ABSTRACT
The moistening process of Rehmanniae Radix was characterized quantitatively by moisture phase, texture properties, and component content based on water absorption kinetics and expansion kinetics. Non-linear fitting of water absorption kinetics and expansion kinetics in the moistening process of Rehmanniae Radix was carried out. Low-field nuclear magnetic resonance and imaging(LF-NMR/MRI) technology was used to investigate the phase state and distribution changes of water during the moistening process. The Texture Analyzer was used for the determination of texture properties. The correlations between water absorption rate, expansion rate, water phase state, hardness, and compression cycle work of Rehmanniae Radix at different moistening time were analyzed. The results showed that the water absorption kinetics and expansion kinetics of Rehmanniae Radix were in accordance with the first-order kinetics. Moreover, the water absorption rate and expansion rate increased with the increase in temperature but decreased with the increase in the size of the medicinal materials.In the moistening process, the moisture was transferred from the outside to the inside, and the proportion of the moisture phase changed significantly.Within 16 hours, free water increased from 0.825% to 97.7%,while bound water decreased from 99.2% to 2.33%.Within 28 hours, the texture properties, such as hardness and compression cycle work, decreased gradually with the prolongation in moistening time.At 32 hours, water was evenly distributed throughout the whole medicinal material, and the texture properties also tended to be stable.Pearson correlation bivariate analysis showed that moistening time, water absorption rate, expansion rate, the relative content of free water and bound water, hardness, and compression cycle work were significantly correlated, suggesting that water absorption kinetics and expansion kinetics, LF-NMR/MRI,and Texture Analyzer could directly and quantitatively characterize the moistening process.This study is expected to provide a scientific basis for clarifying the scientific connotation of the moistening process of Rehmanniae Radix.
Subject(s)
Drugs, Chinese Herbal , Rehmannia , Plant Extracts , WaterABSTRACT
Liangmianzhen(Zanthoxyli Radix) has long been used as medicine. The current medicinal parts are different from those in the ancient. As recorded in the Chinese Pharmacopeia, the medicinal part is root. However, in ancient works, the medicinal parts include root, stem, leaf, and fruit. In an attempt to find the historical basis that stem is a reasonable medicinal part, the herbalogical study was carried out on this medicinal based on the formal names, synonyms, original plant, medicinal parts, habitat of the medicinal plant, producing area, processing and preparation methods, efficacy, and indications recorded in ancient Chinese materia medica and local gazetteers. The results showed that Liangmianzhen was firstly recorded as a medicinal in Shennong's Classic of Materia Medica with the formal name of "Manjiao". "Manjiao" was adopted from the Han Dynasty to the Qing Dynasty when it was changed to "Rudijinniu", the name originating from the folk in the south of the Five Ridges. Now, the formal name is "Liangmianzhen", which was firstly recorded in Wuxuan County Gazetteer in 1914 and then as a synonym in the Updated Records of Picking Herbs in the South of the Five Ridges. According to the formal names, synonyms, and the descriptions of the original plant, the medicinal plants of Liang-mianzhen have the characteristics of shrub-like young seedlings, vine adult seedlings, corymbiform thyrsus, stems with thorns, amphitropous golden-yellow roots with horn-like branches, and thorns on both sides of the leaves. Thus, "Manjiao", "Rudijinniu", and "Liangmianzhen" were from the same species of Zanthoxylum nitidum(Rutaceae), which was also verified based on the growth environment, habitat, processing and preparation methods, efficacy, and indications. In ancient times, the stem and root were the main medicinal parts and leaves and fruits were also used. However, in the Chinese Pharmacopeia, root is recorded as the only medicinal part, which is obviously inconsistent with the records in the ancient classics. In light of the limited medicinal resources for Liang-mianzhen, other medicinal parts of Z. nitidum is recommended. This study clarified the medicinal parts of Z. nitidum in history. It is recommended that the stem be added to the medicinal parts of Z. nitidum in the next edition of Chinese Pharmacopeia.
Subject(s)
Drugs, Chinese Herbal , Materia Medica , Plants, Medicinal , China , Fruit , Medicine, Chinese TraditionalABSTRACT
BACKGROUND: In recent years, the application of Shenmai (SM) injection, a traditional Chinese medicine (TCM), to treat heart failure (HF) has been gradually accepted in China. However, whether SM improves energy metabolism in patients with HF has not been determined due to the lack of high-quality studies. We aimed to investigate the influence of SM on energy metabolism in patients with HF. METHODS: This single-blind, controlled study randomly assigned 120 eligible patients equally into three groups receiving SM, trimetazidine (TMZ), or control in addition to standard medical treatment for HF for 7 days. The primary endpoints were changes in free fatty acids (FFAs), glucose, lactic acid (LA), pyroracemic acid (pyruvate, PA) and branched chain amino acids (BCAAs) in serum. The secondary outcomes included the New York Heart Association (NYHA) functional classification, TCM syndrome score (TCM-s), left ventricular injection fraction (LVEF), left ventricular internal diastolic diameter (LVIDd), left ventricular internal dimension systole (LVIDs), and B-type natriuretic peptide (BNP). RESULTS: After treatment for 1 week, the NYHA functional classification, TCM-s, and BNP level gradually decreased in the patients in all three groups, but these metrics were significantly increased in the patients in the SM group compared with those in the patients in the TMZ and control groups (P < 0.05). Moreover, energy metabolism was improved in the NYHA III-IV patients in the SM group compared with those in the patients in the TMZ and control groups as evidenced by changes in the serum levels of FFA, LA, PA, and BCAA. CONCLUSIONS: Integrative treatment with SM in addition to standard medical treatment for HF was associated with improved cardiac function compared to standard medical treatment alone. The benefit of SM in HF may be related to an improvement in energy metabolism, which seems to be more remarkable than that following treatment with TMZ.
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BACKGROUND: Primary hypoparathyroidism (HPT) is rarely seen in the clinic, and it can be combined with rhabdomyolysis. There are few reports about this phenomenon. Therefore, it is significant to explore the etiology that is conducive to early diagnosis, timely treatment, and preventing the recurrence. CASE SUMMARY: A 63-year-old man was admitted to our hospital with a severe upper respiratory tract infection and progressing decreased myodynamia of the lower limbs. Blood tests showed creatine kinase > 32000 U/L, creatinine 207.8 µmol/L, calcium 1.28 mmol/L, myoglobin 558.7 ng/mL, and parathyroid hormone 0 pg/mL. He was diagnosed with primary HPT with rhabdomyolysis, and severe upper respiratory tract infection was considered to be the initial trigger. He responded well to supplementation of intravenous calcium gluconate and oral calcium as well as bedside hemodialysis, fluid hydration, infection control, protecting the liver, etc. Creatine kinase, myoglobin, and serum calcium returned to normal, and muscle strength improved significantly. Symptoms improved after symptomatic treatment. CONCLUSION: Severe infection should be prevented, which is the key cause of rhabdomyolysis in patients with HPT.
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OBJECTIVE: To evaluate modified Si-Miao-San (mSMS, ) regulation of insulin sensitivity and explore the molecular mechanism by which mSMS inhibits inflammation and improves insulin action in mice. METHODS: Insulin resistant model in mice was prepared by stimulation with macrophage-derived condition medium (Mac-CM) and the effects of mSMS on oral glucose tolerance, insulin sensitivity and liver glycogen content in mice was observed. The mice adipose tissue was isolated and the regulation of inflammation-related adipokine expression and insulin phosphatidylinositol 3-kinase (PI3K) signaling transduction by mSMS was investigated. Effect of mSMS on insulin-mediated glucose uptake was also investigated in adipocytes. RESULTS: Oral administration of mSMS improved glucose tolerance in mice. Treatment of mice with Mac-CM resulted in glucose intolerance in mice and this change was effectively reversed by mSMS. Meanwhile, mSMS enhanced insulin sensitivity and increased glucose load-stimulated liver glycogen when mice were exposed to Mac-CM. Mac-CM stimulation induced dysregulation of adipokine expression in adipose tissue of mice. mSMS downregulated tumor necrosis factor α and interleukin 6 (IL-6) overexpression and upregulated adiponectin and peroxisomal proliferator activated receptor γ with inhibition of inhibitory kappa B kinase-ß (IKKß) and p65 phophsphorylation. Meanwhile, mSMS inhibited IL-6 production and increased adiponectin secretion in adipocytes against Mac-CM insult. Mac-CM challenge impaired insulin phosphatidylinositol 3 kinase (PI3K) signaling in adipose tissue. Oral administration mSMS inhibited inflammation-induced serine phosphorylation of insulin receptor substrate-1 (IRS-1) and restored insulin-mediated tyrosine phosphorylation, and thereby facilitated insulin PI3K signaling manifested by restoration of Akt phosphorylation. The resultant improvement of insulin sensitivity promoted insulin-stimulated glucose uptake when adipocytes were exposed to Mac-CM. CONCLUSIONS: mSMS improves glucose tolerance in mice by enhancing insulin sensitivity in mice. mSMS inhibits IKKß/NF κ B (p65)-dependent inflammatory response with beneficial regulation of adipokine expression in adipose tissue. mSMS inhibits inflammation and improves insulin sensitivity by blocking inflammatory interaction between IKKß/IRS-1.