Comparative analysis of four terpenoids in root and cortex of Tripterygium wilfordii Radix by different drying methods

The tripterines containing carboxylic acid groups, so using a mobile phase system of aqueous acid can reduce tailing. By comparing with the acetonitrile-acid elution, both acetonitrile-0.2% phosphoric acid and acetonitrile-0.1% formic acid water solution can achieve a better separation, but phosphoric acid has some damage to column, and could easily lead to blockage of the valve, so we choose acetonitrile-0.1% formic acid as the mobile phase.

This experiment compared the ultrasonic-methanol (U1), ultrasonic-ethanol (U2), ultrasonic-ethyl acetate (U3), reflux-methanol (R1), reflux-ethanol (R2), reflux-ethyl acetate (R3) solvent extraction efficiency of terpenoids in Tripterygium wilfordii Radix. The results showed that there was a lower dissolution rate of terpenoids obtained by methanol, ethanol solvent extraction, but the acetate extraction rate is higher than that of methanol and ethanol. Besides, the dissolution rate of triptolide, demethylzeylasteral and celastrol had no significant difference between ultrasonic and reflux extraction, while the dissolution rate of triptophenolide with ultrasonic extraction was higher than reflux. Therefore, we selected the ultrasonic-ethyl acetate as the extraction solvent. The results were shown in Fig. 3.

Linear regression data, precision, repeatability, stability and recovery of 4 analytes were shown in Table 2. The results showed that the RSDs of precision test for triptolide, triptophenolide, demethylzeylasteral and celastrol were 2.95, 3.55, 0.350 and 0.270%, respectively, which indicated a good precision of the experimental method. The RSDs of stability test were 2.53, 3.04, 0.521 and 0.861%, respectively, and the absorbance of the sample solution showed stable within 24 h. The RSDs of repeatability test were 2.83, 3.40, 0.693 and 0.752%, respectively, which indicated a good reproducibility of the samples.

The contents of terpenoids in samples were shown in Tables 3, 4, 5 and 6. The contents of triptolide, triptophenolide, demethylzeylasteral and celastrol, obtained from the Tripterygium wilfordii Radix samples derived from different producing areas and by different drying process temperatures, exhibited obviously different. Among which the contents of triptophenolide are obvious difference at different drying temperatures. There is trace quantity of triptophenolide in some samples of Tripterygium wilfordii Radix. The content of tripterine has nearly two times difference and the demethylzeylasteral about 3 times.

On the whole, the contents of terpenoids in wild Tripterygium wilfordii Radix are higher (The contents of triptolide, triptophenolide, demethylzeylasteral and celastrol were from 38.67 to 70.31 mg/g, 0 to 1.807 mg/g, 0.3513 to 9.205 mg/g, and 3.899 to 15.32 mg/g, respectively) than those in cultivate Tripterygium wilfordii Radix (The contents of triptolide, triptophenolide, demethylzeylasteral and celastrol were 37.94 ~ 47.75 mg/g, 0 ~ 1.164 mg/g, 0.9701 ~ 9.112 mg/g, and 3.202 ~ 8.759 mg/g, respectively). The content changes of terpenoids in samples from different producing areas of wild products of Tripterygium wilfordii Radix is relatively larger than the changes in cultivate samples. Besides, the contents of triptophenolide, celastrol, and demethylzeylasteral in cortex of Tripterygium wilfordii Radix were all higher than the contents of roots (Fig. 4) (The contents of triptolide, triptophenolide, demethylzeylasteral and celastrol were 37.94 ~ 47.37 mg/g, 0 ~ 1.164 mg/g, 0.3513 ~ 7.214 mg/g, and 3.202 ~ 12.97 mg/g, respectively) were less than the cortex part (The contents of triptolide, triptophenolide, demethylzeylasteral and celastrol were 39.93 ~ 70.31 mg/g, 0 ~ 1.807 mg/g, 0.4459 ~ 9.205 mg/g, and 4.111 ~ 15.32 mg/g, respectively).

During the different drying temperature, the suitable drying temperature for cortex of Tripterygium wilfordii Radix was shown in Fig. 5. It was found that the highest content of triptolide in wild samples such as sample 1, 2, 6 and 10 were at 100 °C by comparing different temperatures. It was occupied more than half in all wild samples. The highest content of triptolide in cultivate samples such as samples 4, 8, 9, 12 and 13 were at 100 °C by comparing different temperatures. These samples are far more than in all cultivate samples in half. So it was considered that the suitable drying temperature were both 100 °C, respectively. The highest content of triptophenolide in wild samples such as sample 1, 2, 7 and 10 were at 40 °C by comparing different temperatures. The highest content of triptophenolide in cultivate samples such as samples 4, 5, 8 and 13 were at 80 °C by comparing different temperatures and they account for more than half in all wild and cultivate samples. So it was considered the suitable drying temperature were 40 and 80 °C. The highest content of demethylzeylasteral in wild samples such as sample 1, 6, 7 and 10 were at 40 °C by comparing different temperatures. It was occupied more than half in all wild samples. The highest content of demethylzeylasteral in cultivate samples such as sample 4, 5, 9, 12 and 13 were at 40 °C by comparing different temperatures. These samples are far more than in all cultivate samples in half. So it was considered the suitable drying temperature were both 40 °C. The highest content of celastrol in wild samples such as sample 1, 2, 6 and 10 were at 80 °C by comparing different temperatures. It was occupied more than half in all wild samples. The highest content of celastrol in cultivate samples such as sample 4, 5, 9, 12 and 13 were at 60 °C by comparing different temperatures. These samples are far more than in all cultivate samples in half. So it was considered the suitable drying temperature were 80 and 60 °C.

From the above conclusion, the different contents of Tripterygium wilfordii Radix drying temperature are different. Therefore, choose a suitable drying temperature in order to make the medicinal full and effective use is imperative. Generally speaking, the terpenoids in cortex of Tripterygium wilfordii Radix suitable drying temperature is 40 °C, because it could get most types of ingredients. On the contrary, it is considered the suitable drying temperature is 80 °C as for a maximum contents of total terpenoids obtained.

During the different drying processes, the feasible drying temperature for root of Tripterygium wilfordii Radix was shown in Fig. 6. It was found that the highest content of triptolide in wild samples such as sample 2, 3, 6 and 7 was at 80 °C by comparing different temperatures. The highest content of triptolide in cultivate samples such as sample 4, 8, 9 and 13 was at 100 °C by comparing different temperatures. The highest content of triptophenolide in wild samples such as sample 2, 6, 7 and 10 was at 40 °C by comparing different temperatures. The highest content of triptophenolide in cultivate samples such as sample 4, 5, 8, 11 and 12 was at 80 °C by comparing different temperatures. The highest content of demethylzeylasteral in wild samples such as sample 3, 6 and 7 was at 40 °C which account for more than half in all wild samples by comparing different temperatures. The highest content of demethylzeylasteral in cultivate samples such as sample 4, 5, 9 and 13 was at 60 °C by comparing different temperatures. The highest content of celastrol in wild samples such as sample 1, 2, 3 and 7 was at 80 °C by comparing different temperatures. The highest content of celastrol in cultivate samples such as sample 4, 5, 8, 12 and 13 was at 60 °C by comparing different temperatures.