To investigate the killing effect of NK-92MI cells modified by chimeric antigen receptor (CD7-CAR) and specifically targeting CD7 to CD7
  hematological malignant cells.
 
  Three types of hematological malignant tumor cells, including 5 cases of CD7
  acute T-lymphoblastic leukemia (T-ALL), 10 cases of acute myeloid leukemia (AML) and 6 cases of T-cell lymphoma were collected, centrifuged, cultured and used to detect the expression levels of tumor cell surface targets; 7-AAD, CD56-APC, CD3-FITC, IgG Fc-PE flow cytometry were used to detected the transfection efficiency of NK-92MI and CD7-CAR-NK-92MI cells, killing efficiencies of CD7-CAR-NK-92MI cells to CD7
  hematological tumor cells in vitro were determined by flow cytometry using PE Annexin V Apoptosis Detection Kit. Secretion differences of NK-92MI and CD7-CAR-NK-92MI cytokines interleukin (IL)-2, interferon (IFN)-γ, and granzyme B detection were estimated by using CBA kit.
 
  The killing efficiencies of CD7-CAR-modified NK-92MI cells to CD7
  T-ALL, AML, T-cell lymphoma tumor cells were significantly higher than those of NK-92MI cells without genetical modification. The difference showed statistically significant (P＜0.05). The level of IFN-γ and granzyme B were significantly increased among cytokines secreted by CD7-CAR-modified NK-92MI cells as compared with those of NK-92MI cells without genetical modification (P＜0.05) .
 
  CD7-CAR-modified NK-92MI cells have significantly improved killing efficiency against CD7
  T-ALL, AML and T lymphoma cells, and shows specific targeting effects, which provides a clinical basis for the treatment of CD7
  hematological malignancies.
 CD7-CAR-modified NK-92MI cells have significantly improved killing efficiency against CD7+ T-ALL, AML and T lymphoma cells, and shows specific targeting effects, which provides a clinical basis for the treatment of CD7+ hematological malignancies.
  To explore the appropriate procedures for preparing extracellular microvesicles (MV) derived from human mesenchymal stem cells (MSC).
 
  Human MSCs from umbilical cords were cultured in a serum-free medium and maintained in a basal medium for 72 hours after the cell confluence reached to 80%. The supernatants of cultured cells were collected and MVs were enriched. MVs were identified by flow cytometry and electron microscopy. The total protein amount in MVs was used as a parameter for the content of MVs. The supernatants were adjusted to different pH values, and the output of MVs was detected. The supernatants were also collected for enriching the MV and detecting the protein content of MV after the cells were maintained in the basic medium for different time.
 
  Flow cytometric analysis showed that the MVs expressed CD9, CD63 and CD81, morphologically presented round under an electron microscope and the diameter of MV was around 100 nm. After enrichment of MV, the protein content of MVs in the supernatants was 416.8±128.1, 255.4±77.9 and 142.8±46.4 μg per 10
  MSC，respectively at pH of supernatant 3, 7 and 9 (P＜0.05). The protein content of the supernatants per 10
  MSC was 173.6±44.5, 262.4±49.6 and 364.2±37.8 μg respectively after starvation culture for 48, 72 and 96 hrs (P＜0.05).
 
  MVs can be readily collected after MSCs were starved for 96 hours, and the pH of the supernatants is adjusted at 3.0.
 MVs can be readily collected after MSCs were starved for 96 hours, and the pH of the supernatants is adjusted at 3.0.
  To explore the method for inducing the differentiation of bone marrow cells into megakaryocytes in vitro so as to use for evaluating the activity of traditional Chinese medicines.
 
  The bone marrow cells were separated from femurs and tibias of mice. The experiments were divided into 4 groups control (no adding cytokines), TPO (adding 50 ng/ml TPO), TPO+SCF (50 ng/ml+50 ng/ml) and TPO+SCF+IL-6+IL-9 (50 ng/ml+50 ng/ml+20 ng/ml+20 ng/ml). The bone marrow cells in 4 groups were cultured in vitro for 6 d. Then the cell growth status was observed by the inverted microscopy, and the cell count was detected by using the automatic cell counter. The ratio and absolute count of megakaryocytes were detected by flow cytometry.
 
  Compared with control, three induction methods could stimulate the differentiation of bone marrow cells into megakaryocytes in vitro. TPO could slightly enhance the differentiation of bone marrow cells into megakaryocytes. Both the combination of TPO and SCF, and the combination of TPO, SCF, IL-6 and IL-9 could intensively stimulate proliferation of bone morrow cells and promote the differentiation of bone marrow cells into megakaryocytes. The addition of IL-6 and IL-9 could decrease the proliferation of non-megakaryocytes, but promote the differentiation of bone marrow cells into megakaryocytes.
 
  The optimized differentiation of bone marrow cells into megakaryocytes has been completed by co-induction regimen of TPO, SCF, IL-6 and IL-9, which can be used to screen and evaluate traditional Chinese medicines promoting formation of platelets.
 The optimized differentiation of bone marrow cells into megakaryocytes has been completed by co-induction regimen of TPO, SCF, IL-6 and IL-9, which can be used to screen and evaluate traditional Chinese medicines promoting formation of platelets.
  To investigate the effect of PDGFRα
  stromal cells derived SCF on hematopoiesis of adult mice.
 
  Pdgfrα-CreER; R26-tdTomato mice model was constructed, and the proportion and distribution of PDGFRα
  cells in the liver, spleen, lung, kidney and bone marrow were analyzed by flow cytometry and confocal microscopy. Then the Pdgfrα-CreER; Scf 
  mice model was further constructed, the Scf in PDGFRα
  was knocked out specifically, the effect of Scf-knocked out in PDGFRα
  stromal cells in the propitiation of HSPCs in the bone marrow was analyzed by flow cytometry.  https://www.selleckchem.com/products/pnd-1186-vs-4718.html  The effect of SCF on the proportion on number of peripheral blood cells in mice was analyzed by whole blood analyzer.
 
  After Scf was knocked out in PDGFRα
  stromal cells, the propitiation and number of LKS- cell, LKS+ cell, HSC, MPP1, MKP, PreGM, PreMegE, and CFU-E in the bone marrow of mice was decreased, as well as in the number of red blood cells and hemoglobin concentration of peripheral blood. However, Scf knocked out from PDGFRα
  cells showed no effect on the hematopoiesis in spleen.