An absorbable hemostatic material based on polysaccharide was prepared. The concentration of blood cells and coagulation factors was increased by reducing the water content in the blood, so as to reduce the coagulation time and achieve the purpose of rapid hemostasis. The specific surface area of starch was increased by using hydrochloric acid to hydrolyze potato starch, which made it easier to combine with α-amylase and increased the degradation rate. Starch was crosslinked into microspheres by crosslinking agent, which made the particle size uniform and greatly improved the water absorption. The surface modification of crosslinked starch microspheres with carboxymethyl group can further improve the water absorption of hemostatic materials. The results showed that the water absorption rate of our hemostatic material was more than 800%, and the average hemostatic time in the animal model was 138.7s. Compared with the imported products on the market, our hemostatic material have better hemostatic performance.
Animals ; Hemostasis ; Hemostatics/pharmacology* ; Polysaccharides/pharmacology* ; Starch/pharmacology* ; Water/pharmacology*

To evaluate the effectiveness and safety of self-prepared absorbable hemostatic fibrils.A kind of absorbable hemostatic fibrils were prepared by self-developed patent technique. The physical form and molecular structure of the fibrils and a marketed product Surgicel were characterized by general observation and infrared spectroscopy; the carboxyl content, pH value and relative molecular mass of fibrils were determined by potentiometric titration method, pH meter and copper ethylenediamine method, respectively. The behavior of the fibrils and Surgicel in contact with blood was observed by inverted microscope, the cytotoxicity was evaluated by agarose diffusion cell assay . The external iliac artery hemorrhage model and the back muscle infiltration model in rats were established. The hemostatic effectiveness of the fibrils was investigated by hemostasis time and blood weight, and the degradation and biosafety of fibrils were investigated by observation photography, immune organ weighing, hematology and coagulation index measuring, and histopathological examination. The fibrils and Surgicel had similar molecular structures. Compared with the raw material regenerated cellulose, the typical carboxyl stretching vibration absorption peak of -COOH appeared near in both fibrils and Surgicel. The carboxyl content of the two materials was about 20%, and the pH value was about 3. The relative molecular mass of the fibers after oxidation was 4466±79, which was close to that of Surgicel(>0.05). After contacting with blood, the volume of fibrils and Surgicel expanded, and absorbed blood of dozens of times as their own weight. The results of agar diffusion test showed that the fibrils had no cytotoxicity. The results of animal experiments showed that the hemostasis completed within and there was no significant difference in blood weight and speed of hemostasis between two products (both >0.05). The fibrils could be degraded 1 week after being implanted to the bleeding sites of the muscle. There were no pathological effects on the appearance, body weight, food intake, immunological tissue thymus, spleen, lymph nodes, hematology and coagulation indexes of the rats, and no obvious abnormality found in the histopathological examination. The prepared absorbable hemostatic fibrils have excellent biological safety and effectiveness.
Animals ; Cellulose/pharmacology* ; Hemostasis ; Hemostatics/pharmacology* ; Rats ; Spleen

Whether in war or peace, timely, effective and accurate hemostasis is an important measure to improve the survival rate and cure rate of the wounded. All the countries in the world are actively developing different types of hemostatic materials so as to reduce the amount of bleeding in an emergency and create favorable conditions for subsequent transport and treatment. At present, the commercialized hemostatic materials are mainly divided into natural biological, synthetic biological, mineral and coagulation components, but all these materials have their own limitations. In this article, the characteristics of chitosan and its derivatives are reviewed as the representatives of the natural organic macromolecular polysaccharide hemostasis materials. Their molecular structures, biomedical properties, domestic and foreign research and application progress as well as comparison with applications of other hemostatic materials are involved. The further research is prospected for optimization and innovation to develop composite chitosan hemostatic materials with the function of hemostasis, antibiosis, pain relief and promoting wound healing.
Blood Coagulation ; Chitosan/pharmacology* ; Hemorrhage ; Hemostasis ; Hemostatics ; Humans

Effective haemostatic materials can quickly control bleeding and achieve the purpose of saving patients' lives. In recent years, chitosan-based haemostatic materials have shown good haemostatic effects, but their application is limited because chitosan is almost insoluble in water. Carboxymethyl chitosan-based haemostatic materials can promote hemostasis by activating red blood cells and aggregating platelets. In addition, carboxymethyl chitosan can bind with Ca²⁺ to activate platelets and coagulation factors, and start endogenous coagulation pathways, which can adsorb fibrinogen in plasma to promote haemostasis. In this paper, the latest research progress of carboxymethyl chitosan-based haemostatic materials and their haemostatic mechanism were reviewed, in order to further strengthen the understanding of the haemostatic mechanism of carboxymethyl chitosan-based haemostatic materials, and provide new idea for the research and clinical application of carboxymethyl chitosan-based haemostatic materials.
Humans ; Hemostatics ; Chitosan/pharmacology* ; Hemostasis ; Blood Coagulation/physiology* ; Hemorrhage

OBJECTIVE: A dynamic gel loaded with lyophilized platelet-rich plasma-chitosan/difunctionalized polyethylene glycol (LPRP-CP) was prepared to investigate its hemostatic antibacterial and promoting wound healing of scald wounds through in vitro and in vivo experiments. METHODS: In this study, normal gauze/blank tablet (Ctrl), LPRP-CP, Chitosan HUCHUANG Powder(Chito P)and ChitoGauze XP PRO group (Chito G group) were set. The hemostatic effect and promoting healing effect of the four groups of materials were evaluated by establishing rabbit ear artery hemorrhage model and superficial Ⅱ° scalded model of skin on the back. The hemostatic time and bleeding amount were calculated and the gross and histological results of scald healing were observed. The antibacterial effect of the four groups of materials was evaluated by antibacterial test in vitro. RESULTS: In the rabbit ear arterial hemorrhage model, the hemostasis of all materials was successful. The hemostatic time of Ctrl, Chito P, LPRP-CP and Chito G groups was 213.33±38.30, 118.33±24.01, 115.00±8.37 and 111.67±11.69 s, respectively. The blood loss was 1233.83±992.27, 346.67±176.00, 193.33±121.47 and 147.50±80.66 mg, respectively. Compared with Ctrl, the hemostasis time of LPRP-CP, Chito P and Chito G group was significantly shorter (P<0.001), and the amount of blood loss of LPRP-CP and Chito G group was decreased (P<0.05). Compared with LPRP-CP, there were no significant differences in hemostatic time and blood loss between Chito P and Chito G group (P>0.05). In the model of superficial Ⅱ° scalded on the back of rabbit, the wound healing rate of LPRP-CP was faster than that of the other three groups at the same time, and the healing effect was perfect. In the antibacterial test in vitro, only LPRP-CP had better anti-S. aureus effect, and all groups had no anti-E. coli effect. CONCLUSION LPRP-CP is an excellent hemostatic material for superficial wounds, and has certain antibacterial and wound healing effects, which has a wide academic value and research prospects.
Animals ; Anti-Bacterial Agents/pharmacology* ; Chitosan/pharmacology* ; Hemorrhage ; Hemostasis ; Hemostatics ; Humans ; Platelet-Rich Plasma ; Rabbits

This article aims to establish the fingerprints, determine the hemostatic pharmacodynamic indicators, and explore the spectrum-effect relationship of Notoginseng Radix et Rhizoma in 12 different specifications. Firstly, HPLC and liquid chromatography-mass spectrometry(LC-MS) were employed to establish the fingerprints of Notoginseng Radix et Rhizoma. The rat plasma recalcification experiment and the rat gastric bleeding experiment were conducted to determine the pharmacodynamic indicators, including plasma recalcification time(PRT), thrombin time(TT), prothrombin time(PT), and activated partial thromboplastin time(APTT). Afterwards, the partial least squares method was employed to explore the spectrum-effect relationship of Notoginseng Radix et Rhizoma in different specifications. Twenty-six common peaks were detected in the HPLC fingerprints of different specifications of Notoginseng Radix et Rhizoma, and 11 out of the 26 common peaks represented saponins. The content of dencichine was determined by LC-MS. The rat experiments showed that the pharmacodynamic indicators were significantly different among different specifications of Notoginseng Radix et Rhizoma. The spectrum-effect relationship was explored between 27 common components and pharmacodynamic indicators. Among them, 16 components had positive effects on the pharmacodynamic indicators of Notoginseng Radix et Rhizoma, and 11 exerted negative effects. This study provides a basis for the precision medication and quality control of Notoginseng Radix et Rhizoma.
Animals ; Chromatography, High Pressure Liquid ; Drugs, Chinese Herbal/pharmacology* ; Hemostatics ; Quality Control ; Rats ; Rhizome ; Saponins

This dissertation is to determine the biopotency of hemostat which processed in different places by establishing a bioassay method of Bletillae Rhizoma based on the thrombin time. Contrast test is the main methodology. Specifically, the reference substance of Bletillae Rhizoma is determined by comparing with the control substance of vitamin K1 using thrombin time, which is calibrated the Bletillae Rhizoma. The hemostatic biopotency is calculated by using the method of "parallel line assay method based on quantitative responses" (3.3) from different processed products. It indicates that there is a strong linear correlation between Bletillae Rhizoma and control drugs (Y = 66.332-23.913X, R2 = 0.995 3). The hemostatic biopotency of Bletillae Rhizoma from different processed products ranged between 821.93-1 187.53 U x g(-1) shown in the paper, and all of them can meet the requirements of the test. The methodology has an appropriate instrument precision (RSD 3.8%), intermediate precision (RSD 4.6%), repeatability (RSD 3.2%) and stability (RSD 3.7%). Therefore, it can be turned out that the methodology which established in the dissertation is good at determinating the hemostatic biopotency of Bletillae Rhizoma and it is reliable, simple and repeatable.
Animals ; Drugs, Chinese Herbal ; pharmacology ; standards ; Hemostatics ; pharmacology ; standards ; Orchidaceae ; chemistry ; Rats ; Rats, Sprague-Dawley ; Rhizome ; chemistry ; Thrombin Time

A porous composite particle (CP) was fabricated by the methods of emulsification and cross-link based on chitosan, alginate and collagen protein, and the tranexamic acid-loaded composite particles (TACP) was prepared by immersing the composite particle into the solution of tranexamic acid and by freeze drying. In the hepatic and splenic hemorrhage model of rabbits, CP and TACP were randomly used as haemostatic agents, and the Suxiaozhixuefen (Flashclot) was used as control. The corresponding hemostatic time and bleeding amount were observed respectively. The hemostatic time of CP and Flashclot were (2.48 +/- 0.88) min and (3.07 +/- 0.84) min, respectively, no significant difference was observed. However, the hemostatic time of TACP was (1.90 +/- 0.75) min, which was significantly shorter than that of CP and Flashclot (P < 0.05). In the splenic bleeding model of rabbits, similar results were obtained with these three kinds of hemostatics. These results indicated that the CP based on chitosan, alginate and collagen protein displayed similar hemostatic efficiency to Flashclot. However, the TACP might be one of promising haemostatic powders due to its more excellent hemostatic efficiency.
Alginates ; administration & dosage ; pharmacology ; Animals ; Biocompatible Materials ; chemistry ; Chitosan ; administration & dosage ; pharmacology ; Collagen ; administration & dosage ; pharmacology ; Female ; Hemostatics ; administration & dosage ; pharmacology ; Male ; Rabbits ; Tranexamic Acid ; administration & dosage ; pharmacology

The effect of chitosan with different molecular weight and deacetylation degree on blood hemostasis was tested. The experiments found evident alteration of red blood cell morphology and unusual coagglutination between erythrocytes in the anticoagulant blood which was treated by chitosan acetic acid solution. The red blood cells clot formation experiments showed that chitosan with low deacetylation degree (60%-70%) caused more red blood cells to assemble when compared versus chitosan with other deacetylation degrees. The effect of molecular weight between 10(5)-10(6) was not obvious. The thrombin time (TT), prothrombin time (PT), activated partial thromboplastin time (APTT), and concentration of fibrinogen (FIB) of blood treated by chitosan acetic acid solution were measured. The results proved that the hemostasis property of chitosan acetic acid solution was independent of the platelets and the normal "Cascade-like" coagulation pathway.
Acetic Acid ; chemistry ; pharmacology ; Animals ; Chitosan ; chemistry ; pharmacology ; Fibrinogen ; analysis ; Hemostatics ; chemistry ; pharmacology ; Partial Thromboplastin Time ; Prothrombin Time ; Rabbits ; Thrombin Time

This study was aimed to develop a new generation of ideal hemostatic powder which can be safely, effectively and easily used mainly to first aid anterior to hospital by the synergistic effect of physical and chemical hemostatic mechanisms. The tranexamic acid(TA)-loaded porous starch(PS) (TAPS) was prepared by using PS as carrier and TA as loaded drug component. The absorption property of TAPS was evaluated by water absorption; the hemostatic ability of TAPS was evaluated by test in vitro and in vivo, the blood coagulation time of TAPS was detected by using Lee-white method. The experiment was divided into 3 groups: blank control group, Yunnan Baiyao group and TAPS group, each group with 10 blood samples in vitro test; the 27 SD rats were used to test in vivo, and randomly were divided into 3 groups: PS,Yunnan Baiyao and TAPS, each group consisted of 9 rats for establishing the animal model of liver trauma and detecting the complete hemostasis time. The results showed that the water absorption of PS did not be affected by TA when dose of TA loaded in PS was <0.02 g/g PS. There was no statistic difference in blood coagulation time between TAPS and PS groups(P > 0.05). The complete hemostatic time of TAPS for trauma of left lobe liver was 236.67 ± 55.00 seconds, which was shorter than that of Yunnan Baiyao (340.00 ± 73.48 seconds) and PS (396.67 ± 68.37 seconds) (P < 0.05 and P < 0.01, respectively). It is concluded that PS can load TA and play the hemostatic effect through releasing TA; the TA loading <0.02 g/g PS did not affect the water absorption and pro-coagulation properties. The TA can enhance the hemostatic efficacy of PS, the hemostatic property of TAPS is derived from synergism of physical and chemical hemostatic mechanisms.
Animals ; Blood Coagulation Tests ; Drug Carriers ; Hemostatics ; chemical synthesis ; pharmacology ; Male ; Rats ; Rats, Sprague-Dawley ; Starch ; administration & dosage ; Tranexamic Acid ; chemical synthesis ; pharmacology