[Powder modification technology used for the preparation of the hydrophilic decoction pieces of indigo naturalis and the modification principle].

The hydrophilicity of the normal decoction pieces (NDP) of Indigo Naturalis is not good, therefore, it is not suit for decoctions. In this paper, powder modification technology is used and some NDP and alcohol are ground together in the vibromill to prepare the hydrophilic decoction pieces (HDP) of Indigo Naturalis. Initially, the properties of NDP, ultrafine decoction pieces (UDP) and HDP are compared, the hydrophilicity of UDP was promoted slightly, that of HDP is promoted dramatically. Then, three batches of Indigo Naturalis are prepared to HDP separately, but there is no obvious difference in the contact angle. Furthermore, the size distribution, surface area and micro-shape of HDP are bigger than that of UDP and smaller than NDP. The contents of indigo and indirubin in three decoction pieces are the same, as well as the species of inorganic substance, although there is a little difference in the proportion of five inorganic substances. The fact suggests the change of physical state and the qualitative and quantitative change of organism and inorganic substances are not the main factors to influence the hydrophilicity. In addition, hydroxyl, methylene and methyl can be identified at the wavenumber of 3 356 cm(-1) and 1 461 cm(-1) in infrared spectrum; the content of alcohol in HDP is 0.67% measured by gas chromatogram. The stability of HDP in the heating condition is studied, the fact suggests the hydrophilic effect of HDP at 40 degrees C is relatively stable. All above research suggests that the alcohol is the main factor to influence the hydrophilicity and maybe the intermolecular force which fixed alcohol molecule on the surface of Indigo Naturalis is the basic principle to produce the hydrophilicity.

[Influence of superfine grinding on micromeritic properties of Scutellaria baicalensis].

OBJECTIVE: To study the micromeritic properties of different particle size of Scutellaria baicalensis and provide a basis for being directly used or as raw material of Chinese herba preparation. METHODS: Size distribution, surface area and pore volume, contact angle, angle of repose and bulk density, moisture absorption, micromorphology, Infrared spectrum, HPLC fingerprint were used to evaluate the differences of micromeritic properties of 4 kinds of Scutellaria baicalensis superfine grinding. RESULTS: With the particle size of powders decreased, size distribution and bulk density decreased, the surface area and pore volume, contact angle and moisture absorption increased, angle of repose first increased and then decreased. Infrared spectrum and HPLC fingerprint showed no change of chemical composition of Scutellaria baicalensis. CONCLUSION: Different particle size of Scutellaria baicalensis leads to the differences of micromeritic properties. Superfine grinding III is determined as a better particle size.

[Effect of particle design on micromeritic property of dental ulcer powder].

OBJECTIVE: To prepare dental ulcer powder by using particle design technology, and compare the effect on the micromeritic property of dental ulcer powder with regular grinding and ultrafine grinding methods. METHOD: Above three methods were respectively used to make dental ulcer powder, in order to evaluate their difference in appearance character, grain size distribution, specific surface area and porosity, contact angle, micro-morphological character and borneol's stability. RESULT: Compared with normal powder, ultrafine powder and particle design showed increase in color uniformity and decrease in sour taste, and the particle design powder smells almost no borneol. Their grain size distributions were significantly less that of normal powder (P < 0.01), with the same grain size distribution in ultrafine powder and particle design powder. Their specific surface areas and porosities were significantly more than that of normal powder (P < 0.01), with the highest figures in ultrafine powder. Their contact angles were significantly more than that of normal powder (P < 0.01), with the highest figure in particle design powder. The surface of normal powder was smooth, with a few of small particle adhered. The surface of ultrafine powder was partially coated with small particles, where as the surface of particle design powder was mostly coated with particles. There was difference in micro-morphological character and surface attachment among the three. The 10-day accelerate stability experiment showed that normal power, ultrafine powder and particle design powder lost borneol by 90. 13% , 66. 48% and 40.57%, respectively. Particle design powder showed the highest stability, followed by ultrafine powder and normal powder. CONCLUSION: The preparation process can affect the micromeritic properties, by changing microscopic structure of the powders. We can design the macroscopic property of powder by regulating the formation of the microscopic structure with particle design technology.