OBJECTIVE: To investigate the effect and relative mechanism of Recombinant Human Thrombopoietin (rhTPO) on long-term hematopoietic recovery in mice with acute radiation sickness. METHODS: Mice were intramuscularly injected with rhTPO (100 μg/kg) 2 hours after total body irradiation with ⁶⁰Co γ-rays (6.5 Gy). Moreover, six months after irradiation, peripheral blood, hematopoietic stem cells (HSC) ratio, competitive transplantation survival rate and chimerization rate, senescence rate of c-kit⁺ HSC, and p16 and p38 mRNA expression of c-kit⁺ HSC were detected. RESULTS: Six months after 6.5 Gy γ-ray irradiation, there were no differences in peripheral blood white blood cells, red blood cells, platelets, neutrophils and bone marrow nucleated cells in normal group, irradiated group and rhTPO group (P>0.05). The proportion of hematopoietic stem cells and multipotent progenitor cells in mice of irradiated group was significantly decreased after irradiation (P<0.05), but there was no significant changes in rhTPO group (P>0.05). The counts of CFU-MK and BFU-E in irradiated group were significantly lower than that in normal group, and rhTPO group was higher than that of the irradiated group(P<0.05). The 70 day survival rate of recipient mice in normal group and rhTPO group was 100%, and all mice died in irradiation group. The senescence positive rates of c-kit⁺ HSC in normal group, irradiation group and rhTPO group were 6.11%, 9.54% and 6.01%, respectively (P<0.01). Compared with the normal group, the p16 and p38 mRNA expression of c-kit⁺ HSC in the irradiated mice were significantly increased (P<0.01), and it was markedly decreased after rhTPO administration (P<0.01). CONCLUSION The hematopoietic function of mice is still decreased 6 months after 6.5 Gy γ-ray irradiation, suggesting that there may be long-term damage. High-dose administration of rhTPO in the treatment of acute radiation sickness can reduce the senescence of HSC through p38-p16 pathway and improve the long-term damage of hematopoietic function in mice with acute radiation sickness.
Humans ; Mice ; Animals ; Thrombopoietin/metabolism* ; Hematopoietic Stem Cells ; Blood Platelets ; Recombinant Proteins/therapeutic use* ; Radiation Injuries ; RNA, Messenger/metabolism*

OBJECTIVE: To compare the effects of artificial liver treatment with double plasma molecular adsorption system(DPMAS) mode and traditional plasma exchange (PE) mode on platelets in patients, and to evaluate the clinical efficacy of recombinent human thrombopoietin (rhTPO) in the treatment of thrombocytopenia. METHODS: A total of fifteen patients undergoing artificial liver with DPMAS model admitted to the Fifth Affiliated Hospital of Guangzhou Medical University from January 2018 to November 2020 were selected and included in the DPMAS group, and another 15 patients receiving PE were selected and included in the PE group. The improvement of clinical symptoms, such as fatigue, jaundice, oliguria, edema, etc. before and after artificial liver treatment was compared between the two groups, and the trend of blood routine (especially platelet), coagulation function and other indexes before and after treatment were compared between the two groups. The use of rhTPO and the number of platelets were recorded during treatment. RESULTS: The improvement rate of clinical symptoms in DPMAS group was 86.67%, which was higher than that in PE group, but the difference was not statistically significant (P>0.05). There was no statistical significance in the outcome of the two groups within 90 days (P>0.05). There was no significant difference in white blood cell (WBC) and hemoglobin (HB) between the two groups after treatment (P>0.05). However, the level of platelet(PLT) in DPMAS group was significantly lower than that before treatment (P < 0.05), and was significantly lower than that in PE group (P < 0.05). After treatment, the international normalized ratio (INR) level in PE group was significantly improved (P < 0.05), but there was no significant difference in the INR level in DPMAS group (P>0.05). The patients in the DPMAS group received an average of (8.2±3.1) doses of rhTPO and (1.5±0.3) IU of platelet transfusions during hospitalization. In DMPAS group, platelets increased significantly after infusion of terbium. CONCLUSION Compared with PE mode, the artificial liver with DPMAS mode can reduce platelet levels in patients, but the application of rhTPO can stimulate platelet regeneration and increase platelet levels in the patients, thereby reducing the risk of bleeding due to platelet hypoplasia.
Blood Platelets ; Humans ; Liver, Artificial ; Plasma Exchange ; Recombinant Proteins ; Thrombocytopenia/therapy* ; Thrombopoietin

OBJECTIVE: To investigate the effect of recombinant human thrombopoietin (rhTPO) on thrombocytopenia (TCP) induced by endotoxin lipopolysaccharide (LPS) in mice. METHODS: Sixty male C57BL/6 mice were divided into normal saline (NS) control group (NS group), sepsis-induced TCP model group (LPS group) and rhTPO treatment group (LPS+rhTPO group) by random number table with 20 mice in each group. Sepsis-induced TCP model was reproduced by one intraperitoneal injection of LPS 30 mg/kg, and the mice in NS group were given the same amount of NS. In LPS+rhTPO group, 2.7 kU/kg rhTPO was subcutaneously injected into mice immediately after intraperitoneal injection of LPS, once every 24 hours. The mice in NS group and LPS group were injected subcutaneously with the same amount of NS. The observation period of each group lasted for 72 hours. The inner canthus blood was harvested before and every 24 hours after modeling, and the platelet count (PLT) was measured by animal blood cell counter. The eyeball blood of mice was harvested at 72 hours after modeling, and the proportion of CD61⁺CD62p⁺ cells in platelet-rich plasma was detected by flow cytometry, by which the platelet activation was reflected. Lung and spleen tissues of mice were harvested, and the positive expression of CD41 was determined by immunohistochemistry, by which the platelet sequestration in organs was reflected. Bone marrow cells from unilateral femur of mice were harvested, and the proportion of CD41⁺CD61⁺ cells was determined by flow cytometry to reflect the proliferation of bone marrow megakaryocytes. RESULTS: There was no significant difference in PLT among the groups before modeling. With the extension of the time after modeling, PLT in LPS group was decreased continuously, and increased slightly at 72 hours, but it was still significantly lower than that in NS group (×10⁹/L: 308.60±21.70 vs. 1 152.72±50.27, P < 0.05); PLT in LPS+rhTPO group was increased continuously with the extension of modeling time, and it was significantly higher at 72 hours than that in LPS group (×10⁹/L: 926.78±48.85 vs. 308.60±21.70, P < 0.05). At 72 hours after modeling, the proportion of CD61⁺CD62p⁺ cells in platelet-rich plasma of LPS group was significantly higher than that of NS group [(25.07±2.55)% vs. (4.17±0.38)%, P < 0.05], while the value in LPS+rhTPO group was significantly lower than that of LPS group [(15.92±1.26)% vs. (25.07±2.55)%, P < 0.05]. The proportion of CD41⁺CD61⁺ cells in bone marrow megakaryocytes of LPS group was significantly higher than that of NS group [(11.84±0.80)% vs. (3.60±0.42)%, P < 0.05], and the proportion of CD41⁺CD61⁺ cells in LPS+rhTPO group was significantly higher than that in LPS group [(30.96±2.49)% vs. (11.84±0.80)%, P < 0.05]. Immunohistochemistry showed that the positive expressions of CD41 in lung and spleen tissues of LPS group increased significantly than NS group [A value: 828.94±119.30 vs. 447.09±16.19 in lung tissue, (280.15±16.71)×10³ vs. (0.65±0.26)×10³ in spleen tissue, both P < 0.05], while the positive expressions of CD41 in lung and spleen tissues of LPS+rhTPO group decreased significantly than LPS group [A value: 542.78±2.95 vs. 828.94±119.30 in lung tissue, (129.40±13.49)×10³ vs. (280.15±16.71)×10³ in spleen tissue, both P < 0.05]. CONCLUSIONS The rhTPO in endotoxin-induced TCP may stimulate the proliferation of bone marrow megakaryocytes, inhibit platelet activation and affect platelet sequestration in organs, so as to increase platelet levels.
Animals ; Blood Platelets ; Humans ; Male ; Mice ; Mice, Inbred C57BL ; Platelet Count ; Recombinant Proteins ; Thrombocytopenia ; Thrombopoietin

The main physiological function of megakaryocytes is the production of platelets, whose development, maturation and platelet production are a complex regulatory process, and are involved in many factors. In recent years it was found that the lung is also the main site of megakaryocyte-producing platelets in addition to bone marrow. Based on the findings of recent years, this review summarizes the process of megakaryocyte development, maturation and platelet production, with emphasis on the analyzing the regulatory effects of apoptotic factors, miRNA, thrombopoietin and its receptors, interleukins, transcription factors and their corresponding signal pathways on platelet production. To understand the regulatory mechanism of platelet production can help to understand the pathological mechanism of platelet-related diseases and provide new ideas for the diagnosis and treatment of platelet-related diseases.
Blood Platelets ; Bone Marrow Cells ; Megakaryocytes ; Thrombopoiesis ; Thrombopoietin

Objective: To investigate and analyze the impact on PLT recovery of recombinant human thrombopoietin (rhTPO) in severe aplastic anemia (SAA) patients with allogeneic hematopoietic stem cell transplantation (allo-HSCT). Methods: A retrospective analysis of Hematology Division of General Hospital of Jinan Military Command was conducted in the 85 SAA cases who treated with allo-HSCT from January 2010 to March 2017. According to the administration of medicines for platelets, 85 patients were divided into rhTPO group (n=29), rhIL-11 group (n=27) and blank group (n=29), respectively. The median time of PLT ≥20×10⁹/L, PLT ≥50×10⁹/L, and PLT ≥100×10⁹/L, the numbers of megakaryocytes in marrow smear (25±5) days after transplantation and the quantities of platelet transfusion were analyzed retrospectively. The adverse events of rhTPO and rhIL-11 groups were observed. Results: There were no significant differences in the recovery of granulocytes and PLT ≥20×10⁹/L among the three groups (P>0.05). The time of PLT ≥50×10⁹/L in rhTPO group was shorter than that in blank group [16.5 (11-39) d vs 22 (14-66) d, P<0.05], as well as the time of PLT ≥100×10⁹/L [rhTPO: 23 (12-51) d; rhIL-11: 28 (12-80) d; blank group: 35 (18-86) d, P<0.05]. Platelet transfusions were also less in rhTPO group than in rhIL-11 and blank groups [20 (10-30) U, 30 (10-50) U, 35 (10-70) U, P<0.05]. The counts of megakaryocyte in rhTPO group, rhIL-11 group and blank group were 31.5 (0-200), 12 (0-142) and 11(0-187) (P<0.05), respectively. The difference between rhTPO group and rhIL-11 group was statistically significant (P<0.05), but no difference between rhIL-11 group and blank group (P>0.05). Multivariate analysis showed that rhTPO was an independent factor for platelet recovery [HR=4.01 (95%CI 1.81-9.97), P=0.010]. The rhTPO group had no obvious adverse events. Conclusion: rhTPO can promote platelet recovery of SAA patients after allo-HSCT, reduce platelet transfusion with safety.
Anemia, Aplastic/therapy* ; Blood Platelets ; Hematopoietic Stem Cell Transplantation ; Humans ; Platelet Count ; Recombinant Proteins ; Retrospective Studies ; Thrombopoietin

OBJECTIVETo evaluate the efficacy and safety of high dose dexamethasone combined with recombinant human thrombopoietin (rhTPO) in adults with severe newly diagnosed immune thrombocytopenia (ITP).

METHODSForty-eight adult patients with severe ITP were randomized into two groups, experimental group and control group. The patients in experimental group were given high-dose dexamethasone combined with rhTPO treatment, the patients in control group were given single high-dose dexamethasone treatment. Platelet count, platelet increase, as well as the overall response rate were strictly observed in the process. At the same time, the patient's drug tolerance and any adverse drug reactions were observed.

RESULTSThe platelet counts and platelet increase of the patients in experimental group were significantly higher than that in control group (P<0.05) at day 3, 7, 14, 30. There was no significant difference in overall response rates between the two groups (34.8% vs 36.0%, 56.5% vs 48.0%, P>0.05) at day 3, 7. The overall response rates of experimental group at day 14, 30 were significantly higher than that of control group (91.3% vs 68.0%, 82.6% vs 52.0%, P<0.05). The muscle aches occurred in one patient in experimental group which was self-recovery without special treatment.

CONCLUSIONrhTPO combined with high-dose dexamethasone could rapidly increase the platelet count, reduce the risk of bleeding, and prolonge the effect with a low incidence of tolerable adverse events compared to single high-dose dexamethasone. rhTPO combined with high-dose dexamethasone could be a new therapeutic choice for severe primary ITP.

Adult ; Blood Platelets ; Dexamethasone ; administration & dosage ; therapeutic use ; Humans ; Platelet Count ; Purpura, Thrombocytopenic, Idiopathic ; drug therapy ; Recombinant Proteins ; administration & dosage ; therapeutic use ; Thrombopoietin ; administration & dosage ; therapeutic use ; Treatment Outcome

OBJECTIVETo evaluate the impact of recombinant human thrombopoietin (rhTPO) on short-term response of immunosuppressive therapy (IST) in patients with newly diagnosed acquired severe aplastic anemia (SAA).

METHODSThe clinical data of forty adult acquired SAA patients, who treated with IST combined with rhTPO, were retrospective analyzed and the hematologic recovery were compared with patients by the IST alone during the same period. The factors affecting the short-term response were also analyzed.

RESULTSAt 3 months after IST, both the total response rate and CR+GPR rate in rhTPO group were much higher than those in control group (75.0% vs 50.0%, P=0.022; and 17.5% vs 2.5%, P=0.025). At 6 months after IST, there was no difference of total hematologic response rate in rhTPO group and control group (77.5% vs 57.5%, P=0.058), while the CR+GPR rate was still higher in rhTPO group (45.0% vs 22.5%, P=0.033). The median time of platelet transfusion independence was much shorter in rhTPO group [33(0-90) vs 53(0-75) d, P=0.019]. Patients in rhTPO group needed less platelets transfusion support. The median platelet count in rhTPO group was 29(4-95)×10⁹/L at 3 months after IST, which was much higher than that in control group [29(4-95)×10⁹/L, P=0.006]. There was no significant difference regarding overall survival between the two groups (100.0% vs 91.0%, P=0.276).

CONCLUSIONrhTPO is effective in promoting platelet recovery and improving the hematopoietic response for SAA patients with IST.

Anemia, Aplastic ; Blood Platelets ; Humans ; Immunosuppression ; Platelet Count ; Platelet Transfusion ; Recombinant Proteins ; Retrospective Studies ; Thrombopoietin

No abstract available.
Adult ; Biomarkers, Tumor/genetics ; Bone Marrow/pathology ; Calreticulin/genetics ; Erythropoietin/blood ; Female ; Fusion Proteins, bcr-abl/*genetics ; Hematocrit ; Hemoglobins/analysis ; Humans ; Janus Kinase 2/genetics ; Male ; Middle Aged ; Mutation ; Myeloproliferative Disorders/*diagnosis/genetics ; Polycythemia Vera/*diagnosis/genetics ; Receptors, Thrombopoietin/genetics ; Thrombocythemia, Essential/diagnosis ; World Health Organization

The aim of this study was to investigate the radioprotective effect of recombinant murine interleukin 12 (rmIL-12) on mice irradiated by γ-ray. Fifty- six BALB/c mice were totally irradiated by 6.0 Gy of (60)Co γ-ray and randomly divided into irradiation control group,rmIL-12 treated group and recombinant murine thrombopoietin (rmTPO) treated group.The 5 and 20 µg/kg of rmIL-12 were administrated intraperitoneally at 24 h before irradiation respectively (low and high dose rmIL-12 treated group), 15 µg/kg of rmTPO was administrated subcutaneously at 30 min and 24 h following irradiation in rmTPO treated group. The general conditions of mice were observed twice a day, the changes in body weight and peripheral blood cell counts were examined once every three days, bone marrow cells were collected to perform colony cultivation at day 14 and 28 after irradiation. The results showed that the general conditions of mice in rmIL-12 treated group were better than those in irradiation control group. Compared with the irradiation control group,5 and 20 µg/kg rmIL-12 treatment significantly promoted platelet recovery, resulting in less profound nadirs (15.9% vs 8.1%,18.2% vs 8.1%,P < 0.01) and rapid recovery to normal levels (11 days vs 14 days). WBC count recovery rate in rmIL-12 treated group was faster than that in the irradiation control group. The WBC and platelet count recovery rate in 5 µg/kg rmIL-12 treated group were as fast as that in the rmTPO treated group, both of which were slower than that in 20 µg/kg rmIL-12 treated group (P > 0.05). Semi-solid bone marrow cell culture also demonstrated that rmIL-12 could stimulate bone marrow cells to form more CFU-Mix than those in the irradiation control group in vitro at day 14 and 28 after irradiation(P < 0.01).There was no significant difference between rmIL-12 and rmTPO treated groups (P > 0.05), CFU-GM counts in 5 µg/kg rmIL-12 treated group and rmTPO treated group at day 28 after irradiation were higher than those in irradiation control group(P < 0.05), but less than those in 20 µg/kg rmIL-12 treated group (P < 0.05). It is concluded that rmIL-12 has a significant radioprotective effect on mice irradiated by γ-ray.
Animals ; Blood Platelets ; Gamma Rays ; Interleukin-12 ; therapeutic use ; Male ; Mice ; Mice, Inbred BALB C ; Platelet Count ; Radiation Injuries, Experimental ; blood ; Radiation-Protective Agents ; therapeutic use ; Recombinant Proteins ; therapeutic use ; Thrombopoietin ; therapeutic use ; Whole-Body Irradiation

OBJECTIVETo evaluate the efficacy and safety of thrombopoietin (TPO) on platelet engraftment in hematological malignancies patients after allogeneic haematopoietic stem cell transplantation (allo-HSCT).

METHODSOne hundred and twenty patients were enrolled in a multicenter, open-label, randomized, controlled clinical trial, and were randomized into 4 treatment groups following allo-HSCT. Group A was the control arm without TPO, while group B, C and D were trial arms with received 300 U×kg(-1)×d(-1) of TPO starting from day +1, +4 and +7, respectively. A total of 89 cases were evaluated, of which 22 cases in group A, 23 in group B, 20 in group C and 24 in group D. Efficacy evaluation (the time of platelet engraftment, the number of platelet transfusion) and safety evaluation \[adverse events, routine blood tests, liver and renal function, coagulation function and occurrence of graft-versus-host disease (GVHD)\] were observed.

RESULTSThe median platelet engraftment time in experimental groups (groups B, C and D) were on day (13.17 ± 2.89), day (12.15 ± 2.08), day (12.33 ± 1.76), respectively, and that in control group was on day (14.82 ± 5.05). There was statistically significant difference between two groups (P = 0.029), There were no statistically significant difference in the average amount of platelet transfusion, platelet engraftment time, and platelet nadir value among the 3 experimental groups. No significant adverse events were observed in experimental groups.

CONCLUSIONSTPO administration following allo-HSCT for patients with hematologic malignancies appears to shorten platelet engraftment time. TPO given starting from day +7 is effective and safe.

Adolescent ; Adult ; Blood Platelets ; Child ; Female ; Hematologic Neoplasms ; surgery ; Hematopoietic Stem Cell Transplantation ; Humans ; Male ; Middle Aged ; Platelet Transfusion ; methods ; Thrombopoietin ; therapeutic use ; Transplantation, Homologous ; Young Adult