonate, one or more substances necessary for precipitating a desired metal oxide. The method of addition is simple, and coating with a metal oxide can be efficiently performed, which is preferable. For example, when the surface is coated with silica, a sodium silicate solution is added dropwise to an aqueous suspension of the tubular aggregated particles of basic magnesium carbonate under appropriate pH conditions to hydrolyze the sodium silicate and form a tube. What is necessary is just to deposit silica on the surface of the aggregated particles. In the case of alumina, if sodium aluminate or the like is used instead of sodium silicate, the surface can be coated with alumina.
[0071]
In this way, the pH value can be lowered by coating the surface of the tubular aggregated particles of basic magnesium carbonate with the metal oxide, and even a substance which is weak in alkalinity can be included in the tubular structure. Furthermore, if it is an acid-resistant metal oxide, it becomes possible to include an acidic substance.
[0072]
In addition, in the case of encapsulating an oily substance in the hollow carrier comprising the tubular aggregated particles of the basic magnesium carbonate of the present invention, the tubular aggregated particles are surface-treated with a fatty acid or a fatty acid salt to be lipophilic, whereby the encapsulation efficiency is excellent. It can be a hollow carrier. Examples of the fatty acid used include caproic acid, caprylic acid, capric acid, lauric acid, myristic acid, palmitic acid, stearic acid, behenic acid, oleic acid, linoleic acid, and linolenic acid. Salts, potassium salts and the like can be used.
[0073]
In order to treat the surface of the tubular aggregated particles of basic magnesium carbonate with these fatty acids or fatty acid salts, an appropriate amount of a fatty acid or a fatty acid salt is added to a suspension of the tubular aggregated particles, stirred, and dried. When adding a fatty acid or a fatty acid salt and stirring, the temperature of the suspension of the tubular aggregated particles of basic magnesium carbonate is set to a temperature equal to or higher than the melting point of the fatty acid to be used, or higher than a temperature at which a predetermined amount of the fatty acid salt to be used is dissolved. It is desirable to keep.
[0074]
In the case of adding a fatty acid or a fatty acid salt, in the case of a fatty acid, it was heated to a temperature higher than the melting point of the fatty acid to make it liquid, and in the case of a fatty acid salt, it was heated to a temperature at which a predetermined amount of the fatty acid salt was dissolved. It may be in the form of a solution. For example, when capric acid is used as the fatty acid, the temperature is preferably 30 ° C. or higher, when lauric acid is 45 ° C. or higher, and when stearic acid is 70 ° C. or higher.
[0075]
When a solution of a fatty acid salt is used and its concentration is 10% by weight, for example, the temperature is preferably 35 ° C. or more for sodium laurate, 50 ° C. or more for sodium myristate, and 75 ° C. or more for sodium stearate. By doing so, the surface treatment of the tubular aggregated particles of basic magnesium carbonate can be performed more efficiently.
[0076]
There is no particular restriction on the drying after the surface treatment, but if it is dried using a fluidized-bed drier, a spray drier (spray drier), a vacuum freeze drier or the like, the powder can be obtained as it is. . Whether or not lipophilicity has been achieved by the surface treatment can be confirmed by repelling water and not dispersing in water when the surface-treated tubular aggregated particles are charged into water.
[0077]
By performing a surface treatment with a fatty acid or a fatty acid salt in this manner, the surface of the hollow carrier can be made lipophilic, and a hollow carrier excellent in encapsulation efficiency when encapsulating an oily substance is obtained. In addition to fatty acids or fatty acid salts, the surface of the hollow carrier may be made lipophilic with resin acids, titanate-based coupling agents, silane-based coupling agents, aluminate-based coupling agents, and various other surface treatment agents. You can also.
[0078]
The thus-prepared basic magnesium carbonate having a tubular structure can contain various substances therein. At that time, the basic magnesium carbonate having a tubular structure can be used as a suspension or a dried powder after drying. When used in the form of a suspension, the suspension after the reaction may be used as it is, but in addition to the anion component of the water-soluble magnesium salt and the cation component of the water-soluble carbonate, In some cases, impurities derived from acidic or alkaline substances added for pH adjustment are contained, and depending on the application, the impurities may have an adverse effect. What is necessary is just to replace and remove with a solvent.
[0079]
On the other hand, when used in the form of a dry powder, a dry powder may be obtained through a dehydration step or a drying step.However, depending on a drying method, dry aggregation may occur and crushing may be required in a later step. However, there is a possibility that the particle shape is destroyed in the crushing step. Therefore, as a more desirable technique for obtaining a dry powder, the solvent of the basic magnesium carbonate suspension after generation is replaced with an organic solvent such as alcohol, or a washing step with an organic solvent such as alcohol is provided after dehydration. And then drying.
[0080]
By replacing or washing the solvent with an organic solvent such as alcohol, a dry powder in which aggregation due to drying is suppressed can be obtained. In addition, as the organic solvent used here, a solvent having low solubility of basic magnesium carbonate is preferable, and for example, methyl alcohol, ethyl alcohol, propanol, acetone and the like can be used. In addition, a drying method that does not easily cause dry agglomeration may be adopted without replacing or washing the solvent with the organic solvent as described above. For example, a spray drier (spray drier), a fluidized bed drier, a vacuum freezer If a dryer or the like is used, a dry powder in which dry aggregation is suppressed can be obtained.
[0081]
Subsequently, a desired substance, for example, an effective substance such as a fragrance substance, a nutrient, a food additive, a medicine, a pesticide, or a fertilizer is included in the thus-prepared basic magnesium carbonate having a tubular structure. At this time, it is preferable to use the dry powder as described above, but it is also possible to use the basic magnesium carbonate having a tubular structure as a slurry. The method for encapsulation is not particularly limited, but the following methods are widely applicable and relatively simple, which is more preferable.
[0082]
First, one or more desired substances are dissolved or suspended in a solvent. In the case of a suspension, the particles in the solution must be smaller than the inner diameter of the hollow carrier to be charged next, so it is particularly necessary to sufficiently disperse the solid particles using an ultrasonic disperser or the like. . A higher concentration is preferable because the amount of substance that can be introduced into the tube increases, but if the viscosity is too high, the air and the solution or suspension inside the tubular structure cannot be replaced, and sometimes the viscosity is high. Therefore, there is a risk of breaking the tubular structure.
[0083]
This solution or suspension and the dry powder of the above-mentioned hollow carrier may be mixed, stirred and impregnated so that the whole becomes uniform, and dried. If the penetration of the solution or suspension into the interior of the tubular structure is insufficient, the air inside the tubular structure is degassed by reducing the pressure using a vacuum pump or an aspirator, etc. Infiltration can be promoted. Drying may be performed by evaporating the solvent by heating or the like.
[0084]
At this time, it is necessary to sufficiently consider the properties of the substance contained in the heating temperature. If drying at a low temperature is required, the drying time is reduced by performing the drying under reduced pressure. Thus, functional particles in which a desired substance is included in the hollow carrier can be obtained. Further, the hollow carrier can be used for forming functional particles without forming a dry powder from the slurry once, which will be described in detail later.
[0085]
The basic magnesium carbonate itself constituting the hollow carrier undergoes dehydration of crystallization water, decomposition of a hydroxyl group, and decomposition of a carbonic acid group in order by heating. For example, the chemical formula of basic magnesium carbonate mMgCO _Three ・ Mg (OH) _Two ・ NH _Two When the value of n in O (the number of crystallization waters) is 8, 3 to 4 crystallization waters are dehydrated at 50 to 100 ° C., and the value of n becomes 4 to 5; The value of lost n is 0.
[0086]
When the temperature exceeds 250 ° C., hydroxyl groups are decomposed at 300 to 450 ° C., and carbonic acid groups are decomposed at 450 to 550 ° C. to release carbon dioxide. However, the damage to the tubular structure from these changes is not significant. Therefore, depending on the substance to be included and the purpose of use, it is possible to positively modify the basic magnesium carbonate into an anhydride or an oxide by heating.
[0087]
As the substance to be encapsulated inside the tubular agglomerated particles of the basic magnesium carbonate which is the hollow carrier of the present invention, as described above, medicines, cosmetics, food-related drugs, flavors, agricultural chemicals, fertilizers and the like can be mentioned. Various components to be included and applications of the functional particles including the components will be described below.
[0088]
Various components can be included in pharmaceuticals, and the various pharmaceutical components are encapsulated in a hollow carrier composed of tubular aggregated particles of basic magnesium carbonate, thereby providing sustained release, controlled release, protection, and masking. It can be a medicine having functional properties such as sex. Then, the functional particles containing various pharmaceutical ingredients in the hollow carrier of the present invention, oral drugs, aerosols, ointments, suppositories, cataplasms, etc., the above-mentioned sustained release, release controllability, It can be a pharmaceutical preparation having functions such as protective properties and masking properties.
[0089]
As an oral drug, it can be applied to solid preparations such as tablets, capsules, powders, granules and pills, as well as liquid preparations such as syrups, suspensions and emulsions. In the case of a solid preparation, the powder containing the functional particles of the present invention can be granulated to obtain tablets, granules, pills or the like, or can be used as a powder in a powder state. In the case of a liquid preparation, the functional particles of the present invention may be dispersed in a liquid.
[0090]
In the aerosol medicine, a powdery inhalant in which a hollow carrier containing a pharmaceutical ingredient is used in a powder state may be used, or a mist or paste inhalant may be dispersed in a liquid. In the case of an ointment or suppository, the tubular aggregated particles of basic magnesium carbonate containing a pharmaceutical component may be kneaded with a base such as oils and fats and an emulsion to form a paste or cream. In the case of a poultice, a hollow carrier containing a pharmaceutical ingredient can be kneaded with a resin or the like, formed into a sheet, and used in a compress or the like.
[0091]
Although the specific use of the functional particles containing the pharmaceutical ingredient varies depending on the kind of the pharmaceutical ingredient to be included, various kinds of the following can be applied as the pharmaceutical ingredient to be included. For example, nervous system drugs include agents for the central nervous system such as antiepileptics, antipyretics, analgesics, and general cold agents, and agents for the peripheral nervous system such as autonomic nervous agents and anticonvulsants. Drugs acting on the body defense mechanism include immunosuppressants, immunostimulants, anti-inflammatory agents, antiallergic agents, antirheumatic agents, interferon-like agents, and the like.
[0092]
Examples of drugs for circulatory organs include arrhythmic agents, vasodilators, vasoconstrictors, antihypertensive agents, antihypertensive agents, antiatherosclerotic agents, hyperlipidemic agents, diuretics, and the like. Respiratory medicines include bronchodilators, antitussives, expectorants, antitussives, and gargles. Examples of the gastrointestinal medicine include antidigestive ulcers, antacids, stomach digestives, antiobesity agents, antiemetics, emetics, antiphlogistics, laxatives, intestinals, compound gastrointestinals and the like. Examples of the medicine for the outer skin include a germicidal disinfectant for the outer skin, a wound protectant, an agent for purulent diseases, an analgesic / pruritic / astringent / anti-inflammatory agent, and a bath agent.
[0093]
Metabolic drugs include vitamin A-like agents, vitamin D-like agents, vitamin B1-like agents, vitamin B2-like agents, vitamin C-like agents, vitamin P-like agents, vitamin E-like agents, vitamin K-like agents, and mixed vitamin-like agents. In addition to vitamin-like agents such as preparations, calcium preparations, mineral preparations, saccharide preparations, organic acid preparations, protein amino acid preparations and other nutritional tonics, liver disease preparations, antidote, addictive poisoning preparations, gout treatments, There are enzyme preparations, diabetes preparations, general metabolic preparations, uric acid metabolism preparations, lipid metabolism preparations, carbohydrate metabolism preparations and the like.
[0094]
The hollow carrier of the present invention, by including the above-mentioned pharmaceutical component, is not only capable of gradually releasing the encapsulated pharmaceutical component and maintaining its efficacy for a long period of time, but also effective in reducing side effects. In addition, even if a component is easily decomposed or deteriorated by contact with air, light, heat, or the like, decomposition or deterioration of the component can be suppressed by being included in the tubular agglomerated particles of basic magnesium carbonate. .
[0095]
However, if the drug component is weak in alkalinity, it may be decomposed or deteriorated due to the alkalinity of basic magnesium carbonate. Therefore, it is desirable that the encapsulated pharmaceutical component is an alkali-resistant component. However, this is not limited to the case where a basic aggregate of tubular particles of magnesium carbonate whose pH has been lowered by surface treatment is used. Further, the encapsulated drug component may be protected in advance with alkali resistance like microcapsules or nanocapsules, or may be in a stable emulsified state.
[0096]
Furthermore, even for a pharmaceutical component having an unpleasant taste such as bitterness at the time of oral administration, since the component is included in the tubular aggregated particles of basic magnesium carbonate, the unpleasant taste at the oral time can be reduced. Explaining by giving specific examples, if stimulating the internal mucous membranes such as digestive organs such as general cold remedies and antibiotics, or if enclosing a drug with strong side effects, these drug components will be released from the end of the tubular structure of the hollow carrier. By being gradually released, irritation and side effects can be reduced, and the drug effect can be maintained for a long period of time.
[0097]
In addition, by including useful bacteria and the like that are weak to acids such as bifidobacteria, these components or fungi can be protected from stomach acid, and more of these components or fungi can be effectively treated in the affected area for therapeutic purposes. It is possible to operate. Furthermore, if a digestive agent, a digestive enzyme agent, etc. are included, a formulation having a controlled release property, in which these components are released after the basic magnesium carbonate as a hollow carrier is decomposed by stomach acid, can be obtained.
[0098]
In addition, since basic magnesium carbonate itself has a drug effect as a therapeutic agent for gastric ulcer / duodenal ulcer, gastritis and upper digestive tract abnormalities in addition to antacids and laxatives, the effects of these basic magnesium carbonates It can also be a pharmaceutical preparation having the effect of other pharmaceutical ingredients contained therein. In addition to the above-mentioned oral drugs, for example, a hollow carrier containing a bronchodilator can be used as a powder inhalant, and if it contains a dermatological drug such as an anti-inflammatory analgesic, it can be used as an ointment or poultice. It is excellent in persistence of the drug effect and can reduce side effects such as rash.
[0099]
As for cosmetics, various moisturizers, plant extracts, cosmetic agents, coloring agents, fragrances, and the like shown below can be included. By including these cosmetic components, a cosmetic having functions such as sustained release, controlled release, protection, and masking properties can be obtained. Plant extracts include astringent / cooling components, anti-inflammatory / anti-allergic components, bactericidal / bacteriostatic components, UV protection components, skin activating components, moisturizing components, and the like.
[0100]
Cosmetic agents include whitening agents, vitamins, hormones, antipruritics, antipruritics, anti-inflammatory agents, hair growth promoters, exfoliants, astringents, antioxidants, antibacterials, There are UV inhibitors such as benzophenone, benzoic acid, cinnamic acid and salicylic acid, and UV shielding agents such as titanium oxide, zinc oxide and cerium oxide. Examples of the coloring agent include organic synthetic coloring matter, natural coloring matter, inorganic coloring agent, white pigment, and polymer particles, and examples of the flavoring agent include natural flavoring, synthetic flavoring, and compounding flavoring.
[0101]
By encapsulating the above-mentioned cosmetic ingredients, not only the encapsulated cosmetic ingredients are gradually released and their effects can be maintained for a long period of time, but also they are easily decomposed or deteriorated by contact with air, light, heat and the like. Even if it is a component, decomposition or alteration of the component can be suppressed. Explaining with specific examples, by encapsulating cosmetic drugs such as vitamins, the antioxidant effect, which is the effect of vitamins, is exhibited over a long period of time, and the degradation and deterioration of vitamins due to contact with air are suppressed can do.
[0102]
As for the food-related drugs, various nutrients and preservatives shown below can be included. By incorporating these components, food-related drugs having functions such as sustained release, controlled release, protection, and masking properties can be obtained.
[0103]
Nutrients include docosaexaenoic acid, eisacopentaenoic acid, linoleic acid, γ-linolenic acid, α-linolenic acid, evening primrose oil, borage oil, lecithin, octacosanol, rosemary, sage, γ-oryzanol, β-carotene, In addition to palm carotene, perilla oil, chitin, chitosan, royal jelly, propolis, gimhema, heme iron, oil-soluble vitamins such as vitamin A, vitamin D, vitamin E, vitamin F, vitamin F, vitamin K, vitamin K and derivatives thereof, and vitamins Water-soluble vitamins such as B1, vitamin B2, vitamin B6, vitamin B12, vitamin C, vitamin L, vitamin P, nicotinic acid, pantothenic acid, and choline, and derivatives thereof. Further, in addition to preservatives such as an antioxidant, an oxygen scavenger, a preservative, a water retention emulsion stabilizer, a fungicide, an antibacterial agent, and a bactericide, a coloring agent, a coloring agent and the like can be applied.
[0104]
By encapsulating the above-mentioned food-related drug component, not only the component is gradually released and its effect can be continued for a long time, but also a component which is easily decomposed or deteriorated by contact with air, light, heat, etc. Even if it does, decomposition or alteration of the component can be suppressed. Explaining with specific examples, if a preservative component such as an antioxidant is included, not only does the component exert its effect over a long period of time, but also it can prevent decomposition or deterioration due to contact with air or light and heat. You can also. In addition, if a substance having an unpleasant taste during oral administration is included, a masking effect such as bitterness and acidity can be exhibited.
[0105]
With regard to the fragrance, various fragrance components shown below can be included. By incorporating these components, fragrances having functions such as sustained release, controlled release, protection, and masking properties can be obtained. In addition, by incorporating the fragrance component, not only can the aroma and flavor power be maintained for a long period of time, but also the storability can be improved by preventing oxidation and moisture absorption.
[0106]
The flavor components included include citrus essential oils such as orange, lemon, lime, and grapefruit, and plant essential oils such as flower essential oil, peppermint oil, spearmint oil, and spice oil, as well as cola nuts, coffee, vanilla, cocoa, black tea, Green tea, oolong tea, spices, bonito flavor, shrimp flavor, crab flavor, hinokitiol, extracts, ole oranges, essences, recovered fragrance, synthetic fragrance compounds, compounded fragrance compositions and the like.
[0107]
As for pesticides, various insecticides, insect repellents, fungicides, herbicides, pesticides, plant growth regulators, etc. can be mentioned, and fertilizers such as ammonium sulfate, salt ammonium, ammonium nitrate, sodium nitrate, nitrate lime, urea, etc. Phosphate fertilizers such as nitrogenous fertilizer, lime superphosphate, lime superphosphate, and water-soluble phosphoric acid, potash fertilizers such as potassium sulfate, potassium chloride, potassium sulfate, and soluble potassium, as well as fertilizers containing pesticides. And wood vinegar.
[0108]
The functional particles containing these pesticides or fertilizers are effective as sustained-release pesticides or sustained-release fertilizers that exhibit their effects over a long period of time because the components of the contained pesticides or fertilizers are gradually released. In addition, even if the substance is easily decomposed or deteriorated by contact with air or water and its efficacy is reduced, decomposition or deterioration can be suppressed by enclosing the substance in a hollow carrier.
[0109]
The functional particles produced in this manner can exhibit various effects by encapsulating the various substances as described above, and further have the surface coated with an organic polymer, a fatty acid or a fatty acid salt as necessary. Thus, by enhancing the effect of preventing or protecting the contained substance from leaking or by modifying the surface properties, it can be optimized for various uses.
[0110]
The organic polymer used at this time may be appropriately selected depending on the application and required performance. However, if a water-soluble polymer in which a hydrophilic solvent can be used is used, coating can be performed relatively easily. The water-soluble polymer includes a natural polymer, a modified natural polymer, and a synthetic polymer. As the natural polymer, starchy materials, mannan, seaweed, plant mucilage, microbial mucilage, protein and the like can be used.
[0111]
More specifically, starchy substances include potato starch, potato starch, tapioca starch, wheat starch, corn starch, etc., mannan include konjac, etc., and seaweeds include funi, agar (galactan), sodium alginate. Examples of plant mucilage include trollooi, tragacanth gum, gum arabic and the like, microbial mucilage includes dextran and levan, and proteins include gelatin, casein, collagen, glue and the like.
[0112]
Examples of the modified natural polymer include cellulose-based viscose, methylcellulose (MC), ethylcellulose (EC), hydroxyethyl erulose (HEC), carboxymethylcellulose (CMC), and the like. CMS), dialdehyde starch and the like. Examples of the synthetic polymer include polyvinyl alcohol (PVA), sodium polyacrylate, and polyethylene oxide.
[0113]
In particular, for pharmaceutical and food applications, edible biopolymers such as gelatin, casein, myosin, collagen, alginic acid, chitosan, zein, mannan, carrageenan, soybean protein, dextrin, starch, curdlan, and xanthan gum are suitable.
[0114]
Further, as the above-mentioned fatty acids for coating, lauric acid, myristic acid, palmitic acid, stearic acid, oleic acid, behenic acid and the like can be used, and as the fatty acid salts, sodium salts and potassium salts of these fatty acids can be used. By coating the surface with these fatty acids or fatty acid salts, the surface of the functional particles can be made lipophilic, and by imparting water repellency, contact between the functional particles and water can be suppressed. It is also possible to control the release and control the release rate.
[0115]
To coat particles containing an active substance in a hollow carrier with these organic polymers, fatty acids or fatty acid salts, after encapsulating the active substance, add an appropriate amount of an organic polymer or the like before drying, and flow Drying may be performed using a layer dryer, a spray dryer (spray dryer), a vacuum freeze dryer, or the like. In addition, these organic polymers and the like can be used alone, but it is also possible to express effects that cannot be obtained alone by using two or more substances in combination or by crosslinking in some cases. .
[0116]
Further, as described above, the hollow carrier can be used as a slurry without forming a dry powder. For example, in order to enclose edible oil inside a hollow carrier in a water slurry state, edible oil is added directly or as an emulsion to a water slurry of a hollow carrier made of basic magnesium carbonate, and the whole is homogenized as much as possible by stirring or the like. I do. Next, by utilizing the difference in boiling point between water and edible oil, this mixture is heated to evaporate only water, so that the edible oil can be included inside the tubular structure.
[0117]
Although the temperature at this time is not particularly limited, it is 40 ° C. to the boiling point or less under normal pressure, preferably 60 to 90 ° C. If it is less than 40 ° C., it takes time to evaporate water. Therefore, the temperature is preferably from 60 to 90 ° C., in which water can be removed in a relatively short time and boiling does not destroy the aggregated tubular particles. If necessary, this operation can be performed at a lower temperature by reducing the pressure.
[0118]
In addition, if the hollow carrier is previously subjected to lipophilic treatment with various surfactants such as fatty acids, resin acids, and coupling agents, oil-based substances can be included relatively easily. . After enclosing the desired substance in this manner, the substance adhering to the surface of the functional particles can be removed by washing with a solvent such as water or alcohol as needed.
[0119]
The hollow carrier of the present invention is, as described above, tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate, and the functional particles are obtained by contacting various effective substances with the tubular agglomerated particles as described above. By enclosing it inside the tubular structure, it can be manufactured by a relatively simple method. This unique shape of a tubular shape exhibits excellent characteristics such as a long-term stable sustained release effect, a release control property of releasing inclusions under a specific environment, a deterioration preventing effect, a masking effect, a protective effect, and the like.
[0120]
The sustained release effect also has a characteristic that the release speed can be controlled by controlling the length, inner diameter, and thickness of the tube. Furthermore, the above-mentioned functional particles have a surface coated with an organic polymer as necessary, and have a variety of effects, such as a leakage prevention and a sustained release effect, a deterioration prevention effect, a masking effect, a protection effect, etc. of the contained substance. It can correspond to the application.
[0121]
【Example】
Hereinafter, the present invention will be described more specifically with reference to Examples and Comparative Examples. However, the present invention is not limited to these Examples and is specified by the appended claims. Needless to say. The production (comparative) example relates to a hollow carrier, and the applied (comparative) example relates to functional particles.
[0122]
[Production Example 1] (Production of hollow carrier)
To 2.0 L of an aqueous solution of magnesium sulfate heptahydrate (125 g / L) adjusted to 40 ° C., while maintaining the temperature at 40 ° C., 0.50 L of an anhydrous sodium carbonate aqueous solution (220 g / L) was gradually added, followed by stirring for 50 minutes. Thus, magnesium orthocarbonate was obtained (first step). Observation of this orthomagnesium carbonate by SEM confirmed that it was columnar particles having a diameter of 1 to 3 μm and a length of 10 to 50 μm.
[0123]
Subsequently, the suspension of the magnesium orthocarbonate columnar particles (pH 10.2) obtained in the first step is heated and stirred for 120 minutes while maintaining the temperature at 55 ° C. to produce basic magnesium carbonate. (Second step). The obtained product was washed with ion-exchanged water and ethanol, dried, and then observed with a SEM. As a result, flaky primary particles having a thickness of 0.01 to 0.04 μm and a diameter of 0.5 to 2 μm were obtained. It was confirmed that these were basic magnesium carbonate tubular aggregated particles having an outer diameter of 1 to 5 μm, an inner diameter of 0.5 to 3 μm, and a length of 5 to 20 μm.
[0124]
[Production Example 2] (Production of hollow carrier)
7. A 2.0-liter suspension of magnesium hydroxide (30 g / L) was stirred at a temperature of 20 ° C. while stirring, and a carbon dioxide-containing gas consisting of 25% by volume of carbon dioxide and 75% by volume of air was added. After introducing the solution at a rate of 0 L / min for 30 minutes, the insoluble residue was removed to prepare a magnesium hydrogen carbonate solution (pH 7.3) (first step).
[0125]
Following this step, an appropriate amount of aqueous sodium hydroxide solution is added to the magnesium hydrogen carbonate solution to adjust the pH of the solution to 8.0, and the temperature is raised to 35 ° C. by heating. The suspension was stirred for 60 minutes while maintaining the temperature to prepare a suspension of orthomagnesium carbonate (second step). When this orthomagnesium carbonate was observed by SEM, it was confirmed that the particles were columnar particles having a diameter of 5 to 10 μm and a length of 30 to 100 μm.
[0126]
Subsequently, an appropriate amount of an aqueous sodium hydroxide solution was added to the suspension of columnar particles of magnesium orthocarbonate to adjust the pH of the solution to 10.5, and the solution was heated to raise the solution temperature to 55 ° C. The mixture was stirred for 120 minutes while maintaining the same temperature to obtain a suspension of basic magnesium carbonate (third step). Observation of this basic magnesium carbonate with a SEM revealed that it was composed of flaky fine crystals having a thickness of 0.02 to 0.1 μm and a diameter of 1 to 2 μm, an inner diameter of 2 to 5 μm, an outer diameter of 5 to 10 μm, and a length of 20 to It was confirmed that the particles were 50 μm tubular aggregated particles.
[0127]
[Production Example 3] (Production of hollow carrier)
A suspension of basic magnesium carbonate was obtained in the same manner as in Production Example 2 except that the pH in the second step was 9.0 and the temperature in the third step was 50 ° C.
In addition, when the orthomagnesium carbonate generated in the second step was observed by SEM, it was confirmed that the particles were columnar particles having a diameter of 1 to 3 μm and a length of 20 to 50 μm. When the basic magnesium carbonate obtained in the third step was observed with a SEM, the thickness was 0.01 to 0.05 μm and the diameter was 0.2 to 1 μm. It was confirmed that the particles were tubular aggregated particles having an outer diameter of 2 to 3 μm and a length of 5 to 30 μm.
[0128]
[Production Example 4] (Production of hollow carrier)
A suspension of basic magnesium carbonate was obtained in the same manner as in Production Example 2, except that the pH in the second step was set to 10.0 and the temperature in the third step was set to 40 ° C. In addition, when the orthomagnesium carbonate generated in the second step was observed by SEM, it was confirmed that the particles were columnar particles having a diameter of 0.5 to 1 μm and a length of 10 to 50 μm.
[0129]
Further, when the basic magnesium carbonate obtained in the third step was observed by SEM, it was found that the inner diameter was 0.1 to 0.5 μm and a diameter of 0.1 to 0.5 μm. It was confirmed that the particles were tubular agglomerated particles having a size of 5 to 1 μm, an outer diameter of 1 to 1.5 μm, and a length of 5 to 30 μm.
[0130]
[Production Example 5] (Production of hollow carrier coated with metal oxide)
In the same manner as in Production Example 3, a suspension of tubular aggregated particles of basic magnesium carbonate was obtained. An appropriate amount of ion-exchanged water was added to this suspension to make 2.0 L of a suspension having a solid content of 20 g / L. Then, while maintaining the temperature at 50 ° C. and stirring, the reagent sodium aluminate (Kanto Chemical; First grade, Al _Two O _Three 500 mL of a solution (concentration: 35% by weight) (concentration: 40 g / L) was added at a rate of 5 mL / min using a tube pump.
[0131]
Stirring was continued for 15 minutes after the addition was completed (the amount of sodium aluminate added was 100 g of MgO in basic magnesium carbonate). _Two O _Three 20.5g in conversion). Then, the suspension of the product was separated by filtration, washed with 10 L of water, further washed with 1 L of methyl alcohol, and dried at 105 ° C. to obtain a surface-treated basic magnesium carbonate.
[0132]
Observation of the product by SEM revealed that 50 to 100 nm of fine alumina particles adhered to the surface of the flaky fine crystal forming the tubular aggregated particles of basic magnesium carbonate. In this state, the entire surface of the crystal was covered. When the pH of the 1% by weight suspension of the hollow carrier was measured based on JIS K5101, it was 8.6, and it was confirmed that the suspension was neutralized. Not covered with metal oxide
Was measured in the same manner and found to be alkaline with a pH of 10.5 to 11.
[0133]
[Production Example 6] (Production of hollow carrier surface-treated with fatty acid salt)
In the same manner as in Production Example 3, a suspension of tubular aggregated particles of basic magnesium carbonate was obtained. While maintaining and stirring the suspension at a temperature of 50 ° C., 100 mL of an aqueous solution (concentration: 20 g / L) of a reagent sodium laurate (Kanto Chemical Co., Ltd., deer grade) heated to 50 ° C. was added thereto and stirred for 60 minutes. Continued.
[0134]
Thereafter, the suspension was dried with a spray dryer to obtain a hollow carrier surface-treated with sodium laurate. 5 g of this hollow carrier was put into a 200 mL beaker containing 100 mL of ion-exchanged water, and stirred vigorously for 1 minute with a glass rod. Was confirmed.
[0135]
[Production Comparative Example 1]
After gradually adding 0.50 L of an anhydrous sodium carbonate aqueous solution (200 g / L) to 2.0 L of an aqueous solution of magnesium sulfate heptahydrate (125 g / L) adjusted to 15 ° C. while maintaining the same temperature, the temperature of the mixture was measured. Was stirred for 3 hours while maintaining the temperature at 15 ° C. to obtain magnesium orthocarbonate. When the orthomagnesium carbonate was observed by SEM, it was columnar particles having a diameter of 20 to 30 μm and a length of 100 to 500 μm.
[0136]
This suspension of normal magnesium carbonate (pH 8.5) was stirred for 125 hours while maintaining the temperature at 20 ° C. to produce basic magnesium carbonate. The obtained product was washed with ion-exchanged water and ethanol, dried, and then observed with a SEM. The product was composed of flaky primary particles having a thickness of 0.05 to 0.5 μm and a diameter of 1 to 7 μm. The agglomerated particles were confirmed to be amorphous to elliptical basic magnesium carbonate having a diameter of 10 to 70 μm.
[0137]
[Production Comparative Example 2]
0.50 L of anhydrous sodium carbonate aqueous solution (220 g / L) was gradually added to 2.0 L of magnesium sulfate heptahydrate aqueous solution (125 g / L) adjusted to 80 ° C. while maintaining the temperature at 80 ° C. The mixture was stirred for 60 minutes while maintaining the temperature at 80 ° C. to produce basic magnesium carbonate.
[0138]
The obtained product was washed with ion-exchanged water and ethanol, dried, and then observed with a SEM. As a result, flaky primary particles having a thickness of 0.01 to 0.05 μm and a diameter of 0.3 to 2 μm were obtained. It was confirmed that it was an amorphous basic magnesium carbonate having a diameter of 2 to 4 μm. Note that, in this comparative example, the formation of magnesium orthocarbonate could not be confirmed in the course of the reaction.
[0139]
[Production Comparative Example 3]
Carbon dioxide gas was introduced into 2.0 L of magnesium hydroxide suspension (30 g / L) adjusted to 60 ° C. at a rate of 1.5 L / min for 240 minutes while stirring at a temperature of 60 ° C. Magnesium carbonate was produced. Note that, in this comparative example, the formation of magnesium orthocarbonate could not be confirmed in the course of the reaction.
[0140]
The obtained product was washed with ion-exchanged water and ethanol, dried, and then observed with a SEM. As a result, a flaky primary particle having a thickness of 0.01 to 0.05 μm and a diameter of 0.5 to 2 μm was obtained. It was confirmed to be elliptic to spherical basic magnesium carbonate having a diameter of 10 to 15 μm.
[0141]
[Application Example 1]
In a 500 mL beaker, 10.0 g of the basic magnesium carbonate of Production Example 1 was weighed, 200 mL of a methanol solution of naphthalene (20 mg / mL) was added, and the mixture was immersed for 1 hour. Then, the solid content was separated by filtration and washed with methanol. Then, functional particles containing naphthalene were produced by evaporating methanol. Similarly, with respect to the basic magnesium carbonates of Production Examples 2 to 4, functional particles containing naphthalene were produced.
[0142]
[Application Example 2]
10 g of the basic magnesium carbonate of Production Example 1 was impregnated with 10 g of a 1% aqueous solution of alkyl polyaminoethyl glycine hydrochloride, dried in an incubator at a temperature of 30 ° C., and water was evaporated. Functional particles having a release effect were produced. Similarly, with respect to the basic magnesium carbonates of Production Examples 2 to 4, functional particles having a sustained release effect of alkyl polyaminoethyl glycine hydrochloride were produced.
[0143]
[Application Example 3]
50 g of a commercially available bonito flavor was placed in a 200 ml beaker, and 50 ml of a 20% aqueous solution of a reagent α-cyclodextrin was added to prepare a bonito flavor-containing cyclodextrin aqueous solution. 20 g of the basic magnesium carbonate produced in Production Example 1 was added to this solution, and the mixture was stirred. The mixture was suctioned under reduced pressure until no air bubbles were observed, then returned to normal pressure, air-dried, and hollowed out of basic magnesium carbonate. The bonito flavor was included in the carrier.
[0144]
Then, 20 ml of a 2% aqueous solution of a carrageenan-glucomannan crosslinked product (6: 4) is added, mixed until uniform, dried by vacuum freeze drying, and surface-coated with a polymer (carrageenan-glucomannan crosslinked product). The dried bonito flavor-containing functional particles were produced. Similarly, with respect to the basic magnesium carbonates of Production Examples 2 to 4, bonito flavor-encapsulated functional particles surface-coated with a polymer were produced.
[0145]
[Application Example 4]
In a 200 ml beaker, 10 g of commercially available bifidobacteria (freeze-dried powder, viable cell count 4 × 108 / mL) and 10 ml of edible oil (“Panasate”, medium-chain fatty acid ester manufactured by NOF CORPORATION) are mixed lightly, After adding and stirring the basic magnesium carbonate having the tubular structure of Production Example 1 therein, the edible oil containing bifidobacteria was encapsulated in the basic magnesium carbonate having the tubular structure by reducing the pressure with a vacuum dryer. .
[0146]
Next, 10 g of milk calcium and 5 g of sodium caseinate were added to 25 ml of water, and the mixture was thoroughly stirred. Basic magnesium carbonate containing bifidobacteria was added first, mixed until uniform, and freeze-dried in vacuum to dry the surface with casein. To produce bifidobacterium-encapsulated functional particles. The Bifidobacterium-encapsulated functional particles thus produced were orally administered to cover the surface with casein and to neutralize the gastric acid invaded by basic magnesium carbonate if gastric acid entered slightly. At this time, the rate at which bifidobacteria are killed by stomach acid can be reduced.
[0147]
[Application Comparative Example 1]
In the same manner as in Example 1, naphthalene-impregnated particles were produced using the basic magnesium carbonates of Production Comparative Examples 1 to 3.
[0148]
[Application Comparative Example 2]
In the same manner as in Example 2, particles impregnated with alkylpolyaminoethylglycine hydrochloride were produced using the basic magnesium carbonates of Production Comparative Examples 1 to 3.
[0149]
[Application Comparative Example 3]
In the same manner as in Example 3, using the basic magnesium carbonates of Production Comparative Examples 1 to 3, particles impregnated with bonito flavor were produced.
[0150]
[Evaluation of sustained release of naphthalene]
The naphthalene-containing functional particles produced in Application Example 1 and Application Comparative Example 1 were placed in a thermostat at 40 ° C., and the residual ratio of naphthalene was measured over time. The results are shown in Table 1. As shown in Table 1, in the case of the application example 1 using the hollow carrier made of the basic magnesium carbonate having the tubular structure produced in the production example 1, about 20 to 30% even after 15 days. While naphthalene remains, in the case of Application Comparative Example 2 using the basic magnesium carbonate of Production Comparative Examples 1 to 3, it can be seen that all of the naphthalene was volatilized after 5 days.
[0151]
Looking at the inner diameter of the tubular aggregated particles used as the hollow carrier and the naphthalene sustained release effect (naphthalene residual ratio), those having the smaller inner diameter (Production Example 4, inner diameter 0.5 to 1 μm) showed the highest naphthalene residual ratio. Those with a high internal diameter and a large inner diameter (Production Example 2, inner diameter 2 to 5 μm) have a low naphthalene residual ratio. This is considered to be due to the fact that the smaller the inner diameter, the less the contact between the naphthalene contained inside the tubular structure of the hollow carrier and the outside air. Therefore, it is shown that the naphthalene release rate can be controlled by changing the inner diameter of the tubular aggregated particles.
[0152]
[Table 1]

[0153]
[Evaluation of antifungal property]
Antifungal properties of the functional particles impregnated with the alkyl polyaminoethyl glycine hydrochloride produced in Application Example 2 and Application Comparative Example 2, and the basic magnesium carbonate particles of Production Comparative Example 1 not impregnated with the alkyl polyaminoethyl glycine hydrochloride The following tests were performed to evaluate
[0154]
That is, water was poured under the glass desiccator, and the particles were spread on a petri dish placed in the middle stage. A filter paper of 5C was placed thereon, and a bread of 3 cm square and 1.2 cm thick was placed thereon. The lid was kept open at 10% and stored in an incubator set at 28 ° C. Then, after 30 days, 90 days, and 120 days, the bread was examined for the occurrence of mold growing on the bread.
[0155]
The results are as shown in Table 2. No generation of mold was observed in the functional particles using the basic magnesium carbonate having a tubular structure produced in Application Example 2 as a hollow carrier after 120 days. On the other hand, with respect to the functional particles of Application Comparative Example 2 using the basic magnesium carbonates of Production Comparative Examples 1 to 3, generation of mold was observed after 90 days. In addition, in the case of basic magnesium carbonate not impregnated with alkyl polyaminoethyl glycine hydrochloride, a large amount of mold was generated after 30 days.
[0156]
[Table 2]

[0157]
[Evaluation of masking effect of bonito flavor]
The bonito flavor-containing functional particles produced in Application Example 3 and Application Comparative Example 3 are weighed at a rate of 10 g each in six 200 ml beakers, and 6.2 g each of commercially available bonito flavors in another six 200 ml beakers. And stored in a constant temperature and humidity room at a room temperature of 23 ° C. and a humidity of 50%. On the test start date, 3 days, 1 week, 2 weeks, 1 month, and 2 months, 100 ml of boiling water was poured into a beaker, and the intensity of the aroma was examined.
[0158]
The results are as shown in Table 3, and it was confirmed that the bonito flavor-containing functional particles of Application Example 3 emitted a strong aroma even after two months. On the other hand, in the case of Application Comparative Example 3 using the basic magnesium carbonate of Production Comparative Examples 1 to 3, the fragrance was weakened after one week, and the fragrance was hardly felt after two weeks. In addition, the flavor of the commercially available bonito flavor became weak after 3 days, and after 1 week, almost no fragrance was felt.
[0159]
[Table 3]

[0160]
From the above results, that is, as is clear from Tables 1 to 3, the functional particles of the applied examples are derived from the unique shape of the hollow carrier composed of tubular aggregated particles of flaky fine crystals of basic magnesium carbonate. It has a high sustained release property and a masking effect.
[0161]
【The invention's effect】
The functional particles of the present invention are produced by a relatively simple method by contacting a hollow carrier composed of flaky fine crystal tubular agglomerated particles of basic magnesium carbonate with various effective substances and enclosing the same in a tubular structure. it can. The unique shape of the tubular shape exhibits excellent characteristics such as a long-term stable sustained release effect, a release control property of releasing inclusions under a specific environment, a deterioration preventing effect, a masking effect, a protective effect, and the like.
[0162]
In particular, the sustained release effect has an excellent property that the release speed can be controlled by controlling the length, inner diameter, and thickness of the tube.
Furthermore, the above-mentioned functional particles can be applied to various uses by coating the surface with an organic polymer as necessary to prevent leakage of the contained substance and to enhance the protective effect.

Claims (13)

A hollow carrier comprising tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate. The hollow carrier according to claim 1, wherein the tubular aggregated particles have an outer diameter of 1 to 20 m, an inner diameter of 0.5 to 5 m, a length of 5 to 200 m, and a length / outer diameter ratio of 2 to 50. The hollow carrier according to claim 1 or 2, wherein the surface of the tubular aggregated particles is coated with a metal oxide, and the tubular aggregated particles have a pH value of 9.5 or less according to JIS K5101. The hollow carrier according to any one of claims 1 to 3, wherein the tubular aggregated particles are surface-treated with a fatty acid or a fatty acid salt, and the tubular aggregated particles exhibit lipophilicity. Functional particles characterized in that one or more substances are encapsulated in a hollow carrier composed of tubular agglomerated particles of flaky fine crystals of basic magnesium carbonate. The functional particles according to claim 5, wherein the tubular aggregated particles have an outer diameter of 1 to 20 m, an inner diameter of 0.5 to 5 m, a length of 5 to 200 m, and a length / outer diameter ratio of 2 to 50. 7. The functional particles according to claim 5, wherein the surface of the hollow carrier containing at least one substance is coated with a polymer substance, a fatty acid or a fatty acid salt. The functional particles according to any one of claims 5 to 7, wherein the substance to be included is a fragrance substance, a nutrient, a food additive, a medicine, an agricultural chemical, or a fertilizer. Mixing a water-soluble magnesium salt and a water-soluble carbonate to form columnar particles of normal magnesium carbonate having a diameter of 0.5 to 10 μm and a length of 5 to 500 μm at a temperature of 25 to 55 ° C .; The suspension of the columnar particles of magnesium carbonate at a temperature higher than the temperature at which the magnesium carbonate was formed in the first step, at a temperature of 40 to 70 ° C. and a pH of 9.5 to 11.5. A method of producing a hollow carrier, comprising tubular aggregated particles of flaky fine crystals of basic magnesium carbonate prepared by a second step of heat treatment in a range. A first step of preparing a magnesium bicarbonate solution by introducing a carbon dioxide-containing gas into the magnesium hydroxide suspension, and adjusting the magnesium bicarbonate solution to a pH of 7.5 to 11.0 to form a columnar form of normal magnesium carbonate. A second step of forming particles, and adjusting the pH of the suspension of columnar particles of magnesium carbonate to a pH of 9.0 to 12.0 and a temperature of 30 to 75 ° C., and then maintaining the above temperature range, A method for producing a hollow carrier, comprising: tubular aggregated particles of flaky fine crystals of basic magnesium carbonate prepared by the third step of producing magnesium carbonate. A method for producing functional particles, comprising bringing one or more substances into contact with the hollow carrier according to claim 9 or 10, thereby including the substance inside the hollow carrier. A method for producing functional particles, comprising, after encapsulating one or more substances in the hollow carrier according to claim 9 or 10, and coating the surface with a polymer substance, a fatty acid or a fatty acid salt. The production of the functional particles according to claim 11 or 12, wherein the substance included in the hollow carrier is at least one selected from a fragrance substance, a nutrient, a food additive, a medicine, a pesticide or a fertilizer. Method.