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.

Hepatic encephalopathy is a difficult and critical disease with rapid progression and limited treatment methods in the field of liver disease， and it is urgently needed to make breakthroughs in its pathogenesis. Selection of appropriate prevention and treatment strategies is of great importance in delaying disease progression and reducing the incidence and mortality rates. This article reviews the theory of “turbid toxin pathogenesis” and related prevention and treatment strategies for hepatic encephalopathy in traditional Chinese medicine/Zhuang medicine， proposes a new theory of “turbid toxin pathogenesis”， analyzes the scientific connotations of “turbid”， “toxin”， and the theory of “turbid toxin pathogenesis”， and constructs the “four-step” prevention and treatment strategies for hepatic encephalopathy， thereby establishing the new clinical prevention and treatment regimen for hepatic encephalopathy represented by “four prescriptions and two techniques” and clarifying the effect mechanism and biological basis of core prescriptions and techniques in the prevention and treatment of hepatic encephalopathy， in order to provide a reference for the prevention and treatment of hepatic encephalopathy.

Hepatic encephalopathy （HE） is a common complication of severe liver disease in the end stage， and it is urgently needed to improve the rate of effective treatment and clarify the pathogenesis of HE. The liver is a crucial hub for immune regulation， and disruption of immune homeostasis is a key factor in the pathological mechanisms of HE. As the main metabolites of intestinal flora， short-chain fatty acids （SCFAs） play a vital role in the biological processes of both innate and adaptive immunity and can regulate the proliferation and differentiation of immune cells maintain the homeostasis of intestinal microenvironment and the integrity of barrier function. Studies have shown that SCFAs participate in bidirectional and dynamic interactions with the liver-gut-brain axis through immunomodulatory pathways， thereby playing an important role in the diagnosis， treatment， and prognostic evaluation of HE. Starting from the immunoregulatory effect of SCFAs， this article summarizes and analyzes the crosstalk relationship between SCFAs and the liver-gut-brain axis and the significance of SCFAs in the diagnosis and treatment of HE， in order to provide new ideas for optimizing clinical prevention and treatment strategies.

ObjectiveTo study the mechanism by which Shexiang Tongxin dropping pills （STDP） ameliorate the dysfunction of coronary microvascular endothelial cells in the rat model of heart failure. MethodsThe heart failure model was established by ligation of the left anterior descending coronary artery in rats， which were then allocated into sham， model， STDP， and telmisartan （TLM） groups and treated for 21 days. The heart function was detected by echocardiography， and the levels of myocardial injury markers， nitric oxide （NO）， endothelin-1 （ET1）， and angiotensinⅡ （AngⅡ） were determined by enzyme-linked immunosorbent assay （ELISA）. The protein levels of endothelial nitric oxide synthase （eNOS） and inducible nitric oxide synthase （iNOS） were determined by Western blot. The model of cardiac microvascular endothelial cell injury was established by AngⅡ induction and then treated with the STDP-containing serum （5%， 10%， and 20%） for 24 h. The levels of NO and ET1 were measured by ELISA. Western blot was employed to determine the protein levels of eNOS， iNOS， angiotensin-converting enzyme 2 （ACE2）， and angiotensinⅡ receptor 2 （AT2）. MLN-4760， an ACE2 inhibitor， was used to explore the mechanism underpinning the regulatory effect of STDP on the ACE2-AT2/MAS pathway. ResultsCompared with the sham group， the model group showed decreases in left ventricular ejection fraction （LVEF） and left ventricular fractional shortening （LVFS） （P<0.05）， a decline in serum NO level， elevations in serum AngⅡ and ET1 levels， a reduction in p-eNOS/eNOS ratio， and up-regulation in iNOS expression （P<0.05）. Compared with the model group， STDP increased LVEF， LVFS， and cardiac output （P<0.05）， raised the level of NO and lowered the levels of AngⅡ and ET1 in the serum （P<0.05）， increased the p-eNOS/eNOS value， and inhibited iNOS expression （P<0.05）. Compared with the AngⅡ group， STDP increased the NO content and decreased the ET1 content in endothelial cells （P<0.05）， increased the p-eNOS/eNOS ratio， and inhibited the iNOS expression （P<0.05）. The ACE2 inhibitor MLN-4760 reversed the regulatory effects of STDP on p-eNOS， eNOS， and iNOS. ConclusionSTDP improves the cardiac function in the rat model of heart failure， enhances the synthesis and release of NO in cardiac microvascular endothelial cells， reduces AngⅡ and ET1 levels， and regulates the expression of p-eNOS and eNOS， thereby ameliorating the dysfunction of microvascular endothelial cells in heart failure. This mechanism is related to the upregulation of the expression of proteins in the ACE2-AT2/MAS pathway.

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.

Objective To explore the current application of high-throughput drug sensitivity(HDS)testing in children with relapsed and refractory acute leukemia(RR-AL)and analyze the feasibility of salvage treatment plans.Methods A retrospective collection of clinical data from children with RR-AL who underwent HDS testing at the Department of Children's Hematology and Oncology of the First Affiliated Hospital of Zhengzhou University from November 2021 to October 2023 was conducted,followed by an analysis of drug sensitivity results and treatment outcomes.Results A total of 17 children with RR-AL underwent HDS testing,including 7 cases of relapsed refractory acute myeloid leukemia and 10 cases of relapsed refractory acute lymphoblastic leukemia.The detection rate of highly sensitive chemotherapy drugs/regimens was 53%(9/17),while the detection rate of moderately sensitive chemotherapy drugs/regimens was 100%(17/17).Among the 17 RR-AL patients with highly and moderately sensitive chemotherapy drugs and regimens,the MOACD regimen(mitoxantrone+vincristine+cytarabine+cyclophosphamide+dexamethasone)accounted for 100%,with the highest inhibition rate for single-agent mitoxantrone(94%,16/17),and the highest inhibition rate for targeted therapy being bortezomib(94%,16/17).Nine patients adjusted their chemotherapy based on HDS testing results,with 4 undergoing hematopoietic stem cell transplantation.Four patients achieved disease-free survival,while 5 died.Eight patients received empirical chemotherapy,with 2 undergoing hematopoietic stem cell transplantation;4 achieved disease-free survival,while 4 died.Conclusions HDS testing can identify highly sensitive drugs/regimens for children with RR-AL,improving the rate of re-remission and creating conditions for subsequent hematopoietic stem cell transplantation.

Perioperative bleeding is closely related to the prognosis of patients, and massive blood loss can lead to serious adverse events. Tranexamic acid, a lysine derivative, exerts anti-fibrinolytic effects by competitively blocking lysine binding sites on plasminogen to achieve hemostasis. Perioperative use of tranexamic acid can effectively reduce the risk of bleeding and the need for blood transfusion, and reduce the risk of bleeding related complications and death. At present, the use of tranexamic acid for perioperative hemostasis is increasingly widespread, and it is gradually entering the consensus and guidelines in more surgical fields. In this paper, the mechanism of action, perioperative application and adverse reactions of tranexamic acid were reviewed, and the effectiveness and safety of tranexamic acid in different surgical types were discussed, so as to provide reference for the application and research of tranexamic acid in China.

Hepatic encephalopathy is a clinical syndrome of central nervous system dysfunction caused by liver insufficiency.It severely affects the quality of life of patients and may lead to death.Accurate prediction of the risk of developing hepatic encephalopathy is crucial for early intervention and treatment.In order to identify the risk of hepatic encephalopathy in patients in advance,many studies have been devoted to efforts to develop tools and methods to identify the risk of hepatic encephalopathy as early as possible,so as to develop preventive and early management strategies.Most conventional hepatic encephalopathy risk prediction models currently assess the prob-ability of a patient developing hepatic encephalopathy by analysing factors such as clinical data and biochemical indicators,however,their accuracy,sensitivity and positive predictive value are not high.The application of artificial intelligence to clinical predictive modelling is a very hot and promising area,which can use large amounts of data and complex algorithms to improve the accuracy and efficiency of diagnosis and prognosis.To date,there have been few studies using AI techniques to predict hepatic encephalopathy.Therefore,this paper reviews the research progress of hepatic encephalopathy risk prediction models,and also discusses the prospect of AI application in hepatic encephalopathy risk prediction models.It also points out the challenges and future research directions of AI in HE risk prediction model research in order to promote the development and clinical application of hepatic encephalopathy risk prediction models.