Rapid Kinetics and Spectroscopy.
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- RK-Spectro Technical Note 90 : How to use the MOS500 capillary holder
- RK-Spectro Technical Note 89 : CD measurements in NIR region
- RK-Spectro Technical Note 88 : μSFM - Refolding of lysozyme using a 50μl stock solution and MOS-200
- RK-Spectro Technical Note 87: μSFM - Absorbance kinetics using a 200μl stock solution and MOS-200
- RK-Spectro Technical Note 86: MOS-500 - Installation of MCD accessory and example of MCD spectrum
- RK-Spectro Technical Note 85: SFM-X000 used in anaerobic conditions_ loading of instrument
- RK-Spectro Technical Note 84: Single wavelength kinetic using MOS-500 in anisotropy mode
- RK-Spectro Technical Note 83: Spectral recording MOS-500 in anisotropy mode
- RK-Spectro Technical Note 82: Steady state spectral recording in absorbance mode using MOS-500
- RK-Spectro Technical Note 81: Single wavelength kinetic using MOS-500 in absorbance mode
- RK-Spectro Technical Note 80: Single wavelength kinetic using MOS-500 in fluorescence mode
- RK-Spectro Technical Note 79: Single wavelength kinetics experiment using MOS-500 in CD mode
- RK-Spectro Technical Note 78: Thermal denaturation of lysozyme in spectra mode using single peltier and MOS-500
- RK-Spectro Technical Note 77: Excitation fluorescence scan using MOS-500
- RK-Spectro Technical Note 76: Single wavelength kinetics experiment using MOS200 in fluorescence mode
- RK-Spectro Technical Note 75: Thermal denaturation of cytochrome-c using TCU-250 and MOS-500
- RK-Spectro Technical Note 74: Spectral recording using MOS-500 in Circular Dichroism mode
- RK-Spectro Technical Note 73: Determination of your experimental dead time in fluorescence mode using μFC-08 and SFM-4000/S
- RK-Spectro Technical Note 67: Steady state spectral recording using MOS-450 in ORD mode
- RK-Spectro Technical Note 66: 3D trace using a diode array in absorbance mode
- RK-Spectro Technical Note 64: Single wavelength kinetics experiment using MOS200 in absorbance mode
- RK-Spectro Technical Note 63: Single wavelength kinetic of cytochrome c in fluorescence mode
- RK-Spectro Technical Note 62: Dead time determination using DCIP and acid ascorbic with the microcuvette μFC-08
- RK-Spectro Technical Note 61: Anisotropy T- format using MOS-200/M and an additional PMS-250
- RK-Spectro Technical Note 60: X-ray head
- RK-Spectro Technical Note 59: Single wavelength kinetics experiment using MOS200M_CD in CD mode
- RK-Spectro Technical Note 58: Titration of Cytochrome c
- RK-Spectro Technical Note 57: Single wavelength kinetic using J715-720 and Bio-Kine in fluorescence mode
- RK-Spectro Technical Note 56: Single wavelength kinetics using J715-720 and Bio-Kine32 in CD mode-reaction 2
- RK-Spectro Technical Note 55: Single wavelength kinetics using J715-720 and Bio-Kine32 in CD mode-reaction 1
- RK-Spectro Technical Note 54: Determination of your experimental dead time in fluorescence mode
- RK-Spectro Technical Note 53: Determination of your experimental dead time in fluorescence mode
- RK-Spectro Technical Note 52: Designing double mixing quench flow experiments
- RK-Spectro Technical Note 50: Global mode experiment using MOS-200M in absorbance mode
- RK-Spectro Technical Note 49: Determination of minimum washing volume for the microcuvette (mFC-08)
- RK-Spectro Technical Note 48: Installation of SFM20 on the J810 spectropolarimeter using spectra manager with advanced mode
- RK-Spectro Technical Note 47: Installation of SFMX00 on the J810 spectropolarimeter with advanced mode
- RK-Spectro Technical Note 46: Installation of SFM-X00 on the J810 spectropolarimeter
- RK-Spectro Technical Note 45: Installation of SFM20 on the J810 spectropolarimeter
- RK-Spectro Technical Note 44: Pulsed flow method for Quench flow experiment
- RK-Spectro Technical Note 43: Ageing methods for long time reaction using MPS software and biokine up to the version 4.04
- RK-Spectro Technical Note 42: Spectral recording using MOS450_AF-CD and Emission monochromator in fluorescence mode
- RK-Spectro Technical Note 41: Excitation fluorescence scan using MOS450AF-CD
- RK-Spectro Technical Note 40: QFM-400 upgrade for slow reactions studies
- RK-Spectro Technical Note 39: Determination of the minimal ageing time for each delay line
- RK-Spectro Technical Note 38: Anisotropy T-format using MOS250 and two additional channels
- RK-Spectro Technical Note 37: Anisotropy T-format using MOS200 and an additional PMS250
- RK-Spectro Technical Note 36: DNPA hydrolysis using the low temperature accessory
- RK-Spectro Technical Note 35: DNPA hydrolysis using QFM-400
- RK-Spectro Technical Note 34: Design of stopped flow sequence, determination of minimum washing volume
- RK-Spectro Technical Note 33: Stopped-flow_Diode array detection using Kinspec
- RK-Spectro Technical Note 32: SFM-20 used in anaerobic conditions and the loading of instruments
- RK-Spectro Technical Note 31: Determination of your experimental dead time in absorbance mode
- RK-Spectro Technical Note 25: Performing emission fluorescence spectra using MOS250
- RK-Spectro Technical Note 24: Titration of cytochrome-c using the titrator accessory combined with MOS250
- RK-Spectro Technical Note 23: Different acquisition modes using the titrator accessory combined with MOS250
- RK-Spectro Technical Note 22: Thermal denaturation of cytochrome-c using TCU-250 and MOS450
- RK-Spectro Technical Note 20: Single wavelength kinetics experiment using MOS250 in fluorescence mode
- RK-Spectro Technical Note 18: Create a stopped-flow sequence using MPS32 software
- RK-Spectro Technical Note 17: Single wavelength kinetics experiment using MOS250 in absorbance mode
- RK-Spectro Technical Note 16: Steady state spectral recording using MOS250 in absorbance mode
- RK-Spectro Technical Note 15: Single wavelength kinetics experiment using MOS450_AF-CD in CD and Fluorescence mode
- RK-Spectro Technical Note 14: Single wavelength kinetics experiment using MOS450 AF-CD in CD mode
- RK-Spectro Technical Note 13: Single wavelength kinetics experiment using MOS450_AF-CD in anisotropy mode
- RK-Spectro Technical Note 12: Single wavelength kinetics experiment using MOS450_AF or AF-CD in fluorescence mode
- RK-Spectro Technical Note 11: Single wavelength kinetics experiment using MOS 450_AF or AF-CD in absorbance mode
- RK-Spectro Technical Note 10: Spectral recording MOS450_AF-CD in anisotropy mode
- RK-Spectro Technical Note 9: Spectral recording using MOS450_AF-CD in Circular Dichroism mode
- RK-Spectro Technical Note 8: Steady state spectral recording using MOS450-AF or AF-CD in absorbance mode
- RK-Spectro Technical Note 6: Dual wavelength kinetic using MOS-LED and SFM100_motorized in absorbance mode
- RK-Spectro Technical Note 05: Quenched-flow mode_ Rate constant determination using Biokine
- RK-Spectro Technical Note 5: Dual wavelength kinetic using MOS-LED and SFM100_manual in absorbance mode
- RK-Spectro Technical Note 4: single wavelength kinetic using MOS-LED and SFM100_motorized in fluorescence mode
- RK-Spectro Technical Note 03: Installation of SFM 20 on the J810 spectropolarimeter
- MOS LED Technical Note 3: single wavelength kinetic using MOS-LED and SFM100_manual in Fluorescence mode
- MOS-LED Technical Note 2: single wavelength kinetic using MOS-LED and SFM100_motorized in absorbance mode
- RK-Spectro Technical Note 1: single wavelength kinetic using MOS-LED and SFM100 _manual in absorbance mode