TW201325685A - Method for separating macromolecules with different molecular weight by simulated moving bed - Google Patents

Method for separating macromolecules with different molecular weight by simulated moving bed Download PDF

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TW201325685A
TW201325685A TW100149568A TW100149568A TW201325685A TW 201325685 A TW201325685 A TW 201325685A TW 100149568 A TW100149568 A TW 100149568A TW 100149568 A TW100149568 A TW 100149568A TW 201325685 A TW201325685 A TW 201325685A
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molecular weight
moving bed
polymer
stationary phase
regions
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TW100149568A
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TWI428167B (en
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Ming-Tsai Liang
Ru-Chien Liang
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Univ Ishou
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Abstract

A method for separating macromolecules with different molecular weight by simulated moving bed (SMB) comprises: (a) providing a three-connected-section SMB device containing a mobile phase and a stationary phase with poles in its interior, and the three connected sections α , β and γ with first, second and third flow-rate ratios (m α , m β and m γ ), respectively; (b) providing a mixture containing a large macromolecule and a small macromolecule with elusion constant KL and KS, respectively, wherein the elusion constant KL is smaller than the elusion constant KS, and injecting the mixture into the SMB device, and the stationary phase of the SMB device providing different path for the large and small macromolecules to migrate; (c) making the first flow-rate ratio (m α ) > KL and KS, the second and third flow-rate ratios (m β and m γ ) between KL and KS, and resulting in the two macromolecules to be separated.

Description

一種以模擬移動床分離不同分子量高分子之方法Method for separating different molecular weight polymers by simulated moving bed

本發明係關於一種以模擬移動床分離不同分子量高分子之方法,特別是一種以模擬移動床連續式地分離不同分子量高分子之方法。The present invention relates to a method for separating polymers of different molecular weights by simulating moving beds, and more particularly to a method for continuously separating polymers of different molecular weights by simulating moving beds.

習知連續操作之純化技術包含有:(1)逆相層析(Countercurrent Chromatography)、(2)環管層析(Annual Chromatography)及(3)模擬移動床層析(Simulated Moving Bed,簡稱SMB),其中,逆相層析及環管層析目前仍處於實驗室的開發階段而無法實際應用於產業,而模擬移動床具有降低操作成本及溶劑耗量的優點,因此,目前業界多以模擬移動床作為連續式的純化平台。Conventional continuous purification techniques include: (1) Countercurrent Chromatography, (2) Annular Chromatography, and (3) Simulated Moving Bed (SMB). Among them, reverse phase chromatography and loop chromatography are still in the development stage of the laboratory and cannot be practically applied to the industry. The simulated moving bed has the advantages of reducing operating cost and solvent consumption. Therefore, the current industry mostly uses analog mobile. The bed acts as a continuous purification platform.

請參照第1圖所示,係一組習用四區域之模擬移動床配置示意圖。該SMB係藉由一固定相(Stationary phase,簡稱SP)及一移動相(Mobile phase,簡稱MP)於該四區域之間的相對流動,以分離混合物中的物質。該SMB之四區域分別為α、β、γ及δ區域,該固定相係填充於各區域之數個管柱中,該移動相係於該管柱中朝同一方向流動,並藉由一進料口切換裝置改變該混合物之進料位置,以模擬該固定相與該移動相之相對流動方向。Please refer to Figure 1 for a set of simulated moving bed configurations for a four-zone. The SMB is a relative flow between the four regions by a stationary phase (Stationary phase, SP for short) and a mobile phase (MP) to separate the substances in the mixture. The four regions of the SMB are α, β, γ, and δ regions, respectively, and the stationary phase is filled in a plurality of columns of each region, and the mobile phase flows in the same direction in the column, and The port switching device changes the feed position of the mixture to simulate the relative flow direction of the stationary phase and the mobile phase.

該混合物進入SMB後,該混合物所包含之物質A及B會依照各物質的亨利常數H分別被該固定相吸附或隨該移動相移動,進而分離或純化各物質A及B。舉例而言,若物質A及B中,與該固定相吸附較強者為物質A,則物質A及B之亨利常數H為HA>HBAfter the mixture enters the SMB, the substances A and B contained in the mixture are respectively adsorbed by the stationary phase or moved along with the mobile phase according to the Henry's constant H of each substance, thereby separating or purifying each of the substances A and B. For example, if substances A and B are strongly adsorbed by the stationary phase as substance A, the Henry's constant H of substances A and B is H A >H B .

SMB係根據Yu,H.W等人於2002年所提出之三角理論(“Optimization of a SMB based on an approximated Langmuir Model”AIChE J. 48,2240-2246)所定義該混合物中的各種物質於各區域之淨質量通量F,並控制該淨質量通量F中各區域的流速比值n(各區域之流速比值分別為nα、nβ、nγ及nδ),使該混合物中的各種物質之亨利常數H於各區域中係符合如第1表所示之預定範圍內,藉此以該SMB對該混合物之各種物質加以分離。The SMB is based on the theory of the triangle proposed by Yu, HW et al. in 2002 ("Optimization of a SMB based on an approximated Langmuir Model" AIChE J. 48, 2240-2246). a net mass flux F, and controlling the flow rate ratio n of each region in the net mass flux F (the flow rate ratios of the respective regions are n α , n β , n γ , and n δ , respectively ), so that various substances in the mixture are The Henry's constant H is within a predetermined range as shown in Table 1 in each region, whereby the various substances of the mixture are separated by the SMB.

舉例而言,將該混合物自該β及γ區域注入該SMB中,當各區域之流速比值n滿足第1表所示之條件,該物質A移動至該α區域,該物質B移動至β、γ或δ區域後,即可於該α區域得到純度較高的物質A。For example, the mixture is injected into the SMB from the β and γ regions, and when the flow rate ratio n of each region satisfies the condition shown in Table 1, the substance A moves to the α region, and the substance B moves to β, After the γ or δ region, a substance A having a higher purity can be obtained in the α region.

然而,由於SMB分離混合物的原理,係根據該混合物中物質A及B與固定相之間的吸附能力而推導出符合第1表所示的三角理論,並以亨利常數H作為代表各物質之吸附能力的參考常數,對於不同分子量高分子而言,各不同分子量高分子與該固定相之吸附能力的鑑別度不佳,而無法以亨利常數H作為分離的參考常數。However, due to the principle of SMB separation mixture, the triangulation theory according to Table 1 is derived based on the adsorption capacity between the substances A and B in the mixture and the stationary phase, and the Henry's constant H is used as the representative of the adsorption of each substance. The reference constant of the ability, for different molecular weight polymers, the discrimination of the adsorption capacity of the different molecular weight polymers and the stationary phase is not good, and the Henry's constant H cannot be used as the separation reference constant.

以親水性高分子中的聚乙二醇(Polyethylene glycol,簡稱PEG)為例,該PEG能夠作為一種藥物載體以延長藥物於生物體內釋放的時間。現階段選用特定分子量之PEG的方法,係僅能以特定的PEG製程條件控制並提高該特定分子量PEG之產量,然而,所產出的PEG純度不高,且可能包含有分子量小於400且具有生物毒性之PEG。因此,有必要提供一種連續式的純化方法係能夠對不同分子量之PEG進行純化,以得到純度高的PEG產物。Taking polyethylene glycol (PEG) in a hydrophilic polymer as an example, the PEG can be used as a drug carrier to prolong the release time of the drug in the living body. At this stage, the method of selecting PEG of a specific molecular weight can only control and increase the yield of the specific molecular weight PEG by a specific PEG process condition, however, the produced PEG is not pure, and may contain a molecular weight of less than 400 and have a biological Toxic PEG. Therefore, it is necessary to provide a continuous purification method capable of purifying PEG of different molecular weights to obtain a PEG product of high purity.

本發明之主要目的係提供一種以模擬移動床分離不同分子量高分子之方法,能夠分離出特定分子量之高分子。The main object of the present invention is to provide a method for separating a polymer of a different molecular weight by simulating a moving bed, and capable of separating a polymer having a specific molecular weight.

本發明之次一目的係提供一種以模擬移動床分離不同分子量高分子之方法,能夠以連續式進料分離特定分子量高分子。A second object of the present invention is to provide a method for separating polymers of different molecular weights by simulating a moving bed, which is capable of separating a specific molecular weight polymer by continuous feeding.

為達到前述發明目的,本發明之以模擬移動床分離不同分子量高分子之方法,包含:In order to achieve the foregoing object, the present invention provides a method for separating different molecular weight polymers by simulating a moving bed, comprising:

(a)提供一包含至少三區域之模擬移動床係由一移動相及一固定相所組成,其中,該固定相顆粒內部係具有孔隙,該三區域依序為α、β及γ區域,分別具有一流速比值mα、mβ及mγ,該移動相於該模擬移動床中係朝同一方向流經該三區域之間,該固定相係相對於該移動相朝反方向模擬移動;(b)提供具有至少二不同大、小分子量高分子混合物注入該模擬移動床中,該大、小分子量高分子分別具有一去滌常數KL及KS,該去滌常數KL小於該去滌常數KS,該固定相之孔隙係用以提供該大、小分子量高分子不同的移動距離;及(c)該α區域之流速比值mα應大於KL及KS,該β及γ區域之流速比值mβ及mγ應介於KL及KS之間,使該小分子量者移動至該α區域,該大分子量者移動至該β及γ區域,以分離該大及小分子量高分子。(a) providing a simulated moving bed system comprising at least three regions consisting of a mobile phase and a stationary phase, wherein the stationary phase particles have pores inside, and the three regions are sequentially α, β and γ regions, respectively Having a flow rate ratio m α , m β , and m γ , the moving phase flows between the three regions in the same direction in the simulated moving bed, and the stationary phase simulates moving in a reverse direction with respect to the moving phase; b) providing a mixture of at least two different large and small molecular weight polymers injected into the simulated moving bed, the large and small molecular weight polymers respectively having a de-collection constant K L and K S , and the de-polyester constant K L is smaller than the de-diluting a constant K S , the pore of the stationary phase is used to provide different moving distances of the large and small molecular weight polymers; and (c) the flow rate ratio m α of the α region should be greater than K L and K S , the β and γ regions The flow rate ratios m β and m γ should be between K L and K S to move the small molecular weight to the α region, and the large molecular weight is moved to the β and γ regions to separate the large and small molecular weights. molecule.

本發明之以模擬移動床分離不同分子量高分子之方法中,該固定相顆粒內部具有一孔隙度εp,該高分子能夠滲入該固定相顆粒的孔隙體積具有一體積分率KD,該去滌常數K係指該固定相顆粒內部的孔隙度εp與該高分子能夠滲入的孔隙體積佔該固定相顆粒孔隙之體積分率KD的乘積。In the method for simulating a moving bed to separate polymers of different molecular weights, the stationary phase particles have a porosity ε p inside, and the polymer can penetrate into the pore volume of the stationary phase particles to have an integral integration ratio K D . The constant K refers to the product of the porosity ε p inside the stationary phase particles and the pore volume in which the polymer can penetrate into the volume fraction K D of the pores of the stationary phase particles.

本發明之以模擬移動床分離不同分子量高分子之方法中,該α區域之後端設有一第一出料口Oα,該γ區域之後端較佳設有一第二出料口Oγ,一進料口I設於該β及γ區域之間。In the method for simulating a moving bed to separate polymers of different molecular weights, the first end of the α region is provided with a first discharge port O α , and the rear end of the γ region is preferably provided with a second discharge port O γ The port I is disposed between the β and γ regions.

本發明之以模擬移動床分離不同分子量高分子之方法中,該小分子量者自該第一出料口Oα流出,該大分子量者自該第二出料口Oγ流出。In the method for simulating a moving bed to separate polymers of different molecular weights, the small molecular weight is discharged from the first discharge port O α , and the large molecular weight is discharged from the second discharge port O γ .

本發明之以模擬移動床分離不同分子量高分子之方法中,各該區域包含至少一管柱,該管柱內填充一顆粒內部具有孔隙之固定相。In the method for simulating a moving bed to separate polymers of different molecular weights, each of the regions comprises at least one column filled with a stationary phase having pores inside the particles.

本發明之以模擬移動床分離不同分子量高分子之方法,其中,該高分子為聚乙二醇、聚乳酸、聚乙烯吡咯酮或多醣。In the present invention, a method for separating a polymer of a different molecular weight by a simulated moving bed, wherein the polymer is polyethylene glycol, polylactic acid, polyvinylpyrrolidone or a polysaccharide.

為讓本發明之上述及其他目的、特徵及優點能更明顯易懂,下文特舉本發明之較佳實施例,並配合所附圖式,作詳細說明如下:The above and other objects, features and advantages of the present invention will become more <RTIgt;

本發明以模擬移動床分離不同分子量高分子之方法,係用以分離不同分子量高分子,特別係以一去滌常數K做為分離不同分子量高分子的參考常數,該去滌常數K係與該高分子於固定相顆粒孔隙內的移動距離具有線性關係。The method for separating different molecular weight polymers by simulating moving bed is used for separating polymers of different molecular weights, in particular, using a de-collection constant K as a reference constant for separating polymers of different molecular weights, the de-polyester constant K system and the The moving distance of the polymer in the pores of the stationary phase particles has a linear relationship.

本發明所指高分子係由至少一種相同的結構單元(稱作單體),藉由共價鍵相互連接而形成的聚合物,該聚合物能夠均勻分散於適當溶液中而不會發生團聚或凝集,如此,該高分子於該SMB各區域內之流動才能夠呈線性關係。例如聚乙二醇(簡稱PEG)、聚乳酸(Poly lactic acid,簡稱PLA)、聚乙烯吡咯酮(Polyvinyl pyrrolidone,簡稱PVP)等,以及生物體內常見的多醣(Polysaccharide)、聚胺基酸(Amino acid,又稱胜肽)、蛋白質(Protein)、核酸(Nucleic acid,又可分成核糖核酸及去氧核糖核酸)等;本實施例係將不同分子量之PEG分散於純水溶液中以SMB進行分離。The polymer referred to in the present invention is a polymer formed by interconnecting at least one identical structural unit (referred to as a monomer) by covalent bonds, and the polymer can be uniformly dispersed in a suitable solution without agglomeration or Aggregation, in this way, the flow of the polymer in each region of the SMB can be linear. For example, polyethylene glycol (referred to as PEG), polylactic acid (PLA), polyvinyl pyrrolidone (PVP), and the like, and polysaccharides (polysaccharides) and polyamino acids (Amino) commonly found in living organisms. Acid, also known as peptide, protein, nucleic acid (Nucleic acid, can be divided into ribonucleic acid and deoxyribonucleic acid), etc.; in this embodiment, PEG of different molecular weight is dispersed in a pure aqueous solution and separated by SMB.

本發明之以模擬移動床分離不同分子量高分子之方法,係提供一包含至少三區域之SMB作為一種連續進料式的純化平台,對具有不同分子量高分子進行純化。舉例而言,本發明之SMB可以提供如第2圖所示之三區域的SMB,該SMB係由一移動相及一具有孔隙之固定相所組成,該三區域依序為α、β及γ區域,其中該α區域之後端設有一第一出料口Oα(稱作Extract outlet),該γ區域之後端設有一第二出料口Oγ(稱作Raffinate outlet),該進料口I(稱作Feed inlet)則設於該β及γ區域之間。該三分離區域係由至少一管柱c組成,該三分離區域之管柱c相互連通,該管柱c內係填充一固定相(Stationary phase,簡稱SP),特別係該固定相的顆粒內部具有孔隙,且該固定相之顆粒間亦具有間隙供該移動相通過,並使該移動相(Mobile phase,簡稱MP)朝同一方向依序流經該α、β及γ區域之管柱c內,該固定相則係以一進料口切換裝置於一切換時間tsw後改變該進料口I於該三分離區域之相對位置,使該固定相相對該移動相朝另一方向模擬移動。The method for simulating a moving bed to separate polymers of different molecular weights according to the present invention provides a purification platform comprising at least three regions of SMB as a continuous feed type purification platform for polymers having different molecular weights. For example, the SMB of the present invention can provide a three-region SMB as shown in FIG. 2, the SMB consisting of a mobile phase and a stationary phase having pores, which are sequentially α, β, and γ. a region, wherein the rear end of the alpha region is provided with a first discharge port O α (referred to as an extract outlet), and a rear end of the γ region is provided with a second discharge port O γ (referred to as Raffinate outlet), the feed port I (called Feed inlet) is located between the β and γ regions. The three separation regions are composed of at least one column c, and the columns c of the three separation regions are connected to each other. The column c is filled with a stationary phase (SP), in particular, the internal phase of the stationary phase. Having pores, and the particles of the stationary phase also have a gap for the mobile phase to pass, and the mobile phase (MP) flows sequentially in the same direction through the column c of the α, β, and γ regions. The stationary phase changes the relative position of the feed port I to the three separation regions after a switching time tsw by a feed port switching device to simulate the movement of the stationary phase relative to the moving phase in the other direction.

本發明之以模擬移動床分離不同分子量高分子之方法,係根據該固定相顆粒內部之孔隙與該高分子的分子量大小之關係,使不同分子量高分子於該固定相中具有不同移動距離,且該高分子與該固定相之間不具有吸附性,而是該高分子的分子量與固定相所提供的移動距離具有線性關係,如此,能夠達到分離不同分子量高分子之目的。The method for separating different molecular weight polymers by simulating moving bed according to the present invention is to make different molecular weight polymers have different moving distances in the stationary phase according to the relationship between the pores inside the stationary phase particles and the molecular weight of the polymer, and The polymer does not have adsorptivity with the stationary phase, but the molecular weight of the polymer has a linear relationship with the moving distance provided by the stationary phase. Thus, the purpose of separating polymers of different molecular weights can be achieved.

更詳言之,該SMB之固定相顆粒內部係具有一固定體積之孔隙,而分子量較小的高分子進入管柱後,其能夠滲入的孔隙體積佔該固定相顆粒內部孔隙的體積分率為KDS(分子量較大者,其能夠滲入的孔隙體積佔該固定相顆粒內部孔隙的體積分率為KDL),而其分子半徑R(Stoke Radius)係相對於分子量較大者小,因此,該分子量較小的高分子越容易進入固定相顆粒內部之孔隙中,而該分子量較大之高分子較不易進入該孔隙中,則該分子量較大者的體積分率KDL越接近0,該分子量較大之高分子自進入該管柱至流出該管柱之所需時間越短。請參考公式Ⅰ,原以混合物與固定相間吸附能力(亨利常數H)為基礎的淨質量通量F公式中,可將亨利常數H代換為去滌常數K。More specifically, the internal phase of the SMB has a fixed volume of pores, and after the smaller molecular weight polymer enters the column, the volume of pores that can penetrate into the pores of the stationary phase particles is divided. K DS (the larger the molecular weight, the pore volume that can penetrate into the pore volume of the stationary phase particles is K DL ), and the molecular radius R (Stoke Radius) is smaller than the larger molecular weight, therefore, The polymer having a smaller molecular weight is more likely to enter the pores inside the stationary phase particles, and the polymer having a larger molecular weight is less likely to enter the pore, and the volume fraction K DL of the larger molecular weight is closer to 0. The shorter the time required for the larger molecular weight polymer to enter the column to flow out of the column. Please refer to Formula I. In the net mass flux F formula based on the adsorption capacity between the mixture and the stationary phase (Henry's constant H), the Henry's constant H can be replaced with the de-refresh constant K.

其中,Qsp為移動相的體積流速;εe為固定相顆粒間的孔隙度,而1-εe係指管柱內扣除該固定相顆粒間孔隙之比例;m為同一區域內固定相與流動相之流速比值;C為高分子於該區域內流動相之濃度;K為去滌常數,係「該固定相顆粒內部的孔隙度εp」與「該高分子能夠滲入的孔隙體積佔該固定相顆粒孔隙之體積分率KD」的乘積(即K=εep‧KD)。Where Qsp is the volumetric flow rate of the mobile phase; ε e is the porosity between the stationary phase particles, and 1-ε e is the ratio of the inter-particle pores in the column; m is the stationary phase and flow in the same region The ratio of the velocity of the phase; C is the concentration of the mobile phase in the region; K is the de-collection constant, which is "the porosity ε p inside the stationary phase particles" and "the pore volume in which the polymer can penetrate" The product of the volume fraction of the phase pores K D " (ie K = ε ep ‧ K D ).

由於淨質量通量F係與去滌常數K具有正相關,其中,該孔隙度εp為一定值,因此,可根據各高分子之分子量大小求得各該高分子之去滌常數K。更詳言之,該高分子於管柱內的滯留時間tR係符合公式Ⅱ,其中,該高分子能夠滲入的孔隙體積佔該固定相顆粒孔隙之體積分率KD越大者,代表該高分子於該管柱中的滯留時間tR越長。Since the net mass flux F is positively correlated with the de-collection constant K, wherein the porosity ε p is a constant value, the depletion constant K of each of the polymers can be determined according to the molecular weight of each polymer. More detail, the polymer residence time in the column at t R lines meet Ⅱ formula, wherein the pore volume of the polymer can penetrate into account the particle porosity of the stationary phase volume fraction were greater the K D, representing the The longer the residence time t R of the polymer in the column.

如此,根據公式Ⅱ所示,選取三個以上不同分子量之高分子,並以與後續進行SMB分離之相同條件的固定相跟移動相進行層析(即習知的管柱層析法)測得各該分子量高分子之滯留時間tR,即可得知各去滌常數K的數值。Thus, according to Formula II, three or more polymers of different molecular weights are selected and subjected to chromatography (ie, conventional column chromatography) using the stationary phase and the mobile phase under the same conditions as the subsequent SMB separation. The retention time t R of each of the molecular weight polymers can be used to obtain the value of each decanting constant K.

舉例而言,本實施例係以SMB分離不同分子量之PEG,其中,本實施例之管柱層析法係選用與後續SMB所使用的固定相和移動相相同,以上述之管柱層析法操作至少五種不同分子量(PEG400、PEG1500、PEG3500、PEG8000及PEG20000)之PEG,並測量各分子量PEG的滯留時間tR,將該滯留時間tR帶入公式Ⅱ中,換算各分子量之去滌常數K,依序分別為0.538、0.4592、0.4093、0.3606及0.2975,並以該5種分子量PEG及其去滌常數K作出一自然對數迴歸方程式(公式Ⅲ),即可以該自然對數迴歸方程式換算其他分子量PEG之去滌常數K。For example, in the present embodiment, the PEG of different molecular weights is separated by SMB, wherein the column chromatography method of the present embodiment is the same as the stationary phase and the mobile phase used in the subsequent SMB, and the above-mentioned column chromatography is used. Operate PEG of at least five different molecular weights (PEG 400 , PEG 1500 , PEG 3500 , PEG 8000, and PEG 20000 ), and measure the residence time t R of each molecular weight PEG, and bring the residence time t R into Formula II, and convert each The molecular weight of the polyester constant K is 0.538, 0.4592, 0.4093, 0.3606 and 0.2975, respectively, and a natural logarithmic regression equation (Formula III) is obtained by using the five molecular weight PEGs and their removal constant K, that is, the natural logarithm The regression equation converts the polyester constant K of other molecular weight PEG.

由於各區段之淨質量通量F與流速比值m之設定條件係根據三角理論之推導而來,其推導原理在此恕不贅述,以下係就包含有一大分子量及一小分子量之高分子混合物(以下簡稱混合物)作為說明,其中,KS代表該小分子量高分子之去滌常數,KL代表該大分子量高分子之去滌常數,FS代表該小分子量高分子之淨質量通量,FL代表該大分子量高分子之淨質量通量。Since the conditions for setting the net mass flux F and the flow rate ratio m of each segment are derived from the trigonometric theory, the derivation principle will not be described here. The following series contain a mixture of a large molecular weight and a small molecular weight polymer. (hereinafter referred to as a mixture) as an illustration, wherein K S represents a de-collating constant of the small molecular weight polymer, K L represents a de-collating constant of the large-molecular-weight polymer, and F S represents a net mass flux of the small-molecular-weight polymer, F L represents the net mass flux of the large molecular weight polymer.

各區段之淨質量通量F與流速比值m之關係式請參照第2表,並請參照第3圖所示,該β區域之流速比值mβ為X軸,該γ區域之流速比值mγ為Y軸,依據該三角理論,該β及γ區域之mβ及mγ應落於由KL、KS所圈圍之斜線區塊(依圖面所示),則能夠於該第一出料口Oα及該第二出料口Oγ分別得到純度較高之大、小分子量高分子。For the relationship between the net mass flux F and the flow rate ratio m of each segment, refer to Table 2, and refer to Fig. 3, the flow rate ratio m β of the β region is the X axis, and the flow rate ratio m of the γ region γ is the Y-axis. According to the triangulation theory, m β and m γ of the β and γ regions should fall on the diagonal block surrounded by K L and K S (as shown in the figure), A discharge port O α and the second discharge port O γ respectively obtain large and small molecular weight polymers having high purity.

第2表:本實施例大、小分子量高分子於各區域之淨質量通量FLi、FSi(i為各區域代號),及各區域流速比值m與大、小分子量高分子之去滌常數KL、KS關係式Table 2: The net mass flux F Li , F Si (i is the code of each region) of the large and small molecular weight polymers in each region in this example, and the flow rate ratio m of each region and the removal of the large and small molecular weight polymers Constant K L , K S relation

當該高分子混合物自該進料口I進入該SMB後,該移動相帶動該混合物於該管柱之孔隙中移動,由於該小分子者之去滌常數KS大於該大分子者之去滌常數KL,因此,該小分子者於該SMB之移動距離係大於該大分子者之移動距離,該小分子者流出該管柱所需之時間大於該大分子者所需之時間。藉由該大、小分子者的移動距離差,以及配合該SMB之各區域的流速比值m,使移動距離長之小分子者移動至該α區域,而移動距離短之大分子者移動至該β或γ區域,如此,可分離該大、小分子高分子。After the polymer mixture enters the SMB from the feed port I, the mobile phase drives the mixture to move in the pores of the column, since the polyester molecule has a larger K S than the macromolecule The constant K L , therefore, the movement distance of the small molecule to the SMB is greater than the moving distance of the macromolecule, and the time required for the small molecule to flow out of the column is greater than the time required by the macromolecule. By moving the distance difference between the large and small molecules and the flow rate ratio m of each region of the SMB, the small molecule with a long moving distance is moved to the α region, and the macromolecule with a short moving distance moves to the The β or γ region, in this way, can separate the large and small molecular polymers.

舉例而言,當該小分子者移動至該α區域,該α區域之流速比值mα係大於該小分子量者之去滌常數KS,而該β及γ區域之流速比值mβ及mγ係介於該小分子量者之去滌常數KS及該大分子量者之去滌常數KL間,使該小分子量者於該α區域自該第一出料口Oα分離;而該大分子量者隨該移動相移動至該γ區域,該γ區域之流速比值nγ係大於該大分子量者之去滌常數KL,使該大分子量者於該γ區域之第二出料口Oγ分離。For example, when the small molecule moves to the α region, the flow rate ratio m α of the α region is greater than the depletion constant K S of the small molecular weight, and the flow velocity ratios m β and m γ of the β and γ regions are Between the de-collection constant K S of the small molecular weight and the de-collection constant K L of the large molecular weight, the small molecular weight is separated from the first discharge port O α in the α-region; and the large molecular weight Moving to the gamma region with the moving phase, the flow rate ratio n γ of the γ region is greater than the depletion constant K L of the large molecular weight, so that the large molecular weight is separated from the second discharge port O γ of the γ region .

為證實本發明之以模擬移動床分離不同分子量高分子之方法,係能夠用以分離不同分子量之高分子,以下進行不同分子量PEG混合物之較佳實施例說明之。To demonstrate the method of the present invention for separating mobile polymers of different molecular weights by simulating moving beds, it is possible to separate polymers of different molecular weights, and the following is a description of preferred embodiments of PEG mixtures of different molecular weights.

第一實施例:分離分子量8000及400之PEG混合物First Example: Separation of PEG mixtures of molecular weights 8000 and 400

本實施例係以一SMB對包含有一分子量為8000及400之高分子混合物(分別簡稱為PEG8000及PEG400)進行純化。本實施例係用孔徑小於10~100 nm之GMPW管柱(TOSOH)做為SMB之固定相(管徑7.5 mm,管柱長度30 cm),其孔隙度為0.3643,該SMB之移動相為純水,該PEG8000之進料濃度為252.16 ppm,該PEG400之進料濃度為288.93 ppm。本實施例之SMB係以每二支GMPW管柱為一區域,共有三區域α、β及γ,並於各區域之間設置一HPLC泵(Hitachi,L-2130)以控制各區域之流速比值m。In this example, a SMB pair was used to purify a polymer mixture having a molecular weight of 8000 and 400 (referred to as PEG 8000 and PEG 400, respectively ). In this embodiment, a GMPW column (TOSOH) having a pore diameter of less than 10 to 100 nm is used as a stationary phase of SMB (tube diameter: 7.5 mm, column length: 30 cm), and its porosity is 0.3643. The mobile phase of the SMB is pure. For water, the PEG 8000 has a feed concentration of 252.16 ppm and the PEG 400 has a feed concentration of 288.93 ppm. The SMB of the present embodiment has two regions of α, β, and γ for each of the two GMPW columns, and an HPLC pump (Hitachi, L-2130) is disposed between the regions to control the flow rate ratio of each region. m.

此外,請參照第3表所示,係本實施例不同分子量之PEG,先由管柱層析法得到各分子量PEG之tR,代入該公式Ⅱ後得到之去滌常數K,並將各不同分子量之PEG及其去滌常數K取自然對數迴歸而得到公式Ⅲ之自然對數迴歸方程式。In addition, please refer to Table 3, which is a PEG of different molecular weight in this example, first obtain the t R of each molecular weight PEG by column chromatography, and obtain the decontamination constant K obtained by substituting the formula II, and will be different. The molecular weight PEG and its decontamination constant K are subjected to natural logarithmic regression to obtain the natural logarithmic regression equation of Formula III.

根據三角理論,本實施例之mβ較佳為0.362~0.423及mγ為0.470~0.537,係介於該KL及KS之間。在操作實例上,則係以該進料口I之切換時間tsw以控制各區域之流速比值m。According to the triangulation theory, m β of the present embodiment is preferably 0.362 to 0.423 and m γ is 0.470 to 0.537, which is between the K L and K S . In the example of operation, the switching time t sw of the feed port I is used to control the flow rate ratio m of each zone.

請參照第4表,該混合物係自該進料口I注入該SMB,並使該mβ及mγ符合上述條件,則該PEG400係移動至該α區域並於該第一出料口Oα純化出來,而該PEG8000係移動至該β及γ區域並於該第二出料口Oγ純化出來,分別計算該PEG8000及PEG400之純度,若純度大於95%者,則認定該純化條件係能夠提高PEG8000及PEG400之純度。Referring to the fourth table, the mixture is injected into the SMB from the feed port I, and the m β and m γ meet the above conditions, then the PEG 400 moves to the α region and is at the first discharge port O. α is purified, and the PEG 8000 is moved to the β and γ regions and purified at the second outlet O γ to calculate the purity of the PEG 8000 and PEG 400 respectively. If the purity is greater than 95%, the Purification conditions are capable of increasing the purity of PEG 8000 and PEG 400 .

請參照第4圖所示,係將本實施例之純化條件繪製成一符合三角理論之純化條件,該第1b及1c組之切換時間tsw係落於該三角理論之斜線部份,因此能夠於該第一出料口Oα得到高純度的小分子量者(PEG400),於該第二出料口Oγ得到高純度的大分子量者(PEG8000)。Referring to FIG. 4, the purification conditions of the present embodiment are plotted as a purification condition in accordance with the triangulation theory, and the switching time t sw of the 1b and 1c groups falls within the oblique line portion of the triangular theory, so that The first discharge port O α obtains a high-purity small molecular weight (PEG 400 ), and a high-purity large molecular weight (PEG 8000 ) is obtained at the second discharge port O γ .

第二實施例:分離分子量1500及20000之PEG混合物Second embodiment: separation of PEG mixture having a molecular weight of 1500 and 20000

該第二實施例所使用之SMB與第一實施例相同,以該SMB對包含有一分子量為20000及1500之高分子混合物(分別簡稱為PEG20000及PEG1500)進行純化。請參照第3表係該PEG20000及PEG1500之去滌常數K,該PEG20000之進料濃度為1866.5 ppm,該PEG1500之進料濃度為1674.9 ppm。根據三角理論,本實施例之mβ較佳為0.300~0.340及mγ為0.412~0.458,係介於該KL及KS之間。在操作實例上,則係以該進料口I之切換時間tsw控制各區域之流速比值m。The SMB used in the second embodiment was the same as in the first embodiment, and the SMB pair was purified by including a polymer mixture having a molecular weight of 20,000 and 1500 (referred to as PEG 20000 and PEG 1500, respectively ). Please refer to Table 3 for the decontamination constant K of the PEG 20000 and PEG 1500. The feed concentration of the PEG 20000 is 1866.5 ppm, and the feed concentration of the PEG 1500 is 1674.9 ppm. According to the triangulation theory, m β of the present embodiment is preferably 0.300 to 0.340 and m γ is 0.412 to 0.458, which is between the K L and K S . In the example of operation, the flow rate ratio m of each zone is controlled by the switching time t sw of the feed port I.

請參照第5表,該混合物係自該進料口I注入該SMB,並使該mβ及mγ符合上述條件,則該PEG1500係移動至該α區域並於該第一出料口Oα純化出來,而該PEG20000係移動至該β及γ區域並於該第二出料口Oγ純化出來,分別計算該PEG8000及PEG400之純度,若純度大於95%者,則認定該純化條件係能夠提高PEG8000及PEG400之純度。Referring to the fifth table, the mixture is injected into the SMB from the feed port I, and the m β and m γ meet the above conditions, then the PEG 1500 moves to the α region and is at the first discharge port O. α is purified, and the PEG 20000 is moved to the β and γ regions and purified at the second discharge port O γ to calculate the purity of the PEG 8000 and PEG 400 respectively. If the purity is greater than 95%, the Purification conditions are capable of increasing the purity of PEG 8000 and PEG 400 .

請參照第5圖所示,係將本實施例之純化條件繪製成一符合三角理論之純化條件,該第1b及1c組之切換時間tsw係落於該三角理論之斜線部份,因此能夠於該第一出料口Oα得到高純度的小分子量者(PEG1500),於該第二出料口Oγ得到高純度的大分子量者(PEG20000)。Referring to FIG. 5, the purification conditions of the present embodiment are plotted as a purification condition in accordance with the triangulation theory, and the switching time t sw of the 1b and 1c groups falls within the oblique line portion of the triangular theory, so that The first discharge port O α obtains a high-purity small molecular weight (PEG 1500 ), and a high-purity large molecular weight (PEG 20000 ) is obtained at the second discharge port O γ .

由上述可知,本發明之以模擬移動床分離不同分子量高分子之方法能夠應用在分離不同分子量之PEG,且能夠藉由調整各區域之流速比值m,與各不同分子量高分子之去滌常數K的關係,以分離所欲分子量之PEG。此外,本發明之以模擬移動床分離不同分子量高分子之方法亦能用以分離其他高分子,例如聚乳酸、聚乙烯吡咯酮或多醣等。It can be seen from the above that the method for separating different molecular weight polymers by simulating moving bed can be applied to separating PEGs of different molecular weights, and by adjusting the flow rate ratio m of each region, and the polyester removal constant K of different molecular weight polymers. The relationship to separate the desired molecular weight of the PEG. In addition, the method of the present invention for separating mobile polymers of different molecular weights by simulating moving beds can also be used to separate other polymers, such as polylactic acid, polyvinylpyrrolidone or polysaccharides.

本發明之以模擬移動床分離不同分子量高分子之方法,能夠提高該高分子之純度,具有提高該高分子之經濟價值之功效。The method for separating different molecular weight polymers by simulating moving bed in the invention can improve the purity of the polymer and has the effect of improving the economic value of the polymer.

本發明之以模擬移動床分離不同分子量高分子之方法,能夠以連續式進料純化特定分子量的高分子,具有提高該高分子的純化產量之功效。The method for separating different molecular weight polymers by simulating moving bed in the invention can purify a polymer of a specific molecular weight by continuous feeding, and has the effect of improving the purification yield of the polymer.

雖然本發明已利用上述較佳實施例揭示,然其並非用以限定本發明,任何熟習此技藝者在不脫離本發明之精神和範圍之內,相對上述實施例進行各種更動與修改仍屬本發明所保護之技術範疇,因此本發明之保護範圍當視後附之申請專利範圍所界定者為準。While the invention has been described in connection with the preferred embodiments described above, it is not intended to limit the scope of the invention. The technical scope of the invention is protected, and therefore the scope of the invention is defined by the scope of the appended claims.

[本發明][this invention]

c...管柱c. . . Column

α...α區域α. . . Alpha region

β...β區域β. . . Beta region

γ...γ區域γ. . . Gamma region

Oα...第一出料口O α . . . First discharge port

I...進料口I. . . Inlet

Oγ...第二出料口O γ . . . Second discharge port

[習用][customary]

α...α區域α. . . Alpha region

β...β區域β. . . Beta region

γ...γ區域γ. . . Gamma region

δ...δ區域δ. . . Delta region

Oα...第一出料口O α . . . First discharge port

Iγ...進料口I γ . . . Inlet

Oγ...第二出料口O γ . . . Second discharge port

第1圖:習用模擬移動床管柱配置示意圖。Figure 1: Schematic diagram of the configuration of a simulated simulated moving bed column.

第2圖:本發明之三區域SMB管柱配置示意圖。Figure 2: Schematic diagram of the three-zone SMB pipe column configuration of the present invention.

第3圖:三角理論之純化條件示意圖。Figure 3: Schematic diagram of the purification conditions of the triangular theory.

第4圖:第一實施例符合三角理論之純化條件示意圖。Fig. 4 is a schematic view showing the purification conditions of the first embodiment in accordance with the triangulation theory.

第5圖:第二實施例符合三角理論之純化條件示意圖。Fig. 5 is a schematic view showing the purification conditions of the second embodiment in accordance with the triangulation theory.

Claims (7)

一種以模擬移動床分離不同分子量高分子之方法,包含:(a) 提供一包含至少三區域之模擬移動床係由一移動相及一固定相所組成,其中,該固定相顆粒內部係具有孔隙,該三區域依序為α、β及γ區域,分別具有一流速比值mα、mβ及mγ,該移動相於該模擬移動床中係朝同一方向流經該三區域之間,該固定相係相對於該移動相朝反方向模擬移動;(b) 提供具有至少二不同大、小分子量之高分子混合物注入該模擬移動床中,該大、小分子量高分子分別具有一去滌常數KL及KS,該去滌常數KL大於該去滌常數KS,該固定相之孔隙係用以提供該大、小分子量高分子不同的移動距離;(c) 該α區域之流速比值mα應大於KL及KS,該β及γ區域之流速比值mβ及mγ應介於KL及KS之間,使該小分子量者移動至該α區域,該大分子量者移動至該β及γ區域,以分離該大及小分子量之高分子。A method for separating different molecular weight polymers by a simulated moving bed, comprising: (a) providing a simulated moving bed system comprising at least three regions consisting of a mobile phase and a stationary phase, wherein the stationary phase particles have pores inside The three regions are sequentially α, β, and γ regions respectively having flow velocity ratios m α , m β , and m γ , and the mobile phase flows between the three regions in the same direction in the simulated moving bed. The stationary phase system simulates moving in the opposite direction with respect to the moving phase; (b) providing a polymer mixture having at least two different large and small molecular weights into the simulated moving bed, the large and small molecular weight polymers respectively having a decontamination constant K L and K S , the de-collection constant K L is greater than the de-collection constant K S , the pores of the stationary phase are used to provide different moving distances of the large and small molecular weight polymers; (c) the flow rate ratio of the α-region m α should be greater than K L and K S , and the flow rate ratios m β and m γ of the β and γ regions should be between K L and K S to move the small molecular weight to the α region, and the large molecular weight move To the β and γ regions to separate the large and Polymer molecular weight. 如申請專利範圍第1項所述之以模擬移動床分離不同分子量高分子之方法,其中,該固定相顆粒內部具有一孔隙度εp,該高分子能夠滲入該固定相顆粒的孔隙體積具有一體積分率KD,該去滌常數K係指該孔隙度εp與該體積分率KD的乘積。The method for separating different molecular weight polymers by simulating a moving bed according to the first aspect of the patent application, wherein the stationary phase particles have a porosity ε p inside, and the polymer can penetrate into the pore volume of the stationary phase particles to be integrated. The integration rate K D , which is the product of the porosity ε p and the volume fraction K D . 如申請專利範圍第1項所述之以模擬移動床分離不同分子量高分子之方法,其中,該α區域之後端設有一第一出料口Oα,該γ區域之後端設有一第二出料口Oγ,一進料口I設於該β及γ區域之間。The method for separating different molecular weight polymers by simulating a moving bed according to the first aspect of the patent application, wherein a rear end of the α region is provided with a first discharge port O α , and a rear end of the γ region is provided with a second discharge material. Port O γ , a feed port I is disposed between the β and γ regions. 如申請專利範圍第3項所述之以模擬移動床分離不同分子量高分子之方法,其中,該小分子量者自該第一出料口Oα流出,該大分子量者自該第二出料口Oγ流出。The method for separating different molecular weight polymers by simulating a moving bed, as described in claim 3, wherein the small molecular weight is discharged from the first discharge port O α , and the large molecular weight is from the second discharge port. O γ flows out. 如申請專利範圍第1項所述之以模擬移動床分離不同分子量高分子之方法,其中,各該區域包含至少一管柱,該管柱內填充一顆粒內部具有孔隙之固定相。A method for separating different molecular weight polymers by simulating a moving bed as described in claim 1, wherein each of the regions comprises at least one column filled with a stationary phase having pores inside the particles. 如申請專利範圍第1項所述之以模擬移動床分離不同分子量高分子之方法,其中,該高分子為聚乙二醇、聚乳酸、聚乙烯吡咯酮或多醣。A method for separating a polymer of a different molecular weight by a simulated moving bed as described in the first aspect of the patent application, wherein the polymer is polyethylene glycol, polylactic acid, polyvinylpyrrolidone or a polysaccharide. 如申請專利範圍第1項所述之以模擬移動床分離不同分子量高分子之方法,其中,該高分子均勻分散於該移動相中。A method for separating a polymer of a different molecular weight by a simulated moving bed as described in the first aspect of the patent application, wherein the polymer is uniformly dispersed in the mobile phase.
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