COSMOSIL C18-OPN
Reversed phase chromatography / Open colomun chromatography
Open column chromatography is an excellent and easy technique for large scale preparation and purification at low cost. Reversed phase C18 packing materials are used but restricted to about 30-50% water in the mobile phase. The COSMOSIL C18-OPN is a new "Water-Wet" C18 packing material developed for Reversed Phase Open Column Chromatography. The C18-OPN material can be used in 100% aqueous eluents.
C18 packing materials in 100% water Normal C18 materials float on water
Surface of the C18-OPN Gel
The external surface of the C18-OPN gel is coated with hydrophilic groups.
Influence of Particle Size
Effect of Particle Size
| Effect of particle size | ||||||||
|---|---|---|---|---|---|---|---|---|
| Particle (um) | Flow rate (ml/min) | Theoretical plate number | Rs | Separation time(min) | Consumption of solvent (ml) | |||
| TB | TP | CF | Rs | TB/TP | TP/CF | |||
| 75 | 0.25 | 400 | 390 | 340 | 1.00 | 1.74 | 240 | 60 |
| 140 | 0.60 | 300 | 280 | 260 | 0.90 | 1.40 | 100 | 60 |
Separation of Hydrophilic Compounds in Aqueous Solution
In reversed phase chromatography, hydrophilic compounds such as Theobromine and Theophylline could be separated under low concentration of organic solvent. The figure shows they are clearly separated by reversed open column chromatography with 70% of water.
Separation of p-Cresol and p-Ethylphenol by normal and reversed phase mode
Since the structural difference between p-Cresol and p-Ethylphenol is only one methyene group. It is difficult to separate such samples under normal phase condition. On the other hand, the samples are clearly separated under reversed phase condition with COSMOSIL C18-OPN packing material.
Reference
- Nakayama, Hideyuki, et al. "Glucose esters of caffeic acid from Allium macrostemon Bunge." Japanese Journal of Food Chemistry and Safety 27.1 (2020): 28-32.
- Ki, Dae-Won, et al. "New cytotoxic polyacetylene amides from the Egyptian marine sponge Siphonochalina siphonella." Fitoterapia 142 (2020): 104511.
- Miyazaki, Sho, et al. "Identification of a cyanidin-3-O-β-galactoside in gall tissue induced by midges on Japanese beech (Fagus crenata Blume)." Bioscience, Biotechnology, and Biochemistry 84.4 (2020): 797-799.
- Ho, Duc Viet, et al. "Three new steroidal saponins from Aspidistra letreae plants and their cytotoxic activities." Journal of Natural Medicines (2020): 1-8.
- Wong, Chin Piow, et al. "Three new quassinoids isolated from the wood of Picrasma javanica and their anti-Vpr activities." Journal of Natural Medicines (2020): 1-8.
- Mori-Yasumoto, Kanami, et al. "Leishmanicidal phenolic compounds derived from Dalbergia cultrata." Natural Product Research (2020): 1-9.
- Ito, Masahiro, et al. "Isolation and identification of the antimicrobial substance included in tempeh using Rhizopus stolonifer NBRC 30816 for fermentation." International Journal of Food Microbiology (2020): 108645.
- Nakashima, Ken-ichi, et al. "Absolute configurations of talaromycones A and B, α-diversonolic ester, and aspergillusone B from endophytic Talaromyces sp. ECN211." Beilstein Journal of Organic Chemistry 16.1 (2020): 290-296.
- Katsutani, Kazuma, et al. "Eudesmane-type sesquiterpene glycosides: sonneratiosides A–E and eudesmol β-d-glucopyranoside from the leaves of Sonneratia alba." Journal of Natural Medicines (2020): 1-8.
- Iguchi, Tomoki, et al. "Steroidal glycosides from the bulbs of Lilium speciosum." Phytochemistry Letters 37 (2020): 21-28.
Ordering Information
| Product | Cat.No. | PKG Size | Price(US$) | |
|---|---|---|---|---|
| COSMOSIL 75C18-OPN | 37842-66 | 100G | 242.00 | Buy |
| COSMOSIL 75C18-OPN | 37842-95 | 500G | 924.00 | Buy |
| COSMOSIL 75C18-OPN | 37842-11 | 1KG | 1,628.00 | Buy |
| COSMOSIL 140C18-OPN | 37878-16 | 100G | 242.00 | Buy |
| COSMOSIL 140C18-OPN | 37878-45 | 500G | 924.00 | Buy |
| COSMOSIL 140C18-OPN | 37878-61 | 1KG | 1,796.00 | Buy |