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Insoluble fraction

To produce highly purified phosphatidylcholine there are two industrial processes batch and continuous. In the batch process for producing phosphatidylcholine fractions with 70—96% PC (Pig. 4) (14,15) deoiled lecithin is blended at 30°C with 30 wt % ethanol, 90 vol %, eventually in the presence of a solubiHzer (for example, mono-, di-, or triglycerides). The ethanol-insoluble fraction is separated and dried. The ethanol-soluble fraction is mixed with aluminum oxide 1 1 and stirred for approximately one hour. After separation, the phosphatidylcholine fraction is concentrated, dried, and packed. [Pg.101]

Pig. 4. Batch process for producing phosphatidylcholine fractions. 1, Ethanol storage tank 2, deoiled lecithin 3, solubiHzer 4, blender 5, film-type evaporator 6, ethanol-insoluble fraction 7, ethanol-soluble fraction 8, aluminum oxide 9, mixer 10, decanter 11, dryer 12, aluminum oxide removal 13, phosphatidylcholine solution 14, circulating evaporator 15, cooler 16, dryer and 17, phosphatidylcholine. [Pg.101]

In the continuous process for producing phosphatidylcholine fractions with 70—96% PC at a capacity of 600 t/yr (Pig. 5) (16), lecithin is continuously extracted with ethanol at 80°C. After separation the ethanol-insoluble fraction is separated. The ethanol-soluble fraction mns into a chromatography column and is eluted with ethanol at 100°C. The phosphatidylcholine solution is concentrated and dried. The pure phosphatidylcholine is separated as dry sticky material. This material can be granulated (17). [Pg.101]

Fig. 5. Continuous process for producing phosphatidylcholine. 1, Lecithin 2, ethanol 3, blender 4, diffuser 5, thin-type evaporator 6, ethanol-insoluble fraction 7, heat exchanger 8, chromatography column (Si02) 9, prestream 10 and 12, phosphatidylcholine solution 11, circulating evaporator 13, dryer ... Fig. 5. Continuous process for producing phosphatidylcholine. 1, Lecithin 2, ethanol 3, blender 4, diffuser 5, thin-type evaporator 6, ethanol-insoluble fraction 7, heat exchanger 8, chromatography column (Si02) 9, prestream 10 and 12, phosphatidylcholine solution 11, circulating evaporator 13, dryer ...
The standard methods (26) of analysis for commercial lecithin, as embodied in the Official and Tentative Methods of the American Oil Chemists Society (AOCS), generally are used in the technical evaluation of lecithin (27). Eor example, the AOCS Ja 4-46 method determines the acetone-insoluble matter under the conditions of the test, free from sand, meal, and other petroleum ether-insoluble material. The phosphoHpids are included in the acetone-insoluble fraction. The substances insoluble in hexane are determined by method AOCS Ja 3-87. [Pg.103]

The lac resin is associated with two lac dyes, lac wax and an odiferous substance, and these materials may be present to a variable extent in shellac. The resin itself appears to be a polycondensate of aldehydic and hydroxy acids either as lactides or inter-esters. The resin constituents can be placed into two groups, an ether-soluble fraction (25% of the total) with an acid value of 100 and molecular weight of about 550, and an insoluble fraction with an acid value of 55 and a molecular weight of about 2000. [Pg.868]

This is present to the extent of about 30-40% and is found in both the ether-soluble and ether-insoluble fractions. Both free hydroxyl and free carboxyl groups are to be found in the resin. [Pg.868]

The starting material is moderately soluble in hot chloroform, while 2-hydroxyisophthalic acid is quite insoluble. Fractional crystallization from water, an alternative method suggested for the separation of starting material, has been found by the submitters to be unsuccessful. [Pg.51]

Alcohol was then distilled off, until the temperature reached 100°C. 1,706.6 g of distillate was collected. (Theory 1,430 g.) This alcohol was poured into four times its volume of water and an insoluble oil separated (457 g). The insoluble fraction was added back to the copoly-... [Pg.501]

To a stirred — 78 C solution of 5.85 mL (62.5 mmol) of 3-methoxy-l-prnpene in 25 mL of THf- are added 43.1 mL (50 mmol) of 1.16 M. vcc-butyllithium in cyclohexane over a 20-25 min period. The mixture is stirred at — 78 °C for an additional 10 min, and diisopinocampheyl(methoxy)borane [50 mmol prepared from (+ )-a-pinene] in 50 mL of THF is added. This mixture is stirred for 1 h, then 8.17 mL (66.5 mmol) of boron trifluoride diethyl etherate complex are added dropwise to give a solution of diisopiuocampheyl[(Z)-3-inethoxy-2-propenyl]borane. Immediately. 2.8 mL (50 mmol) of acetaldehyde are added and the mixture is stirred for 3 h at — 78 rC and then allowed to warm to r.t. All volatile components are removed in vacuo, then the residue is dissolved in pentane. The insoluble fraction is washed with additional pentane. The combined pentane extracts are cooled to 0 JC and treated with 3.0 mL (50 mmol) of ethanolamine. The mixture is stirred for 2 h at 0rC and is then seeded with a crystal of the diisopinocampheylborane-ethanolaminc complex. The resulting crystals arc filtered and washed with cold pentane. The filtrate is carefully distilled yield 5.6 g (57%) d.r. (synjanti) >99 1 (2/ ,37 )-isomer 90% ee bp 119-120 C/745 Torr. [Pg.290]

Following the same procedures described in the above-mentioned study, additional extractive data were obtained for the epoxy phenolic enamel that was irradiated at 4.7-7.1 Mrad at 25 and — 30 °C in the presence of distilled water, 3% acetic acid, and n-heptane. The changes in the amount of extractives resulting from the irradiation treatment are shown in Table IX. In the case of the water and acetic acid extractives, there was no change in either the chloroform-soluble fractions or the chloroform-insoluble fractions. In the case of the n-heptane extractives, the amount of extractives decreased when the irradiation temperature was reduced from +25 to — 30°C. Infrared spectra of the chloroform-soluble residues from the water and acetic acid extractives of the unirradiated and irradiated enamel were identical to the chloroform-soluble residues from the solvent blanks. In other words, the epoxy phenolic... [Pg.39]

Speciation of plutonium leached from the glass cubes is shown in Figure 1. The first bar represents the total amount of insoluble plutonium and is the summation of suspended plutonium (the difference between the values for filtered and unfiltered waters) and sorbed plutonium—viz., the amount removed from the cubes by a 0.1 M perchloric acid wash, normalized to the volumes of leachant solutions so that it is comparable to the other values in the graphs. For simplicity, the insoluble fractions are combined in one bar, whereas the various oxidation states in the soluble fraction are represented by separate bars. It should be noted that the ordinate scale varies among the graphs. [Pg.337]

Evidence of chemical interaction between the mbbers and compatibUizers was demonstrated by extracting the blends with chloroform at room temperamre and examining both soluble and insoluble fractions with Fourier transform infrared (ETIR) spectrometry. The weight of the insoluble fraction of the compatibilized melt blend was more than that in the uncompatibilized blend indicating the formation of (EP-g-MA)-g-CR due to reaction between MA and allylic chlorine of CR. The compounds containing epoxidized EPDM additive were examined by both optical and... [Pg.309]

The HMR/fractionatlon approach gives very good results When applied to ethylene-propylene copolymer fractions reported by Abls, et. al. (19) These authors extracted sample 5 (In Table VII) with hexane to get soluble and Insoluble fractions (5a and 5b), and with ether to get soluble and insoluble fractions (5c and 5d). The hexane set (5a and 5b) and the ether set (5c and 5d) can be separately analyzed by the HIXCO.TRIADX program. The results are shown In Table VIII. In the 2-state (B/B) model, we have 4 parameters and 12 values to fit to HMR data of pairwise fractions. In the 3-state (B/B/B) model, we have 7 parameters and 12 values to fit. Thus, the use of pairwise fractions Is absolutely essential for 3-state analysis. [Pg.184]

Figure 2. PemB cellular localisation. (A) Fractionation of E. chrysanthemi cells by spheroplasting. Lane 1, culture supernatant lane 2, total cell lysate lane 3, periplasmic fraction lane 4, crude membrane fraction lane 5, cytoplasmic fraction. (B) Detergent extraction of PemB from E. chrysanthemi A837 cell envelopes. Lane 1 crude envelope fraction lane 2 Triton-soluble fraction lane 3 Triton-insoluble fraction lane 4 Sarkosyl-soluble fraction lane 5 Sarkosyl-insoluble fraction. Figure 2. PemB cellular localisation. (A) Fractionation of E. chrysanthemi cells by spheroplasting. Lane 1, culture supernatant lane 2, total cell lysate lane 3, periplasmic fraction lane 4, crude membrane fraction lane 5, cytoplasmic fraction. (B) Detergent extraction of PemB from E. chrysanthemi A837 cell envelopes. Lane 1 crude envelope fraction lane 2 Triton-soluble fraction lane 3 Triton-insoluble fraction lane 4 Sarkosyl-soluble fraction lane 5 Sarkosyl-insoluble fraction.
The chromatogram of the commercial soya lecithin as shown in Figure 4 suggests a number of components and all subsequent work was done with the ethanol-soluble fraction, i.e., phosphatidyl choline, or the ethanol-insoluble fraction, comprised primarily of other phosphatides. [Pg.230]

The dependence of Mp" on sample size for the ethanol-soluble fraction is sumnarized by the solid lines in Figure 7. For both column sets, the apparent MW of the principal peak increases by nearly an order of magnitude as the mass of the injected sample is increased from one to four mg. In contrast, the ethanol-insoluble fraction exhibits a rather narrow chromatogram... [Pg.230]

Figure 7. Effect of sample size on apparent molecular weight for soya lecithin phosphatide fractions (conditions same as for Figures 5 and 6 (O) ethanol-soluble fraction (phosphatidyl choline), oligomer GPC (%) ethanol-soluble fraction (phosphatidyl choline), "main column (l ) ethanol-insoluble fraction (other phos-p hat ides), "oligomer GPC (A) ethanol-insoluble fraction (other phosphatides),... Figure 7. Effect of sample size on apparent molecular weight for soya lecithin phosphatide fractions (conditions same as for Figures 5 and 6 (O) ethanol-soluble fraction (phosphatidyl choline), oligomer GPC (%) ethanol-soluble fraction (phosphatidyl choline), "main column (l ) ethanol-insoluble fraction (other phos-p hat ides), "oligomer GPC (A) ethanol-insoluble fraction (other phosphatides),...
Texturization is not measured directly but is inferred from the degree of denaturation or decrease of solubility of proteins. The quantities are determined by the difference in rates of moisture uptake between the native protein and the texturized protein (Kilara, 1984), or by a dyebinding assay (Bradford, 1976). Protein denaturation may be measured by determining changes in heat capacity, but it is more practical to measure the amount of insoluble fractions and differences in solubility after physical treatment (Kilara, 1984). The different rates of water absorption are presumed to relate to the degree of texturization as texturized proteins absorb water at different rates. The insolubility test for denaturation is therefore sometimes used as substitute for direct measurement of texturization. Protein solubility is affected by surface hydrophobicity, which is directly related to the extent of protein-protein interactions, an intrinsic property of the denatured state of the proteins (Damodaran, 1989 Vojdani, 1996). [Pg.182]

Although PFE lacks a proven total concept for in-polymer analysis, as in the case of closed-vessel MAE (though limited to polyolefins), a framework for method development and optimisation is now available which is expected to be an excellent guide for a wide variety of applications, including non-polyolefinic matrices. Already, reported results refer to HDPE, LDPE, LLDPE, PP, PA6, PA6.6, PET, PBT, PMMA, PS, PVC, ABS, styrene-butadiene rubbers, while others may be added, such as the determination of oil in EPDM, the quantification of the water-insoluble fraction in nylon, as well as the determination of the isotacticity of polypropylene and of heptane insolubles. Thus PFE seems to cover a much broader polymer matrix range than MAE and appears to be quite suitable for R D samples. [Pg.123]

CYCLOHEXANE EXTRACTION. A 5-6g portion of the product was cut into small pieces and stirred in 250 ml cyclohexane at room temperature for 60 hr. The insoluble fraction was separated by filtering the solution through cheesecloth. The cyclohexane-soluble fraction was recovered by distilling the solvent in vacuo and the polymer was dried in vacuo at 40 C for 24 hr. [Pg.439]

The presence of 0.25-0.5 wt-% DCP at 180°C resulted in the formation of about 20% of a cyclohexane-insoluble fraction. The presence of 5 wt-% MAH (based on EPR) increased the amount of cyclohexane—insoluble gel, whose concentration decreased from 65% to 27% as the DCP content increased from 0.25 to 1.0 wt-% (based on EPR), respectively. The cyclohexane-soluble polymer contained about 1 wt-%... [Pg.439]

With AICI3 and Ph3C+ SbClg as inititors, unsatisfactory results were obtained. With AICI3, the system turned black immediately on transferring the initiator into the polymerization tube, and a black precipitate was observed. After 24 h, on pouring the contents of the tube into methanol, no insoluble fraction was observed except the black residue observed earlier. [Pg.452]

Now and then, projectiles from outer space cause excitement and surprises, as in January 2000, when a meteorite impacted the frozen surface of Lake Targish in Canada. It was a new type of C-chondrite with a carbon concentration of 4-5%, and probably came from a D-type asteroid (Hiroi et al., 2001). More exact analysis of the Targish meteorite showed the presence of a series of mono- and dicarboxylic acids as well as aliphatic and aromatic hydrocarbons (Pizzarello et al., 2001). Aromatic compounds and fullerenes were detected in the insoluble fraction from the extraction this contained planetary helium and argon, i.e., the 3He/36Ar ratio was... [Pg.70]

The polymers of 1,4-hexadienes have unusually wide molecular weight distributions. This is illustrated by the gel permeation chromatogram of the methanol-insoluble fraction of poly(5-methyl-1,4-hexadiene) in tetrahydrofuran (Figure 9). The polymer was obtained in 82% conversion and had an inherent viscosity of 2.1 dl./g. in toluene at 25°C. [Pg.183]

The products obtained in IBVE-aMeSt block copolymerization were fractionated with 2-propanol, a good solvent for poly(IBVE) and a nonsolvent for poly(aMeSt). Table II shows molecular weights and compositions of typical blocking products. Figure 7 illustrates examples of 1H-NMR spectra of the 2-propanol-soluble and -insoluble fractions. [Pg.224]

H-NMR spectra of the 2-propanol-insoluble fractions (e.g., Figure 7a) exhibited signals due to both aMeSt and IBVE units (aMeSt, 0.1 and 6.9 ppm IBVE, 0.9 and 2.8-3.6 ppm), i.e., the spectra indicate the presence of both poly(aMeSt) and poly-(IBVE) segments in these fractions. As 2-propanol-insoluble fractions cannot contain homopoly(IBVE), the existence of IBVE... [Pg.224]

Figure 7. IH-NMR spectra of the 2-propanol-soluble and -insoluble fractions of IBVE-cMeSt block copolymerization products obtained in experiment A, Table II. Figure 7. IH-NMR spectra of the 2-propanol-soluble and -insoluble fractions of IBVE-cMeSt block copolymerization products obtained in experiment A, Table II.
All samples were digested with trypsin and analyzed by cIEF in the first dimension followed by LC-MS/MS as described above. Samples were analyzed in duplicate. Sequence searching was performed using OMSSA. Analysis of the soluble fraction yielded a total of 2856 identified proteins, while the insoluble fraction yielded 3227 proteins. Combined, the fresh-frozen sample yielded 3902 protein identifications. The FFPE portion yielded 2845 protein identifications from 14,178 distinct tryptic peptide sequences, on a par with the fresh-frozen soluble fraction. Combining all identifications gave 4145 proteins. While, the soluble fraction and the FFPE extraction yielded similar numbers of protein identification, both found 25% of their respective protein set uniquely (Fig. 20.4). [Pg.351]


See other pages where Insoluble fraction is mentioned: [Pg.99]    [Pg.102]    [Pg.498]    [Pg.346]    [Pg.6]    [Pg.503]    [Pg.32]    [Pg.56]    [Pg.309]    [Pg.241]    [Pg.592]    [Pg.236]    [Pg.154]    [Pg.251]    [Pg.252]    [Pg.262]    [Pg.265]    [Pg.224]    [Pg.350]   
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Cold-insoluble fraction

Heptane soluble and -insoluble fractions

Insoluble fractions, separation

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