This article systematically analyzes the historical evolution of the name， origin， medicinal parts， harvesting and processing， and other aspects of Manjiao and Zanthoxyli Radix by referring to the herbal medicine， medical books， prescription books and other documents of the past dynasties， combined with the relevant modern research materials， in order to provide a basis for the development of famous classical formulas containing the two medicinal materials. According to the herbal textual research， Manjiao was first recorded in Shennong Bencaojing of the Han dynasty with aliases such as Zhujiao， Goujiao and Zhijiao. Throughout history， Manjiao was sourced from the stems and roots of Zanthoxylum armatum in the Rutaceae family， and its leaves and fruits can also be used in medicine. The traditional recorded production area was mainly in Yunzhong（now Tuoketuo region in Inner Mongolia）， with mentions in Zhejiang， Hunan， Fujian， Guangdong， Guangxi， Yunnan， Taiwan， and other provinces. Presently， this species is distributed from the south of Shandong， to Hainan， Taiwan， Tibet and other regions. The roots can be harvested year-round， while the fruits are harvested in autumn after maturity. In ancient times， the roots and stems were mostly used for brewing or soaking in wine， whereas nowadays， the roots are often sliced and then used as a raw material in traditional Chinese medicine， and the fruits should be stir-fried before use. Manjiao has a bitter taste and warm property， and was historically used to treat wind-cold dampness， joint pain， limb numbness， and knee pain. Modern researches have summarized its effects as dispelling wind， dispersing cold， promoting circulation， and relieving pain， and it is used for treating rheumatoid arthritis， toothache， bruises， as well as an anthelmintic. Zanthoxyli Radix initially known as Rudi Jinniugen， recorded in Bencao Qiuyuan of the Qing dynasty， with the alternate name of Liangbianzhen. In recent times， it is more commonly referred to as Liangmianzhen， sourced from the dried roots of Z. nitidum of the Rutaceae family， mainly produced in Guangxi and Guangdong. It can be harvested throughout the year， cleaned， sliced， and dried after harvesting. Zanthoxyli Radix is pungent， bitter， warm and slightly toxic， with the functions of promoting blood circulation， removing stasis， relieving pain， dispelling wind， and resolving swelling. Based on the results of herbal textual research， it is clarified that the ancient Manjiao and the modern Zanthoxyli Radix are not the same species. This article corrects the mistaken belief of by previous scholars that Zanthoxyli Radix is the same as ancient Manjiao， and suggests that formulas described as Manjiao should use Z. armatum as the medicinal herb， while those described as Liangmianzhen or Rudi Jinniu should use Z. nitidum. The processing was performed according to the processing requirements prescribed in the formulas， otherwise， the raw products are recommended for use.

This article systematically analyzes the historical evolution of the name， origin， medicinal parts， harvesting and processing， and other aspects of Manjiao and Zanthoxyli Radix by referring to the herbal medicine， medical books， prescription books and other documents of the past dynasties， combined with the relevant modern research materials， in order to provide a basis for the development of famous classical formulas containing the two medicinal materials. According to the herbal textual research， Manjiao was first recorded in Shennong Bencaojing of the Han dynasty with aliases such as Zhujiao， Goujiao and Zhijiao. Throughout history， Manjiao was sourced from the stems and roots of Zanthoxylum armatum in the Rutaceae family， and its leaves and fruits can also be used in medicine. The traditional recorded production area was mainly in Yunzhong（now Tuoketuo region in Inner Mongolia）， with mentions in Zhejiang， Hunan， Fujian， Guangdong， Guangxi， Yunnan， Taiwan， and other provinces. Presently， this species is distributed from the south of Shandong， to Hainan， Taiwan， Tibet and other regions. The roots can be harvested year-round， while the fruits are harvested in autumn after maturity. In ancient times， the roots and stems were mostly used for brewing or soaking in wine， whereas nowadays， the roots are often sliced and then used as a raw material in traditional Chinese medicine， and the fruits should be stir-fried before use. Manjiao has a bitter taste and warm property， and was historically used to treat wind-cold dampness， joint pain， limb numbness， and knee pain. Modern researches have summarized its effects as dispelling wind， dispersing cold， promoting circulation， and relieving pain， and it is used for treating rheumatoid arthritis， toothache， bruises， as well as an anthelmintic. Zanthoxyli Radix initially known as Rudi Jinniugen， recorded in Bencao Qiuyuan of the Qing dynasty， with the alternate name of Liangbianzhen. In recent times， it is more commonly referred to as Liangmianzhen， sourced from the dried roots of Z. nitidum of the Rutaceae family， mainly produced in Guangxi and Guangdong. It can be harvested throughout the year， cleaned， sliced， and dried after harvesting. Zanthoxyli Radix is pungent， bitter， warm and slightly toxic， with the functions of promoting blood circulation， removing stasis， relieving pain， dispelling wind， and resolving swelling. Based on the results of herbal textual research， it is clarified that the ancient Manjiao and the modern Zanthoxyli Radix are not the same species. This article corrects the mistaken belief of by previous scholars that Zanthoxyli Radix is the same as ancient Manjiao， and suggests that formulas described as Manjiao should use Z. armatum as the medicinal herb， while those described as Liangmianzhen or Rudi Jinniu should use Z. nitidum. The processing was performed according to the processing requirements prescribed in the formulas， otherwise， the raw products are recommended for use.

BackgroundAlcohol dependence patients are prone to relapse after their attempts to quit drinking， which poses a considerable threat to their physical and mental health and creates a heavy burden on their families. Currently， empowerment education is increasingly being utilized in the rehabilitation management of chronic diseases， but there remains a striking lack of empirical research on the application of "Internet +" empowerment education based on timing it right in alcohol dependence patients. ObjectiveTo explore the impact of "Internet +" empowerment education based on timing it right on patients with alcohol dependence， in order to maximize the reduction in relapse rates， craving for alcohol and severity of anxiety symptoms. MethodsA total of 120 patients who were hospitalized in the Department of Addiction Medicine， Hebei Provincial Mental Health Center from May 2022 to April 2023 and met the diagnostic criteria for alcohol dependence in the International Classification of Diseases， tenth edition （ICD-10） were enrolled， and they were classified into study group （n=62） and control group （n=58） using random number table methods. Both groups received standard medication and routine care. Additionally， study group underwent a 6-month "Internet +" empowerment education based on timing it right. At baseline， all subjects were assessed using Penn Alcohol Craving Scale （PACS） and Self-rating Anxiety Scale （SAS）. Three months and six months after intervention， assessments were conducted using PACS， SAS and Michigan Alcoholism Screening Test （MAST）. ResultsThe relapse rates after three and six months of intervention were both lower in study group than those in control group， with statistically significant differences （χ²=8.575， 8.828， P<0.01）. ANOVA with repeated measures on PACS total score and scores of each item revealed a significant time effect， group effect and time×group interaction effect （F=159.714~837.751， 84.645~393.606， 24.302~137.896， P<0.01）. And significant time effect， group effect and time×group interaction effect were also reported on SAS scores （F=166.237， 65.325， 24.724， P<0.01）. Conclusion"Internet +" empowerment education based on timing it right may help reduce relapse rates， alcohol cravings and severity of anxiety symptoms among patients with alcohol dependence. ［Funded by 2023 Annual Hebei Provincial Medical Scientific Research Project Plan （number， 20231537）］

Objective To establish a scientific, comprehensive, and operable community resilience evaluation index system for emergent major infectious diseases. Methods Based on the social ecosystem theory, a preliminary evaluation index system was formed by using content analysis and boundary analysis. The index system was then supplemented and revised through panel discussions. The final index system and index weights were clarified by two rounds of Delphi method. Results The expert positive coefficient, expert authority coefficient, and expert coordination coefficient of the two rounds of expert consultations were examined. According to the screening principle of the ^“threshold method^”, the indicators were screened, and the weights of each indicator were determined in the second round of Delphi expert consultation. The analysis of the reliability of the indicator system showed Cronbach's α= 0.399 , indicating that the indicator system had a relatively high reliability. Factor analysis was carried out on 7 primary indicators, and the measure of sampling adequacy (MSA) values were all greater than 0.5, which passed the validity test. Conclusion A set of evaluation index system that can accurately reflect the resilience level of communities with emergent major infectious diseases has been constructed, including 7 primary indicators, 21 secondary indicators, 54 tertiary indicators, and 108 tertiary indicators, which has realized the quantitative evaluation of the hidden resilience level of communities.

Objective: To investigate the safety and feasibility of transurethral blue laser vaporization of the prostate (BVP) under intravenous anesthesia without intubation. Methods: Clinical data of 30 benign prostatic hyperplasia (BPH) (prostate volume <40 mL) patients undergoing BVP under intravenous anesthesia without intubation in our hospital during Jul.and Nov.2024 were retrospectively analyzed.Preoperative and 1-month postoperative international prostate symptom score (IPSS), quality of life score (QoL), maximum urinary flow rate (Qmax), and postvoid residual volume (PVR) were compared.The operation time, cumulative blue laser activation time, recovery time, postoperative bladder irrigation time, postoperative catheter indwelling time, postoperative 2-hour visual analog scale (VAS) score and incidence of surgical and anesthetic complications were recorded. Results: All 30 patients successfully completed BVP under intravenous anesthesia without intubation.The operation time was (12.5±5.0) min, cumulative laser activation time (9.8±4.1) min, recovery time (6.8±1.2) min, postoperative bladder irrigation time (11.0±4.6) h, postoperative catheter indwelling time (2.7±1.1) days and postoperative 2-hour VAS score was (3.0±1.3).No cases required conversion to intubated general anesthesia, and no severe perioperative surgical or anesthetic complications occurred.Significant improvements in IPSS, QoL, Qmax, and PVR were observed 1 month postoperatively (P＜0.001). Conclusion: BVP under intravenous anesthesia without intubation in the treatment of prostate volume <40 mL BPH is clinically feasible, significantly improving lower urinary tract symptoms without significant surgical or anesthetic complications.

This article systematically analyzes the historical evolution of the name， origin， academic name， medicinal parts， origin， harvesting， processing and other aspects of Abri Herba and Abri Mollis Herba by referring to the herbal medicine， medical books， prescription books and other documents of the past dynasties， combined with the modern literature， so as to provide a basis for the development of famous classical formulas containing this type of medicinal materials. According to the herbal textual research， Abri Herba was first recorded in Lingnan Caiyaolu， with other aliases such as Huangtoucao and Xiye Longlincao. It originates from the dried whole plant of Abrus cantoniensis， a Fabaceae plant， which can be used medicinally except for its fruits. Currently， this species is mainly distributed in Guangdong and Guangxi， and also found in Hunan and Thailand， it can be harvested throughout the year， mainly in spring and autumn. The roots， stems， and leaves can be used for medicinal purposes， but the pods are toxic and need to be removed. After harvesting， impurities and pods are removed， and it is dried and processed for medicinal use. Abri Herba has a sweet and slightly bitter taste， is cool in nature， and is associated with the liver and stomach meridians， it is used for clearing heat and relieving dampness， dispersing blood stasis and relieving pain， and is mainly used to treat jaundice-type hepatitis， stomach pain， rheumatic bone pain， contusion and ecchymosis pain， and mastitis. Abri Mollis Herba was first recorded in the 1982 edition of Zhongyaozhi as another origin for Abri Herba， and was singled out in some monographs such as Xinhua Bencao Gangyao in 1988 for use， while some other monographs use it as a local habitual products or confused products of Abri Herba with aliases such as Daye Jigucao， Qingtingteng， and Maoxiangsi. It comes from the dried whole herb of A. mollis without pods， and is mainly produced in Guangxi and Guangdong， and occasionally found in Hong Kong， Hainan and Fujian. The collection and processing are similar to Abri Herba， after harvesting， impurities and pods are removed， and it is dried and cut for medicinal use. Abri Mollis Herba has a sweet and light taste， is cool in nature， and is associated with the liver and stomach meridians， with the efficacy of clearing heat and detoxifying， and promoting dampness， it is mainly used to treat infectious hepatitis， mastitis， furuncles， burns and scalds， and pediatric malnutrition. Based on the research， A. mollis was first recorded to be used as a medicine in the same origin as A. cantoniensis， and as plants of the same genus， have similar morphological characteristics， and their medicinal parts， collection and processing， properties and flavors， and meridian affiliations are consistent. And in the folk， Abri Mollis Herba is often used as Abri Herba， which has been used for a long time and is now dominated by the cultivation of A. mollis. So it is recommended that the subsequent version of Chinese Pharmacopoeia should include A. mollis in the origin of Abri Herba， and it is also recommended that in famous classical formulas refered to Jiguccao can use A. cantoniensis and A. mollis as the sources of the herb， refered to Mao Jiguccao can use A. mollis as the sources of the herb. Processing is carried out according to the requirements specified in the original formulas， and raw products are recommended to be included in the medicine if there are no requirements.

This article systematically analyzes the historical evolution of the name， origin， academic name， medicinal parts， origin， harvesting， processing and other aspects of Abri Herba and Abri Mollis Herba by referring to the herbal medicine， medical books， prescription books and other documents of the past dynasties， combined with the modern literature， so as to provide a basis for the development of famous classical formulas containing this type of medicinal materials. According to the herbal textual research， Abri Herba was first recorded in Lingnan Caiyaolu， with other aliases such as Huangtoucao and Xiye Longlincao. It originates from the dried whole plant of Abrus cantoniensis， a Fabaceae plant， which can be used medicinally except for its fruits. Currently， this species is mainly distributed in Guangdong and Guangxi， and also found in Hunan and Thailand， it can be harvested throughout the year， mainly in spring and autumn. The roots， stems， and leaves can be used for medicinal purposes， but the pods are toxic and need to be removed. After harvesting， impurities and pods are removed， and it is dried and processed for medicinal use. Abri Herba has a sweet and slightly bitter taste， is cool in nature， and is associated with the liver and stomach meridians， it is used for clearing heat and relieving dampness， dispersing blood stasis and relieving pain， and is mainly used to treat jaundice-type hepatitis， stomach pain， rheumatic bone pain， contusion and ecchymosis pain， and mastitis. Abri Mollis Herba was first recorded in the 1982 edition of Zhongyaozhi as another origin for Abri Herba， and was singled out in some monographs such as Xinhua Bencao Gangyao in 1988 for use， while some other monographs use it as a local habitual products or confused products of Abri Herba with aliases such as Daye Jigucao， Qingtingteng， and Maoxiangsi. It comes from the dried whole herb of A. mollis without pods， and is mainly produced in Guangxi and Guangdong， and occasionally found in Hong Kong， Hainan and Fujian. The collection and processing are similar to Abri Herba， after harvesting， impurities and pods are removed， and it is dried and cut for medicinal use. Abri Mollis Herba has a sweet and light taste， is cool in nature， and is associated with the liver and stomach meridians， with the efficacy of clearing heat and detoxifying， and promoting dampness， it is mainly used to treat infectious hepatitis， mastitis， furuncles， burns and scalds， and pediatric malnutrition. Based on the research， A. mollis was first recorded to be used as a medicine in the same origin as A. cantoniensis， and as plants of the same genus， have similar morphological characteristics， and their medicinal parts， collection and processing， properties and flavors， and meridian affiliations are consistent. And in the folk， Abri Mollis Herba is often used as Abri Herba， which has been used for a long time and is now dominated by the cultivation of A. mollis. So it is recommended that the subsequent version of Chinese Pharmacopoeia should include A. mollis in the origin of Abri Herba， and it is also recommended that in famous classical formulas refered to Jiguccao can use A. cantoniensis and A. mollis as the sources of the herb， refered to Mao Jiguccao can use A. mollis as the sources of the herb. Processing is carried out according to the requirements specified in the original formulas， and raw products are recommended to be included in the medicine if there are no requirements.

Optical imaging is highly valued for its superior temporal and spatial resolution. This is particularly important in near-infrared II (NIR-II, 1 000-3 000 nm) imaging, which offers advantages such as reduced tissue absorption, minimal scattering, and low autofluorescence. These characteristics make NIR-II imaging especially suitable for deep tissue visualization, where high contrast and minimal background interference are critical for accurate diagnosis and monitoring. Currently, inorganic fluorescent probes—such as carbon nanotubes, rare earth nanoparticles, and quantum dots—offer high brightness and stability. However, they are hindered by ambiguous structures, larger sizes, and potential accumulation toxicity in vivo. In contrast, organic fluorescent probes, including small molecules and polymers, demonstrate higher biocompatibility but are limited by shorter emission wavelengths, lower quantum yields, and reduced stability. Recently, gold clusters have emerged as a promising class of nanomaterials with potential applications in biocatalysis, fluorescence sensing, biological imaging, and more. Water-soluble gold clusters are particularly attractive as fluorescent probes due to their remarkable optical properties, including strong photoluminescence, large Stokes shifts, and excellent photostability. Furthermore, their outstanding biocompatibility—attributed to good aqueous stability, ultra-small hydrodynamic size, and high renal clearance efficiency—makes them especially suitable for biomedical applications. Gold clusters hold significant potential for NIR-II fluorescence imaging. Atomic-precision gold clusters, typically composed of tens to hundreds of gold atoms and measuring only a few nanometers in diameter, possess well-defined three-dimensional structures and clear spatial coordination. This atomic-level precision enables fine-tuned structural regulation, further enhancing their fluorescence properties. Variations in cluster size, surface ligands, and alloying elements can result in distinct physicochemical characteristics. The incorporation of different atoms can modulate the atomic and electronic structures of gold clusters, while diverse ligands can influence surface polarity and steric hindrance. As such, strategies like alloying and ligand engineering are effective in enhancing both fluorescence and catalytic performance, thereby meeting a broader range of clinical needs. In recent years, gold clusters have attracted growing attention in the biomedical field. Their application in NIR-II imaging has led to significant progress in vascular, organ, and tumor imaging. The resulting high-resolution, high signal-to-noise imaging provides powerful tools for clinical diagnostics. Moreover, biologically active gold clusters can aid in drug delivery and disease diagnosis and treatment, offering new opportunities for clinical therapeutics. Despite the notable achievements in fundamental research and clinical translation, further studies are required to address challenges related to the standardized synthesis and complex metabolic behavior of gold clusters. Resolving these issues will help accelerate their clinical adoption and broaden their biomedical applications.

Cardiovascular disease (CVD) remains one of the leading causes of mortality among adults globally, with continuously rising morbidity and mortality rates. Metabolic disorders are closely linked to various cardiovascular diseases and play a critical role in their pathogenesis and progression, involving multifaceted mechanisms such as altered substrate utilization, mitochondrial structural and functional dysfunction, and impaired ATP synthesis and transport. In recent years, the potential role of peroxisome proliferator-activated receptors (PPARs) in cardiovascular diseases has garnered significant attention, particularly peroxisome proliferator-activated receptor alpha (PPARα), which is recognized as a highly promising therapeutic target for CVD. PPARα regulates cardiovascular physiological and pathological processes through fatty acid metabolism. As a ligand-activated receptor within the nuclear hormone receptor family, PPARα is highly expressed in multiple organs, including skeletal muscle, liver, intestine, kidney, and heart, where it governs the metabolism of diverse substrates. Functioning as a key transcription factor in maintaining metabolic homeostasis and catalyzing or regulating biochemical reactions, PPARα exerts its cardioprotective effects through multiple pathways: modulating lipid metabolism, participating in cardiac energy metabolism, enhancing insulin sensitivity, suppressing inflammatory responses, improving vascular endothelial function, and inhibiting smooth muscle cell proliferation and migration. These mechanisms collectively reduce the risk of cardiovascular disease development. Thus, PPARα plays a pivotal role in various pathological processes via mechanisms such as lipid metabolism regulation, anti-inflammatory actions, and anti-apoptotic effects. PPARα is activated by binding to natural or synthetic lipophilic ligands, including endogenous fatty acids and their derivatives (e.g., linoleic acid, oleic acid, and arachidonic acid) as well as synthetic peroxisome proliferators. Upon ligand binding, PPARα activates the nuclear receptor retinoid X receptor (RXR), forming a PPARα-RXR heterodimer. This heterodimer, in conjunction with coactivators, undergoes further activation and subsequently binds to peroxisome proliferator response elements (PPREs), thereby regulating the transcription of target genes critical for lipid and glucose homeostasis. Key genes include fatty acid translocase (FAT/CD36), diacylglycerol acyltransferase (DGAT), carnitine palmitoyltransferase I (CPT1), and glucose transporter (GLUT), which are primarily involved in fatty acid uptake, storage, oxidation, and glucose utilization processes. Advancing research on PPARα as a therapeutic target for cardiovascular diseases has underscored its growing clinical significance. Currently, PPARα activators/agonists, such as fibrates (e.g., fenofibrate and bezafibrate) and thiazolidinediones, have been extensively studied in clinical trials for CVD prevention. Traditional PPARα agonists, including fenofibrate and bezafibrate, are widely used in clinical practice to treat hypertriglyceridemia and low high-density lipoprotein cholesterol (HDL-C) levels. These fibrates enhance fatty acid metabolism in the liver and skeletal muscle by activating PPARα, and their cardioprotective effects have been validated in numerous clinical studies. Recent research highlights that fibrates improve insulin resistance, regulate lipid metabolism, correct energy metabolism imbalances, and inhibit the proliferation and migration of vascular smooth muscle and endothelial cells, thereby ameliorating pathological remodeling of the cardiovascular system and reducing blood pressure. Given the substantial attention to PPARα-targeted interventions in both basic research and clinical applications, activating PPARα may serve as a key therapeutic strategy for managing cardiovascular conditions such as myocardial hypertrophy, atherosclerosis, ischemic cardiomyopathy, myocardial infarction, diabetic cardiomyopathy, and heart failure. This review comprehensively examines the regulatory roles of PPARα in cardiovascular diseases and evaluates its clinical application value, aiming to provide a theoretical foundation for further development and utilization of PPARα-related therapies in CVD treatment.

[摘 要] 目的：探讨白蛋白结合型紫杉醇联合PD-1抑制剂用于治疗一线化疗失败的骨与软组织肉瘤的疗效及安全性。方法：回顾性分析北京积水潭医院骨肿瘤科2017年8月至2020年8月收治的一线化疗失败的晚期骨与软组织肉瘤患者。患者接受白蛋白结合型紫杉醇（125~140 mg/m2，第1天和第8天）与PD-1抑制剂（信迪利单抗或特瑞普利单抗，每21 d一次）联合治疗。每2个治疗周期评估1次疗效，按RECIST 1.1标准评估肿瘤疗效，按NCI-CTCAE5.0标准评估不良反应。结果：共20名患者纳入研究，完成1至8个治疗周期，中位治疗周期数为3个。所有患者均可评估疗效，完全缓解4例（20%），部分缓解0例，稳定9例（45%），疾病进展7例（35%）。客观缓解率（ORR）为20%，疾病控制率（DCR）为65%。中位无进展生存期（PFS）为3.0个月。治疗期间主要不良反应包括2级白细胞减少（40%）、1-2级神经毒性反应（20%），以及2级甲状腺功能减退（10%）。结论：白蛋白结合型紫杉醇联合PD-1抑制剂治疗为一线化疗失败的晚期骨与软组织肉瘤患者提供了一种潜在的治疗选择，其不良反应可控，值得开展更大样本的前瞻性研究进一步验证其疗效。