METHOD FOR CULTURING PRIMARY CELLS FROM SOLID TUMOR OF LUNG CANCER AND PRIMARY TUMOR CELLS FROM PLEURAL EFFUSION OF LUNG CANCER AND AUXILIARY REAGENTS
20220267735 · 2022-08-25
Inventors
Cpc classification
C12N5/0688
CHEMISTRY; METALLURGY
C12N2501/115
CHEMISTRY; METALLURGY
International classification
Abstract
A method for culturing primary cells from solid tumor tissues of lung cancer and primary tumor cells from pleural effusion of lung cancer, and the auxiliary reagents. A method for culturing primary cells from solid tumor tissues of lung cancer and primary tumor cells from pleural effusion of lung cancer and the auxiliary reagents. The core of the technology is as follows: (1) solid tumor of lung cancer are treated by using a mild cell dissociating reagent, and lung cancer cells in pleural effusion are dissociated by a mild method, ensuring the vitality of cancer cells to the greatest extent; (2) a special serum-free medium is prepared, and tumor cells derived from solid tumor tissues of lung cancer are cultured in vitro by using a suspension culture system, ensuring the normal amplification of the cancer cells while eliminating the interference of normal cells to the greatest extent.
Claims
1-22. (canceled)
23. A medium for culturing primary cells of lung cancer, comprising a dual-antibody P/S, HEPES, a non-essential amino acid solution, GlutaMax, human recombinant protein EGF, human recombinant protein bFGF, human recombinant protein MSP, cortisol, B27, ITS-X, Y-27632 and an Advanced DMEM/F12 medium; wherein the final concentration of penicillin in the dual-antibody P/S is 100-200 U/mL; the final concentration of streptomycin in the dual-antibody P/S is 100-200 μg/mL the final concentration of the HEPES is 8-12 mM; the final concentration of the non-essential amino acid solution is 0.8-1.2% (volume percentage); the final concentration of the GlutaMax is 0.8-1.2% (volume percentage); the final concentration of the human recombinant protein EGF is 10-100 ng/mL; the final concentration of the human recombinant protein bFGF is 10-50 ng/mL; the final concentration of the human recombinant protein MSP is 5-25 ng/mL; the final concentration of the cortisol is 20-50 ng/mL; the final concentration of the B27 is 1.5-2.5% (volume percentage); the final concentration of the ITS-X is 0.8-1.2% (volume percentage); the final concentration of the Y-27632 is 5-20 μM; and the rest is the Advanced DMEM/F12 medium.
24. A reagent set for culturing primary cells of lung cancer, which is any of the followings: (A1) Consisting of the culture medium of claim 23 and all or part of the following: sample dissociation solution, sample preservation solution and sample washing solution; the sample dissociation solution is composed of collagenase I, collagenase IV and PBS; wherein the final concentration of the collagenase I in the sample dissociation solution is 150-250 U/mL; the final concentration of the collagenase IV in the sample dissociation solution is 150-250 U/mL; and the rest is PBS; the sample preservation solution is composed of fetal bovine serum, dual-antibody P/S, HEPES and HBSS; wherein the final concentration of the fetal bovine serum in the sample preservation solution is 1-5% (volume percentage); the final concentration of the penicillin of the dual-antibody P/S in the sample preservation solution is 100-200 U/mL; the final concentration of the streptomycin of the dual-antibody P/S in the sample preservation solution is 100-200 μg/mL; the final concentration of the HEPES in the sample preservation solution is 8-12 mM; and the rest is HBSS; the sample washing solution is composed of dual-antibody P/S and PBS; wherein the final concentration of the penicillin of the dual-antibody P/S in the sample washing solution is 100-200 U/mL; the final concentration of the streptomycin of the dual-antibody P/S in the sample washing solution is 100-200n/mL; and the rest is PBS; (A2) Consisting of the culture medium and cell isolation buffer; the cell isolation buffer is composed of dual-antibody P/S, heparin sodium and PBS; wherein the final concentration of the penicillin in the dual-antibody P/S is 100-200 U/mL U/mL; the final concentration of the streptomycin in the dual-antibody P/S is 100-200 μg/mL; the final concentration of the heparin sodium is 10 IU/mL; and the rest is PBS; (A3) Consisting of (A1) and all or part of the following reagents: cell digestion solution, digestion termination solution and cell cryopreservation solution; and (A4) Consisting of (A2) and all or part of the following reagents: cell digestion solution, digestion termination solution and cell cryopreservation solution; the composition of the cell digestion solution is as follows: each 10 mL of the cell digestion solution contains 4-6 mL of Accutase, EDTA with a final concentration of 5 mM and 1.5-2.5 mL of TrypLE Express, and the rest is PBS; the sample preservation solution is composed of fetal bovine serum, dual-antibody P/S and a DMEM medium; wherein the final concentration of the fetal bovine serum in the digestion termination solution is 8-12% (volume percentage); the final concentration of the penicillin of the dual-antibody P/S in the digestion termination solution is 100-200 U/mL; the final concentration of the streptomycin of the dual-antibody P/S in the digestion termination solution is 100-200 μg/mL; and the rest is the DMEM medium; the cell cryopreservation solution is composed of an Advanced DMEM/F12 medium, DMSO and 1% methylcellulose solution; wherein the volume ratio of the Advanced DMEM/F12 medium, the DMSO and the 1% methylcellulose solution is 20:2:(0.8-1.2); and the 1% methylcellulose solution is an aqueous solution of methylcellulose with a concentration of 1 g/100 ml.
25. A method for culturing primary cells of lung cancer, which is either method A or method B: method A: a method for culturing primary cells from solid tumor tissues of lung cancer, comprising the following steps: (a1) dissociating solid tumor tissues of lung cancer with the sample dissociation solution described in claim 24, to obtain primary cells from solid tumor of lung cancer; (a2) suspension-culturing the dissociated primary cells from solid tumor of lung cancer in step (a1); method B: a method for culturing primary tumor cells from pleural effusion of lung cancer, comprising the following steps: (b1) separating primary tumor cells from pleural effusion of lung cancer, to obtain primary tumor cells from pleural effusion of lung cancer; (b2) suspension-culturing the separated primary tumor cells from pleural effusion of lung cancer in step (b1).
26. The method according to claim 25, wherein in step (a1), the solid tumor tissues of lung cancer are dissociated with the sample dissociation solution according to a method comprising the following steps: according to the dosage of 0.1-0.3 mL of sample dissociation solution per 1 mg of tissue, treating the solid tumor tissues of lung cancer, which were cut up, with the sample dissociation solution preheated to 37° C. in advance, and dissociating the sample at 37° C. for 15 minutes to 3 hours; in step (b1), the primary tumor cells from pleural effusion of lung cancer can be separated from the pleural effusion of lung cancer according to a method comprising the following steps: suspending the cells in the pleural effusion of lung cancer with the cell isolation buffer, and then obtaining the primary tumor cells from pleural effusion of lung cancer by density gradient centrifugation.
27. The method according to claim 25 wherein in step (a2), the primary cells from solid tumor of lung cancer are suspension-cultured with the culture medium according to a method comprising the following steps: using a cell culture vessel M, suspension-culturing the primary cells from solid tumor of lung cancer with the culture medium, under the condition of 37° C. and 5% CO.sub.2, and replacing the culture medium every 2-4 days; in the step (b2), the primary tumor cells from pleural effusion of lung cancer are suspension-cultured with the culture medium according to a method comprising the following steps: using a cell culture vessel M, suspension-culturing the primary tumor cells from pleural effusion of lung cancer with the culture medium, under the condition of 37° C. and 5% CO.sub.2, and replacing the culture medium every 2-4 days; the cell culture vessel M is any of the followings: (I) a cell culture vessel made of polystyrene, a cell culture vessel made of polycarbonate, a cell culture vessel made of polymethylmethacrylate, a cell culture vessel made of COC resin, a cell culture vessel made of cycloolefin polymer or a cell culture vessel with a low adsorption surface; (II) a cell culture vessel after CYTOP modification of the cell culture vessel in (I).
28. The method according to claim 27, wherein in (II), the cell culture vessel in (I) is CYTOP-modified according to a method comprising the following steps: performing pure oxygen etching on the cell culture vessel in (I) at an etching power of 20 W for 3 minutes; then covering the surface of the cell culture vessel with 1% CYTOP solution, and drying the 1% CYTOP solution in the air to complete CYTOP modification; the composition of the 1% CYTOP solution is as follows: each 100 mL of the 1% CYTOP solution contains 1 mL of CYTOP, and the rest is fluorocarbon oil.
29. The method according to claim 25, wherein before step (a1), the following steps for predissociation treatment of the solid tumor tissues of lung cancer can also be included: washing the surface of a solid tumor tissue sample of lung cancer with 70-75% ethanol (by volume); and washing the solid tumor tissue sample of lung cancer with the sample washing solution and sterile PBS solution successively.
30. The method according to claim 29, wherein the in vitro time of the solid tumor tissue sample of lung cancer subject to predissociation treatment is within 2 hours, and the solid tumor tissue sample of lung cancer is preserved in the sample preservation solution before the predissociation treatment.
31. The method according to claim 25, wherein in step (a1), the following steps are performed after dissociation treatment of the solid tumor tissues of lung cancer with the sample dissociation solution: terminating a dissociation reaction with the digestion termination solution, and collecting a cell suspension; filtering the cell suspension to remove tissue debris and adherent cells; centrifuging and then resuspending cells with sterile PBS; centrifuging again and resuspending the cell precipitation.
32. The method according to claim 25, wherein before step (a2), the following step is also included: passaging the primary cells from solid tumor of lung cancer when masses with a diameter of 80-120 μm are formed by the primary cells from solid tumor of lung cancer; in step (b2), the following step is also included: passaging the primary tumor cells from pleural effusion samples of lung cancer when masses with a diameter of 80-120 μm are formed by the primary tumor cells from pleural effusion samples of lung cancer.
33. The method according to claim 32, wherein the cell digestion solution for the passage is the cell digestion solution.
34. The method according to claim 32, wherein the digestion termination solution for the passage is the digestion termination solution.
35. The method according to claim 25, wherein the method also comprises a step of cryopreserving and/or resuscitating the primary cells from solid tumor of lung cancer or the primary tumor cells from pleural effusion of lung cancer after 2-3 passages and amplifications; the cell cryopreservation solution used for the cryopreservation is the cell cryopreservation solution.
36. The method according to claim 25, wherein the lung cancer is primary lung cancer.
37. The method according to claim 25, wherein the lung cancer is non-small-cell lung cancer or small cell lung cancer.
38. The method according to claim 37, wherein the non-small-cell lung cancer is non-small-cell lung cancer adenocarcinoma or non-small-cell lung cancer squamous cell carcinoma.
39. The method according to claim 25, wherein the primary cells of lung cancer are primary cells from solid tumor of lung cancer or primary tumor cells from pleural effusion of lung cancer.
40. The method according to claim 25, wherein the primary cells of lung cancer are isolated from surgical samples, puncture samples or pleural effusion samples of patients with lung cancer.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
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DETAILED DESCRIPTION OF THE EMBODIMENTS
[0115] The following embodiments are intended for a better understanding of the present invention, but not limiting the present invention. Unless otherwise specified, all the experimental methods in the following embodiments are conventional methods. Unless otherwise specified, all the test materials used in the following embodiments are available from the conventional biochemical stores.
Embodiment 1. Preparing Reagents for Culturing Primary Cells from Solid Tumor of Lung Cancer
[0116] 1. Sample preservation solution (100 mL).
[0117] The specific formula of sample preservation solution (100 mL) is shown in Table 1.
TABLE-US-00001 TABLE 1 Sample Preservation Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Fetal bovine Gibco#16000-044 2 mL 2% serum Dual-antibody Gibco#15140122 1 mL 1% P/S HEPES Gibco# 15630080 1 mL 10 mM HBSS Gibco# 14170161 Added to 100 mL
[0118] After being prepared, the sample preservation solution was sub-packaged in 15 mL centrifuge tubes, and each tube was filled with 5 mL. The sample preservation solution sub-packaged in the centrifuge tubes can be stored at 4° C. for 1 month.
[0119] 2. Sample washing solution (100 mL)
[0120] The specific formula of sample washing solution (100 mL) is shown in Table 2.
TABLE-US-00002 TABLE 2 Sample Washing Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Dual-antibody Gibco#15140122 1 mL 1% P/S PBS Gibco#21-040-CVR Added to 100 mL
[0121] The sample washing solution needs to be prepared just before use.
[0122] 3. Sample dissociation solution (10 mL)
[0123] The specific formula of sample dissociation solution (10 mL) is shown in Table 3.
TABLE-US-00003 TABLE 3 Sample Dissociation Solution (10 mL) Final Reagent Brand Article No. Dosage Concentration 10× collagenase 1 10× stock solution 1 mL 200 U/mL 10× collagenase IV 10× stock solution 1 mL 200 U/mL PBS Gibco#21-040-CVR Added to 10 mL Note: The sample dissociation solution needs to be prepared just before use.
[0124] In Table 3, the preparation of collagenase stock solution is shown in Tables 4 and 5.
TABLE-US-00004 TABLE 4 10× Collagenase 1 Stock Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Collagenase 1 Gibco #17100-017 1 g 2,000 U/mL PBS Gibco#21-040-CVR Added to 100 mL
[0125] After being prepared, the 10× collagenase I stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes, and each tube was filled with 1 mL. The stock solution can be stored at −20° C. for a long term.
TABLE-US-00005 TABLE 5 10× Collagenase IV Stock Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Collagenase IV Gibco #17104-019 1 g 2,000 U/mL PBS Gibco#21-040-CVR Added to 100 mL
[0126] After being prepared, the 10× collagenase IV stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes, and each tube was filled with 1 mL. The stock solution can be stored at −20° C. for a long term.
[0127] In Tables 4 and 5, the unit U of the collagenase (the collagenase I or the collagenase IV) is defined by the enzyme activity of protease: 1 μmol of L-leucine can be released by treating the collagenase (the collagenase I or the collagenase IV) with 1 U of protease for 5 hours at 37° C. and pH 7.5.
[0128] 4. Cell digestion solution (10 mL) The specific formula of cell digestion solution (10 mL) is shown in Table 6.
TABLE-US-00006 TABLE 6 Cell Digestion Solution (10 mL) Final Reagent Brand Article No. Dosage Concentration Accutase Gibco#A11105-01 5 mL 5 mM 0.5M EDTA Invitrogen# AM9261 10 μL TrypLE ™ Express Gibco#12604013 2 mL PBS Gibco#21-040-CVR Added to 10 mL
[0129] The cell digestion solution needs to be prepared just before use.
[0130] 5. Digestion termination solution (100 mL) The specific formula of digestion termination solution (100 mL) is shown in Table 7.
TABLE-US-00007 TABLE 7 Digestion Termination Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Fetal bovine serum Gibco#16000-044 10 mL 10% Dual-antibody P/S Gibco#15140122 1 mL 1% DMEMculture Gibco#11965-092 Added to 100 mL medium
[0131] The prepared digestion termination solution can be stored for 1 month at 4° C.
[0132] 6. Culture medium for primary cells from solid tumor tissues of lung cancer (100 mL) The specific formula of the culture medium for primary cells from solid tumor tissues of lung cancer (100 mL) is shown in Table 8.
TABLE-US-00008 TABLE 8 Culture Medium for Primary Cells from Solid Tumor Tissues of Lung Cancer (100 mL) Final Reagent Brand Article No. Dosage Concentration Dual-antibody P/S Gibco#15140122 1 mL 1% HEPES Gibco#15630080 1 mL 10 mM Non-essential amino acid Gibco#11140-050 1 mL 1% solution GlutaMax Gibco#35050061 1 mL 1% 1,000× human 1,000× stock 50-500 μL 10-100 ng/mL recombinant protein EGF solution 1,000× human 1,000× stock 50-250 μL 10-50 ng/mL recombinant protein bFGF solution 1,000× human 1,000× stock 25-125 μL 5-25 ng/mL recombinant protein MSP solution 1,000× cortisol 1,000× stock 80-200 μL 20-50 ng/mL solution B27 Gibco#12587010 2 mL 2% ITS-X Gibco#51500056 1 mL 1% 1,000× Y-27632 1,000× stock 50-200 μL 5-20 μM solution Advanced DMEM/F12 Gibco#12634010 Added to culture medium 100 mL
[0133] After being prepared, the culture medium for primary cells from solid tumor of lung cancer was filtered and sterilized with a 0.22 μM syringe-driven strainer (Millipore SLGP033RS). The culture medium can be stored at 4° C. for two weeks.
[0134] In Table 8, the preparation of human recombinant protein stock solution is shown in Table 9-Table 12, the preparation of cortisol stock solution is shown in Table 13, and the preparation of Y-27632 stock solution is shown in Table 14.
TABLE-US-00009 TABLE 9 100× BSA Solution (1 mL) Final Reagent Brand Article No. Dosage Concentration BSA Sigma# A1933 0.1 g 0.1 g/mL PBS Gibco#21-040-CVR Added to 1 mL
[0135] 100×BSA solution needs to be prepared just before use.
TABLE-US-00010 TABLE 10 1,000× Human Recombinant Protein EGF Stock Solution (5 mL) Final Reagent Brand Article No. Dosage Concentration Human recombinant Peprotech AF-100-15-100 100 μg 20 μg/mL protein EGF 100× BSA solution 500 μL 0.01 g/mL PBS Gibco#21-040-CVR Added to 5 mL
[0136] After being prepared, the 1,000× human recombinant protein EGF stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes. The stock solution can be stored at −80° C. for a long term.
TABLE-US-00011 TABLE 11 1,000× Human Recombinant Protein bFGF Stock Solution (2.5 mL) Final Reagent Brand Article No. Dosage Concentration Human Peprotech AF-100-18B-50 50 μg 20 μg/mL recombinant protein bFGF 100× BSA 250 μL 0.01 g/mL solution PBS Gibco#21-040-CVR Added to 2.5 mL
[0137] After being prepared, the 1,000× human recombinant protein bFGF stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes. The stock solution can be stored at −80° C. for a long term.
TABLE-US-00012 TABLE 12 1,000× Human Recombinant Protein MSP Stock Solution (2.5 mL) Final Reagent Brand Article No. Dosage Concentration Human recombinant R&D#352-MS-050 50 μg 20 μg/mL protein MSP 100× BSA solution 250 μL 0.01 g/mL PBS Gibco#21-040-CVR Added to 2.5 mL
[0138] After being prepared, the 1,000× human recombinant protein MSP stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes. The stock solution can be stored at −80° C. for a long term.
TABLE-US-00013 TABLE 13 1,000× Cortisol Stock Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration Cortisol Sigma#H0888 2.5 g 25 μg/mL Absolut eethyl Sigma#E7023 5 mL 5% alcohol Ultrapure water Added to 100 mL
[0139] After being prepared, the 1,000× cortisol stock solution was sub-packaged in 1.5 mL sterile centrifuge tubes. The stock solution can be stored at −80° C. for a long term.
TABLE-US-00014 TABLE 14 1,000× Y-27632 Stock Solution (3.125mL) Final Reagent Brand Article No. Dosage Concentration Y-27632 MCE#129830-38-2 10 g 10 mM Ultrapure Added to 3.125 mL water
[0140] After being prepared, the 1,000×Y-27632 stock solution was sub-packaged in 0.5 mL sterile centrifuge tubes. The stock solution can be stored at −80° C. for a long term.
[0141] 7. Cell cytopreserving solution
[0142] The specific formula of cell cytopreserving solution is shown in Table 15.
TABLE-US-00015 TABLE 15 Cell Cytopreserving Solution Reagent Brand Article No. Dosage Advanced DMEM/F12 Gibco#12634010 20 mL culture medium DMSO Sigma#D2438 2 mL 1% methylcellulose solution 1 mL
[0143] The cell cytopreserving solution needs to be prepared just before use.
[0144] In Table 15, the preparation of 1% methylcellulose solution is shown in
[0145] Table 16.
TABLE-US-00016 TABLE 16 1% Methylcellulose Solution (10 mL) Final Reagent Brand Article No. Dosage Concentration Methylcellulose Sigma#M7027 0.1 g 10 g/L Utrapure water Added to 10 mL
[0146] The prepared 1% methylcellulose solution can be stored at 4° C. for a long time.
Embodiment 2. Obtaining a Postoperative Specimen of a Solid Tumor Tissue of Lung Cancer
[0147] 1. The inventor cooperated with national grade-3, first-class hospitals (in China), and the cooperation passed the formal medical ethical review.
[0148] 2. The attending physician selected the enrolled patients according to the clinical indications specified in the medical guidelines, and selected suitable samples for in vitro culture according to the intraoperative clinical indications; the selection criteria of samples were as follows: samples of primary lung cancer with II or III pathological stage and pathological types of non-small-cell lung cancer or small cell lung cancer, weighing more than 20 mg.
[0149] 3. The attending physician provided a patient's basic clinical information, such as gender, age, medical history, family history, smoking history, pathological stages and types, clinical diagnosis, etc. The information related to patient privacy, such as patient's name and ID number, was concealed and replaced by a unified experimental number, and the naming principle of the experimental number was the 8-digit date of sample collection+last four digits of the patient's admission number. For example, for a sample provided on Jan. 1, 2018, if the patient's admission number was T001512765, the sample experiment number was 201801012765.
[0150] 4. During the operation, a surgeon collected a fresh specimen in a sterile environment of an operating room and placed it in a sample preservation solution prepared in advance (see Embodiment 1). The sample was temporarily stored on ice after ex vivo and transported to a laboratory within two hours for further operations.
Embodiment 3. Performing Predissociation Treatment for a Solid Tumor Tissue Sample of Lung Cancer
[0151] The following steps were operated on ice, and the whole operation process was completed within 10 minutes.
[0152] All the surgical apparatuses used in the following embodiments were used only after high temperature and high-pressure sterilization and oven drying in advance.
[0153] 1. The sample was weighed.
[0154] 2. The sample surface was washed with 75% (percentage by volume) ethanol for 10 to 30 seconds.
[0155] 3. The sample was washed with a sample washing solution for 5 times and washed with a sterile PBS solution for 5 times.
[0156] 4. Adipose tissues, connective tissues and necrotic tissues in the sample were carefully peeled off with ophthalmic scissors, ophthalmic forceps, scalpel and other apparatuses.
Embodiment 4. Dissociating the Solid Tumor Tissue Sample of Lung Cancer
[0157] All the surgical apparatuses used in the following embodiments can only be used after high temperature and high-pressure sterilization and oven drying in advance.
[0158] 1. The tissues were cut into small pieces of about 1 mm.sup.3 with ophthalmic scissors.
[0159] 2. The tissue sample cut into pieces was treated with a sample dissociation solution preheated to 37° C. in advance according to the dosage of 0.1 mL of sample dissociation solution (Table 3) per 1 mg of tissue, and the sample was dissociated at 37° C. for 15 minutes to 3 hours. The dissociation of the sample was observed under a microscope every 15 minutes until a large number of individual cells were observed.
[0160] 3. The dissociation reaction was terminated with a 10× volume of digestion termination solution (Table 7), and the cell suspension was collected.
[0161] 4. The cell suspension was filtered with a 100 μm sterile cell strainer to remove tissue debris and adherent cells.
[0162] 5. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0163] 6. The cells were resuspended with 5 mL of sterile PBS and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0164] 7. The cell precipitation was resuspended with the culture medium for primary cells from solid tumor tissues of lung cancer (Table 8), the cell state was observed under a microscope, and the cells were counted.
[0165] In addition to tumor cells, there were also a large number of various types of other cells, such as red blood cells, lymphocytes and fiber cells, which were mixed in the single cell suspension obtained by dissociation, as shown in
[0166] One of the advantages of the present method is that only the cancer cells could be amplified in the subsequent culture process, the proportion of other cells gradually decreases or even disappears, and primary tumor cells of lung cancer with a high purity are finally obtained.
Embodiment 5. Culturing Primary Cells from Solid Tumor of Lung Cancer
[0167] 1. A low-attachment-surface was used for suspension-culturing primary cells from solid tumor tissues of lung cancer, and the culture medium in use was the culture medium for primary cells from solid tumor tissues of lung cancer in example 1; taking a 6-well plate as an example, and cells were planked at a density of 10.sup.6 cells per well in a cell incubator under the condition of 37° C. and 5% CO.sub.2.
[0168] 2. The cell state was observed every day, and the culture medium was replaced every 3 days until the cell masses with a diameter of about 100 μm were formed.
[0169] As shown in
Embodiment 6. Passaging Primary Cells from Solid Tumor Tissues of Lung Cancer
[0170] 1. The cell masses in a culture dish were collected and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0171] 2. The cell masses were washed with sterile PBS solution and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0172] 3. The cell masses were resuspended with a cell digestion solution (Table 6) and dissociated at 37° C. The dissociation of the cell masses was observed under the microscope every 5 minutes until all the cell masses were dissociated into individual cells.
[0173] 4. The dissociation reaction was terminated with a 10× volume of digestion termination solution (Table 7), and the cell suspension was collected.
[0174] 5. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0175] 6. The cell precipitation was resuspended with the culture medium for primary cells from solid tumor tissues of lung cancer (Table 8), and the cells were counted.
[0176] 7. A low-attachment-surface was used for culturing primary cells from solid tumor of lung cancer, and the culture medium in use was the culture medium for primary cells from solid tumor of lung cancer in example 1; a 6-well plate was taken as an example, and cells were planked at a density of 10.sup.6 cells per well in a cell incubator under the condition of 37° C. and 5% CO.sub.2.
Embodiment 7. Cytopreserving Primary Cells from Solid Tumor of Lung Cancer
[0177] The suspension-cultured primary cells from solid tumor of lung cancer by could be cytopreserved after 2-3 passages and amplifications:
[0178] 1. The cell masses in a culture dish were collected and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0179] 2. The cell masses were washed with sterile PBS solution and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0180] 3. The cell masses were resuspended with a cell digestion solution (Table 6) and digested at 37° C. The digestion of the cell masses was observed under the microscope every 15 minutes until all the cell masses were digested into individual cells.
[0181] 4. The digestion reaction was terminated with a 10× volume of digestion termination solution (Table 7), the cell suspension was collected, and the cells were counted.
[0182] 5. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0183] 6. The cell precipitation was resuspended at a density of 10.sup.6/mL with cell cytopreserving solution (Table 15), each 2 mL cytopreserving tube contained 1 mL of cell suspension, and the cell suspension was cytopreserved overnight in a gradient cooling box and transferred into liquid nitrogen for a long-term preservation.
Embodiment 8. Resuscitating Primary Cells from Solid Tumor of Lung Cancer
[0184] Primary cells from solid tumor of lung cancer preserved in liquid nitrogen were resuscitated:
[0185] 1. 37° C. sterile water was prepared five minutes in advance.
[0186] 2. The cytopreserving tubes were removed from liquid nitrogen, and the cells were quickly melted in 37° C. sterile water.
[0187] 3. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0188] 4. The cell precipitation was resuspended with the culture medium for primary cells from solid tumor tissues of lung cancer (Table 8), the primary cells from solid tumor of lung cancer were cultured using a low-attachment-surface, the cells in each tube were resuscitated into a 3.5 cm culture dish, and the cells were cultured in a cell culturing incubator under the condition of 37° C. and 5% CO.sub.2.
Embodiment 9. HE Staining Identification of Primary Cells from Solid Tumor of Lung Cancer
[0189] Description of reagent consumables to be used in the following embodiment:
[0190] HE Staining Kit (Beijing Solarbio Science & Technology Co., Ltd., #G1120);
[0191] Cationic anticreep slide (ZSGB-BIO);
[0192] Xylene, methanol, acetone (Chemical Reagent Beijing Co., Ltd., analytical pure);
[0193] Neutral resin adhesive (Beijing Yili Fine Chemicals Co., Ltd.).
[0194] 1. Suspended primary cells from solid tumor of lung cancer obtained by culturing with the culture medium for primary cells from solid tumor tissues of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 50 ng/mL; the final concentration of human recombinant protein bFGF was 20 ng/mL; the final concentration of human recombinant protein MSG was 20 ng/mL; the final concentration of cortisol was 20 ng/mL; and the final concentration of Y-27632 was 10 μM) were prepared into a cell suspension with a concentration of 10.sup.4/mL, and 10 μL of the cell suspension was added dropwise on a cationic anti-creep slide to be dried in the air.
[0195] 2. 50 μL of a methanol/acetone mixture (volume ratio 1:1) pre-cooled at 4° C. was carefully added dropwise on the air-dried cells, and then the slide was placed in a refrigerator at 4° C. for fixing for 10 minutes.
[0196] 3. The slide for fixing the cells was taken out and naturally dried at room temperature.
[0197] 4. The slide was washed twice with 200 μL of PBS.
[0198] 5. 100 μL of hematoxylin staining solution was added for staining for 1 minute when the moisture on the slide was slightly dried.
[0199] 6. The hematoxylin staining solution was sucked up, and the slide was washed for 3 times with 200 μL of tap water.
[0200] 7. 100 μL of differentiation solution was added dropwise for differentiation for 1 minute.
[0201] 8. The differentiation solution was sucked up, and the slide was washed twice with tap water and washed with distilled water once.
[0202] 9. The moisture on the slide surface was sucked up, and 200 μL of eosin stain was added dropwise for staining for 40 s.
[0203] 10. The eosin stain was sucked up, and rinsing and dehydration were performed successively with 75%, 80%, 90% and 100% ethanol for 20 s, 20 s, 40 s and 40 s.
[0204] 11. After the ethanol was dried in the air, 50 μL of dimethylbenzene was added dropwise for cell permeability.
[0205] 12. After dimethylbenzene was completely dried, a drop of neutral resin adhesive was added, and the slide was sealed with a cover glass, observed under the microscope and photographed.
[0206]
Embodiment 10. Immunofluorescence Staining Identification of Primary Cells from Solid Tumor of Lung Cancer
[0207] Description of reagents to be used in the following embodiments:
[0208] Paraformaldehyde (Chemical Reagent Beijing Co., Ltd., analytical pure), paraformaldehyde powder was dissolved with ultrapure water to form 4% (4 g/100 mL) paraformaldehyde solution;
[0209] Methanol and dimethyl sulfoxide (Chemical Reagent Beijing Co., Ltd., analytical pure); Hydrogen peroxide (Chemical Reagent Beijing Co., Ltd., 35%);
[0210] Methanol, dimethyl sulfoxide and 35% hydrogen peroxide were mixed in the ratio of 4:4:1 (volume ratio) to form Dan's rinsing solution;
[0211] Bovine serum albumin (Sigma, #A1933), bovine serum albumin was dissolved with PBS solution to form 3% (3 g/100 mL) BSA solution; Immunofluorescence primary antibody (Abcam, #ab17139);
[0212] Immunofluorescence secondary antibody (CST, #4408); Hoechst staining solution (Beijing Solarbio Science & Technology Co., Ltd., #C0021);
[0213] The masses of primary cells from solid tumor of lung cancer obtained by culturing with the culture medium for primary cells from solid tumor of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 50 ng/mL; the final concentration of human recombinant protein bFGF was 20 ng/mL; the final concentration of human recombinant protein MSP was 20 ng/mL; the final concentration of cortisol was 20 ng/mL; and the final concentration of Y-27632 was 10 μM) were subject to immunofluorescence staining according to the following steps, the primary antibody was CK8+CK18, and epithelial-derived cells were characterized.
[0214] 1. The masses of primary cells from solid tumor tissues of lung cancer in the culture dish were collected and washed once with PBS, and then the cell precipitation was resuspended with 4% paraformaldehyde and fixed at 4° C. overnight.
[0215] 2. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was resuspended with a precooled methanol solution and placed on ice for 1 hour.
[0216] 3. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was resuspended with Dan's rinsing solution and placed at room temperature for 2 hours.
[0217] 4. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cells were washed with 75%, 50% and 25% (percentage by volume) methanol solution diluted with PBS, 10 minutes each time.
[0218] 5. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was suspended with a 3% BSA solution and sealed at room temperature for 2 hours.
[0219] 6. The primary antibody was diluted with a 3% BSA solution at a ratio of 1:500, the cell precipitation was resuspended with the antibody diluent (3% BSA solution), and the primary antibody was placed at 4° C. overnight.
[0220] 7. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was washed for 5 times with PBS solution, with 20 minutes each time.
[0221] 8. The secondary antibody was diluted with a 3% BSA solution at a ratio of 1:2,000, the cell precipitation was resuspended with the antibody diluent (3% BSA solution), and the secondary antibody was placed at room temperature for 2 hours.
[0222] 9. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was washed for 5 times with PBS solution for 20 minutes each time.
[0223] 10. 100× Hoechst staining solution was added at a volume ratio of 1/100 for staining at room temperature for 20 minutes.
[0224] 11. The cell precipitation was washed twice with PBS solution, for 10 minutes each time. The staining of the cell masses was observed using a laser confocal microscope.
[0225]
TABLE-US-00017 TABLE 17 Immunofluorescence Staining Identification of Primary Cultures of Lung Cancer Samples Positive Rate of S/N Sample No. CK8/CK18 1 20160914ZDH0085 87.2% 2 20160921SMY3832 89.1% 3 20160921LXH3743 93.0% 4 20160922XGX3936 82.5% 5 20160928CLP9564 77.9% 6 20161026XTT6317 91.4% 7 20161108JSM7314 88.8% 8 20161110ZZL3204 79.6% 9 20161110WJj7710 82.5% 10 20161114NSP7802 93.8% 11 20161114YSX7805 89.5% 12 20161115MZL4461 86.8% 13 20161123GPF8479 92.7% 14 20161201WPF9236 77.4% 15 20161201WBY9242 84.0% 16 20161206WYQ9298 93.5% 17 20161223ZGL3074 91.2% 18 20161226CSH1078 89.3% 19 20170111YXM6263 81.2% 20 20170216LJR1120 84.3%
Embodiment 11. Primary Cell Cultures and Primary Tumor Tissues from Solid Tumor Tissues of Lung Cancer
[0226] The DNA extraction mentioned in the following embodiment was performed with TIANGEN blood/tissue/cell genome Extraction Kit (DP304).
[0227] The library building mentioned in the following embodiment was performed with NEB DNA Sequencing and Library Building Kit (E7645).
[0228] The high-throughput sequencing mentioned in the following embodiment refers to the Illumina HiSeq X-ten sequencing platform.
[0229] 1. A solid tumor sample of lung cancer was obtained, 10 mg of solid tumor sample of lung cancer was firstly taken for DNA extraction, library building and whole-genome high-throughput sequencing (WGS), and with a sequencing depth of 30× before in vitro culture operations were performed, the remaining solid tumor samples were used for culturing in vitro primary cells from solid tumor of lung cancer (the specific method refers to that in the previously described embodiment).
[0230] 2. Lung cancer tissues were treated and cultured with the culture medium for primary cells from solid tumor of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 50 ng/mL; the final concentration of human recombinant protein bFGF was 20 ng/mL; the final concentration of human recombinant protein MSP was 20 ng/mL; the final concentration of cortisol was 20 ng/mL; and the final concentration of Y-27632 was 10 μM) for a period of time to form cell masses with a diameter of more than 100 μm, which were recorded as P0-generation cells, followed by P1, P2, Pn successively according to the number of passages. 10.sup.6 cells were taken respectively from P1, P2, P3 and P4-generation primary cell cultures from solid tumor of lung cancer for DNA extraction, library building and whole-genome high-throughput sequencing (WGS), with a sequencing depth of 30×.
[0231] 3. Copy number variation analysis (CNV) was performed based on the sequencing results of each group, and the copy number variations between primary tumor tissues of lung cancer and all generations of primary cell cultures from solid tumor of lung cancer were compared. As shown in
Embodiment 12. Comparing the Success Rates of Different Primary Cell Culture Media for Culturing Primary Cells from Solid Tumor of Lung Cancer
[0232] The operation methods and processes for culturing primary cells from all samples in this embodiment were identical (as mentioned above), and the only difference lied in the culture medium formula. Various tested primary cell culture media were shown in Table 18. Wherein Scheme D is the formula used in the present invention, with details in Table 8 (wherein the final concentration of human recombinant protein EGF was 40 ng/mL; the final concentration of human recombinant protein bFGF was 20 ng/mL; the final concentration of human recombinant protein MSP was 20 ng/mL; the final concentration of cortisol was 20 ng/mL; and the final concentration of Y-27632 was 5 μM)
TABLE-US-00018 TABLE 18 Primary Cell Culture Medium Formula For Test (100 mL) Final Culture Medium Reagent Brand Article No. Dosage Concentration Scheme A mTeSR ™1 medium Stemcell#05850 100 mL Scheme B Alveolar Epithelial ScienCell#3201 100 mL Cell Medium Scheme C Dual-antibody P/S Gibco#15140122 1 mL 1% HEPES Gibco#15630080 1 mL 10 mM 1,000 × human 1,000 × stock 250 μL 50 ng/mL recombinant protein solution EGF 1,000 × human 1,000 × stock 100 μL 20 ng/mL recombinant protein solution bFGF DMEM/F12 culture Gibco# 14170161 Added to medium 100 mL Scheme D See Table 8
[0233] After being prepared, the primary cell culture media were filtered and sterilized with a 0.22 μM syringe-driven strainer (Millipore SLGP033RS). The primary cell culture media can be stored at 4° C. for two weeks.
[0234] 20 solid tumor tissue samples of lung cancer were treated according to each of the four primary cell culture medium schemes, the sample treatment and culture operations were performed according to the methods described in embodiments 3, 4 and 5, and the success rates of those primary cell culture media for culturing primary cells from solid tumor tissues of lung cancer were counted after 10 days of culturing, as shown in Table 19:
TABLE-US-00019 TABLE 19 Culturing in Different Media Sample Preservation Solution Scheme Success rate Scheme A 0% (0/20) Scheme B 25% (5/20) Scheme C 25% (5/20) Scheme D 75% (15/20)
[0235] It can be seen that primary cell culture media have an extremely great impact on the success rate of culturing primary cells from solid tumor cells of lung cancer, and the culture medium for primary cells from solid tumor tissues of lung cancer used in the present invention (Table 8) can, to the greatest extent, stimulate the proliferation of cancer cells in the solid tumor tissue sample of lung cancer and improve the success rate of culturing primary cells from solid tumor of lung cancer.
Embodiment 13. Comparing Success Rates of Different Sample Preservation Solutions for Culturing Primary Cells from Solid Tumor of Lung Cancer
[0236] The operation methods and processes for culturing primary cells from all samples in this embodiment were identical (as mentioned above), and the only difference lied in the sample preservation solution formula. Various tested sample preservation solutions are shown in Table 20. Wherein Scheme E is the formula used in the present invention, and the details are shown in Table 1.
TABLE-US-00020 TABLE 20 Formula of Sample Preservation Solution for Test (100 mL) Sample Preservation Final Solution Concen- Scheme Reagent Brand Article No. Dosage tration Scheme A HBSS Gibco# 14170161 100 mL Scheme B Dual-antibody Gibco#15140122 1 mL 1% P/S HBSS Gibco# 14170161 Added to 100 mL Scheme C Dual-antibody Gibco#15140122 1 mL 1% P/S DMEM culture Gibco#11965-092 Added to medium 100 mL Scheme D Dual-antibody Gibco#15140122 1 mL 1% P/S Fetal bovine Gibco#16000-044 10 mL 10% serum DMEM culture Gibco#11965-092 Added to medium 100 mL Scheme E See Table 1
[0237] After being prepared, those sample preservation solutions in the above table were sub-packaged in 15 mL centrifuge tubes, and each tube was filled with 5 mL of sample preservation solutions. The sample preservation solution sub-packaged can be stored at 4° C. for 1 month.
[0238] 20 solid tumor tissue samples of lung cancer were treated according to each of the five sample preservation solution schemes, and the samples were detached and temporarily preserved at 4° C. in the sample preservation solution; the sample treatment and culture operations were performed according to the methods described in embodiments 3, 4 and 5 two hours after detachment, and the success rates of those sample preservation solutions for culturing primary cells from solid tumor of lung were counted after 10 days of culturing, as shown in Table 21:
TABLE-US-00021 TABLE 21 Culturing in Different Sample Preservation Solutions Sample Preservation Bacteria/Fungus Solution Scheme Success rate contamination rate Scheme A 40% (8/20) 15% (3/20) Scheme B 55% (11/20) 0% (0/20) Scheme C 55% (11/20) 0% (0/20) Scheme D 70% (14/20) 0% (0/20) Scheme E 75% (15/20) 0% (0/20)
[0239] It can be seen that different sample preservation solutions have a great impact on the culture success rate of culturing primary cells from solid tumor of lung cancer, and the sample preservation solution used in the present invention (Table 1) can, to the greatest extent, protect the activity of cancer cells in the solid tumor tissue sample of lung cancer and improve the success rate.
Embodiment 14. Comparing Success Rates of Different Sample Dissociation Solutions for Culturing Primary Cells from Solid Tumor Tissues of Lung Cancer
[0240] The operation methods and processes of primary culturing of all samples in this embodiment were identical (as mentioned above), and the only difference lied in the sample dissociation solution formula. Various tested sample dissociation solutions are shown in Table 22. Wherein Scheme D is the formula used in the present invention, and the details are shown in Table 3.
TABLE-US-00022 TABLE 22 Sample Dissociation Solution Formula for Test (10 mL) Sample Final Dissociation Concen- Solution Reagent Brand Article No. Dosage tration Scheme A Trypsin Gibco# 252,00056 10 mL Scheme B 0.5 M EDTA Invitrogen#AM9261 10 μL 5 mM DNAse Thermo# EN0521 62.5 μL 62.5 U/mL TrypLE ™ Gibco#12604013 Added to Express 10 mL Scheme C 10 × 10 × stock solution 1 mL 200 U/mL collagenase IV DNAse Thermo# EN0521 62.5 μL 62.5 U/mL PBS Gibco#21-040-CVR Added to 10 mL Scheme D See Table 3
[0241] The sample dissociation solution needs to be prepared just before use.
[0242] 20 samples of solid tumor tissue masses of lung cancer weighing more than 100 mg were selected and sub-packaged into four parts equally, and sample treatment and culture operations were performed with the above four sample dissociation solutions respectively according to the methods described in embodiments 3, 4 and 5. The success rates of sample dissociation solutions for culturing primary cells from solid tumor tissues of lung cancer were counted after 10 days of culturing, as shown in Table 23 below:
TABLE-US-00023 TABLE 23 Culturing in Different Sample Dissociation Solutions Scheme Scheme Scheme Scheme S/N Sample No. A B C D 1 20160822ZGQ2244 Failed Failed Failed Passed 2 20160823CZH7746 Failed Failed Failed Failed 3 20160823CXL5741 Failed Failed Passed Passed 4 20160826LBL2723 Failed Passed Failed Passed 5 20160901YZM2848 Failed Failed Passed Passed 6 20160901FYR8262 Failed Failed Failed Failed 7 20160902YXL8520 Failed Failed Failed Failed 8 20160902ZGB3405 Failed Passed Passed Passed 9 20160906YXY9476 Failed Passed Passed Passed 10 20160919HQH3874 Failed Failed Passed Passed 11 20161009FJX0000 Failed Failed Failed Failed 12 20161009LFZ0000 Failed Failed Failed Passed 13 20161010ZLH5257 Failed Passed Passed Passed 14 20161011GLZ8283 Failed Failed Failed Failed 15 20161026YYH6569 Failed Failed Failed Failed 16 20161026ESP0641 Failed Failed Failed Passed 17 20161027MGL7286 Failed Passed Passed Passed 18 20161107WHP9893 Failed Failed Passed Passed 19 20161111YZM2848 Failed Failed Failed Passed 20 20170209WYT2997 Failed Failed Passed Passed Summary 0% 25% 45% 70% (0/20) (5/20) (9/20) (14/20)
[0243] It can be seen that different sample dissociation solutions have a very great impact on the success rate of culturing primary cells from solid tumor tissues of lung cancer, and the sample dissociation solution used in the present invention (Table 3) can, to the greatest extent, isolate the cancer cells from solid tumor tissues of lung cancer and improve the success rate of culturing primary cells from solid tumor tissues of lung cancer.
Embodiment 15. Comparing Success Rates of Different Cell Digestion Solutions for Passaging Primary Cells from Solid Tumor Tissues of Lung Cancer
[0244] The operation methods and processes for passaging primary cells of all samples in this embodiment were identical (as mentioned above), and the only difference lied in the cell digestion solution formula. Various tested cell digestion solution are shown in Table 24. Wherein Scheme D is the formula used in the present invention, and the details are shown in Table 6.
TABLE-US-00024 TABLE 24 Cell Digestion Solution Formula for Test (10 mL) Cell Final Digestion Concen- Solution Reagent Brand Article No. Dosage tration Scheme A Trypsin Gibco# 252,00056 10 mL Scheme B 0.5 M EDTA Invitrogen#AM9261 10 μL 5 mM TrypLE ™ Gibco#12604013 Added to Express 10 mL Scheme C 10 × 10 × stock solution 1 mL 200 U/mL collagenase I 10 × 10 × stock solution 1 mL 200 U/mL collagenase IV PBS Gibco#21-040-CVR Added to 10 mL Scheme D See Table 6
[0245] The cell digestion solution needs to be prepared just before use.
[0246] 20 successfully cultured solid tumor tissue samples of lung cancer were selected, and the primary cells from solid tumor of lung cancer obtained by culture were continuously passaged with the above four cell digestion solutions respectively according to the method described in Embodiment 6. Passaging (for no more than 10 times) was performed every time cancer cells amplified and formed cell masses with a diameter of 100 μm, and the maximum passaging number was recorded. The statistical results are as shown in Table 25:
TABLE-US-00025 TABLE 25 Culturing in Different Cell Digestion Solutions Scheme Scheme Scheme Scheme S/N Sample No. A B C D 1 20160822ZGQ2244 1 3 5 9 2 20160823CXL5741 1 5 5 10 3 20160901YZM2848 1 3 4 10 4 20160902ZGB3405 1 3 5 9 5 20160906YXY9476 1 4 4 10 6 20160919HQH3874 2 6 7 10 7 20161009LFZ0000 1 2 3 8 8 20161010ZLH5257 1 3 4 8 9 20161026ESP0641 1 3 4 8 10 20161027MGL7286 1 5 6 10 11 20161107WHP9893 1 2 4 9 12 20161110ZZL3204 2 4 6 10 13 20161110WJj7710 1 5 5 10 14 20161111YZM2848 1 4 5 10 15 20170111YXM6263 1 4 6 10 16 20161114NSP7802 1 2 3 8 17 20161114YSX7805 1 5 5 9 18 20170209WYT2997 1 4 5 8 19 20170216LJR1120 1 3 3 8 20 20170417LFX7932 1 3 4 9 Summary of passaging 1-2 2-6 3-7 More than number times times times 8 times
[0247] It can be seen that different cell digestion solutions have a very great impact on the success rate of passaging primary cells from solid tumor of lung cancer, and the cell digestion solution used in the present invention (Table 6) can mildly dissociate the cancer cells in the cell masses to continuously passage the samples and maintain the activity of primary cells from solid tumor of lung cancer.
Embodiment 16. Culturing Primary Tumor Cells of Lung Cancer from Puncture Microsamples
[0248] The operation methods and processes of primary culturing of all samples in this embodiment were identical with the methods for culturing primary cells from solid tumor of lung cancer (as mentioned above), and the only difference lied in the sample source which was unified as two puncture samples (Table 26).
TABLE-US-00026 TABLE 26 Culturing of Primary Cells from Puncture Samples of Lung Cancer S/N Sample No. Culture 1 20190107YJD0928 Passed 2 20190113KFH8364 Failed 3 20190114PSY7482 Passed 4 20190114NCC4701 Passed 5 20190117LCN3957 Passed 6 20190125GCY3572 Passed 7 20190201HZY0486 Passed 8 20190201GDN4967 Failed 9 20190205DHB0029 Passed 10 20190207DJB9586 Failed Success Rate 7/10
[0249] It can be seen from Table 26 that the microsamples obtained by puncture can still culture primary cells of lung cancer at a higher success rate.
Embodiment 17. Preparing a Reagent for Culturing Primary Cells from Pleural Effusion of Lung Cancer
[0250] 1. Cell Isolation Buffer (100 mL)
[0251] The specific formula of cell isolation buffer (100 mL) is shown in Table 27:
TABLE-US-00027 TABLE 27 Cell Isolation Buffer (100 mL) Final Reagent Brand Article No. Dosage Concentration Dual-antibody P/S Gibco#15140122 1 mL 1% 1,000 × heparin 1,000 × stock 0.1 mL 10 IU/mL sodium solution solution PBS Gibco#21-040-CVR Added to 100 mL
[0252] The prepared cell isolation buffer can be stored at 4° C. for 1 month.
[0253] In Table 27, the preparation of the heparin sodium solution is shown in Table 28.
TABLE-US-00028 TABLE 28 1,000 × Heparin Sodium (1 mL) Final Reagent Brand Article No. Dosage Concentration Heparin sodium Solarbio#H8270 10 kIU 10 kIU/mL Ultrapure water Added to 1 mL
[0254] 1,000× heparin sodium solution needs to be prepared just before use.
[0255] 2. Cell Digestion Solution (10 mL)
[0256] The specific formula of cell digestion solution (10 mL) is shown in Table 6 (the same as the formula of the cell digestion solution used for culturing primary cells from solid tumor of lung cancer).
[0257] 3. Digestion Termination solution (100 mL)
[0258] The specific formula of digestion termination solution (100 mL) is shown in Table 7 (the same as the formula of the digestion termination solution used for culturing primary cells from solid tumor of lung cancer).
[0259] 4. Culture medium for primary tumor cells from pleural effusion of lung cancer (100 mL)
[0260] The specific formula of culture medium for primary cell from pleural effusion of lung cancer (100 mL) is shown in Table 8 (the same as the formula of the culture medium for primary tumor cells from solid tumor of lung cancer used for culturing primary cells from solid tumor tissues of lung cancer).
[0261] 5. Cell cytopreserving solution
[0262] The specific formula of cell cytopreserving solution (10 mL) is shown in Table 15 (the same as the formula of the cell cytopreserving solution used for culturing primary cells from solid tumor of lung cancer).
Embodiment 18. Obtaining Pleural Effusion Samples of Lung Cancer
[0263] 1. The inventor cooperated with national grade-3, first-class hospitals (in China), and the cooperation passed the formal medical ethical review.
[0264] 2. The attending physician selected the enrolled patients according to the clinical indications specified in the medical guidelines, and selected suitable samples for in vitro culture according to the intraoperative clinical indications; the selection criteria of samples were as follows: primary lung cancer with IV pathological stage and pathological types of non-small-cell lung cancer or small cell lung cancer, and patients accompanied by malignant pleural effusion to be drained, with a drainage amount of not less than 50 mL.
[0265] 3. The attending physician provided a patient's basic clinical information, such as gender, age, medical history, family history, smoking history, pathological stages and types, clinical diagnosis, etc. The information related to patient privacy, such as patient's name and ID number, was concealed and replaced by a unified experimental number, and the experimental number was equal to the 8-digit date of sample collection+last four digits of the patient's admission number. For example, for a sample provided on Jan. 1, 2018, if the patient's admission number was T001512765, the sample experiment number was 201801012765.
[0266] 4. Pleural effusion samples were collected by the attending physician using sterile apparatuses and containers. After being detached, the sample was temporarily preserved on ice and transported to a laboratory for the next operation within 72 hours.
Embodiment 19. Pretreating Pleural Effusion Samples of Lung Cancer
[0267] The following embodiment was operated on ice:
[0268] 1. The pleural effusion sample of lung cancer was kept still on ice for about 30 minutes, so that blood clots and large insoluble solids in the sample were settled to the bottom of the sample tube.
[0269] 2. The supernatant was carefully transferred into a 50 mL sterile centrifuge tube.
[0270] 3. The cell suspension was centrifugated at 2,000 g at room temperature for 5 minutes, and the supernatant was discarded.
[0271] 4. The cell precipitation was resuspended with a cell isolation buffer (Table 27) and centrifuged at 2,000 g for 5 minutes, and the supernatant was discarded.
[0272] 5. The cell precipitation was resuspended with a cell isolation buffer (Table 27), and the cell concentration was adjusted to 10.sup.7-10.sup.8 cells/mL.
Embodiment 20. Density Gradient Centrifugation of Pleural Effusion Samples of Lung Cancer
[0273] 1. Ficoll cell separation solution (MP #50494) of the same volume as the cell suspension was taken by a 50 mL sterile centrifuge tube.
[0274] 2. The cell suspension was carefully added to the upper layer of the cell separation solution, so that a clear interface was formed between them.
[0275] 3. The cell suspension was horizontally centrifuged at 2,000 g at room temperature for 20 minutes.
[0276] 4. A white membrane in an intermediate layer was sucked into a new tube.
[0277] 5. The cell precipitation was resuspended with 20 mL sterile PBS and centrifuged at 1,500 g at room temperature for 10 minutes, and the supernatant was discarded.
[0278] 6. The cell precipitation was resuspended with the culture medium for primary cell from pleural effusion of lung cancer (Table 8), the cell state was observed under a microscope, and the cells were counted.
[0279] In addition to tumor cells, there were also a large number of various types of other cells, such as red blood cells, lymphocytes and fiber cells, mixed in the single cell suspension isolated from the pleural effusion samples of lung cancer, as shown in
Embodiment 21. Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0280] 1. A low-attachment-surface was used for suspension-culturing primary tumor cells from pleural effusion of lung cancer; a 6-well plate was taken as an example, and cells were planked at a density of 10.sup.6 cells per well in a cell incubator under the condition of 37° C. and 5% CO.sub.2.
[0281] 2. The cell state was observed every day, and the culture medium was replaced every 3 days until the cells formed masses with a diameter of about 100 μm.
[0282] As shown in
Embodiment 22. Passaging Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0283] 1. The cell masses in a culture dish were collected and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0284] 2. The cell masses were washed with sterile PBS solution and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0285] 3. The cell masses were resuspended with a cell digestion solution (Table 6) and digested at 37° C. The digestion of the cell masses was observed under the microscope every 5 minutes until all the cell masses were digested into individual cells.
[0286] 4. The dissociation reaction was terminated with a 10× volume of digestion termination solution (Table 7), and the cell suspension was collected.
[0287] 5. The cell suspension was centrifugated at 800 g a room temperature for 10 minutes, and the supernatant was discarded.
[0288] 6. The cell precipitation was resuspended with the culture medium for primary cells for pleural effusion of lung cancer (Table 8), and the cells were counted.
[0289] 7. A low-attachment-surface was used for suspension-culturing primary cells of lung cancer; a 6-well plate was taken as an example, and cells were planked at a density of 10.sup.6 cells per well in a cell incubator under the condition of 37° C. and 5% CO.sub.2.
Embodiment 23. Cytopreserving Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0290] The suspension-cultured primary tumor cells from pleural effusion of lung cancer could be cytopreserved after 2-3 passages and amplifications:
[0291] 1. The cell masses in a culture dish were collected and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0292] 2. The cell masses were washed with sterile PBS solution and centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0293] 3. The cell masses were resuspended with a cell digestion solution (Table 6) and digested at 37° C. The digestion of the cell masses was observed under the microscope every 5 minutes until all the cell masses were digested into individual cells.
[0294] 4. The dissociation reaction was terminated with a 10× volume of digestion termination solution (Table 7), the cell suspension was collected, and the cells were counted.
[0295] 5. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0296] 6. The cell precipitation was resuspended at a density of 10.sup.6/mL with cell cytopreserving solution (Table 15), each 2 mL cytopreserving tube contained each 1 mL of cell suspension, and the cell suspension was cytopreserved overnight in a gradient cooling box and transferred into liquid nitrogen for a long-term preservation.
Embodiment 24. Resuscitating Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0297] Primary tumor cells from pleural effusion of lung cancer preserved in liquid nitrogen could be resuscitated:
[0298] 1. 37° C. sterile water was prepared five minutes in advance.
[0299] 2. The cytopreserving tubes were removed from liquid nitrogen, and the cells were quickly melted in 37° C. sterile water.
[0300] 3. The cell suspension was centrifugated at 800 g at room temperature for 10 minutes, and the supernatant was discarded.
[0301] 4. The cell precipitation was resuspended with the culture medium for primary tumor cells from pleural effusion of lung cancer (Table 8), the primary tumor cells from pleural effusion of lung cancer were cultured using a low-attachment-surface, the cells in each tube were resuscitated into a 3.5 cm culture dish, and the cells were cultured in a cell Culturing incubator under the condition of 37° C. and 5% CO.sub.2.
Embodiment 25. HE Staining Identification of Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0302] Description of reagent consumables to be used in the following embodiment:
[0303] HE Staining Kit (Beijing Solarbio Science & Technology Co., Ltd., #G1120);
[0304] Cationic anticreep slide (ZSGB-BIO);
[0305] Xylene, methanol, acetone (Chemical Reagent Beijing Co., Ltd., analytical pure);
[0306] Neutral resin adhesive (Beijing Yili Fine Chemicals Co., Ltd.).
[0307] 1. Suspended primary tumor cells from pleural effusion of lung cancer obtained by culturing with the culture medium for primary cells from pleural effusion of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 60 ng/mL; the final concentration of human recombinant protein bFGF was 30 ng/mL; the final concentration of human recombinant protein MSG was 25 ng/mL; the final concentration of cortisol was 40 ng/mL; and the final concentration of Y-27632 was 15 μM) were prepared into a cell suspension with a concentration of 10.sup.4/mL, and 10 μL of the cell suspension was added dropwise on a cationic anti-creep slide to be dried in the air.
[0308] 2. 50 μL of a methanol/acetone mixture (volume ratio 1:1) pre-cooled at 4° C. was carefully added dropwise on the air-dried cells, and then the slide was placed in a refrigerator at 4° C. for fixing for 10 minutes.
[0309] 3. The slide for fixing the cells was taken out and naturally dried at room temperature.
[0310] 4. The slide was washed twice with 200 μL of PBS.
[0311] 5. 100 μL of hematoxylin staining solution was added for staining for 1 minute when the moisture on the slide was slightly dried.
[0312] 6. The hematoxylin staining solution was sucked up, and the slide was washed for 3 times with 200 μL of tap water.
[0313] 7. 100 μL of differentiation solution was added dropwise for differentiation for 1 minute.
[0314] 8. The differentiation solution was sucked up, and the slide was washed twice with tap water and washed with distilled water once.
[0315] 9. The moisture on the slide surface was sucked up, and 200 μL of eosin stain was added dropwise for staining for 40 s.
[0316] 10. The eosin stain was sucked up, and rinsing and dehydration were performed successively with 75%, 80%, 90% and 100% ethanol for 20 s, 20 s, 40 s and 40 s.
[0317] 11. After the ethanol was dried in the air, 50 μL of dimethylbenzene was added dropwise for cell permeability.
[0318] 12. After dimethylbenzene was completely dried, a drop of neutral resin adhesive was added, and the slide was sealed with a cover glass, observed under the microscope and photographed.
[0319]
Embodiment 26. Immunohistochemical Staining Identification of Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0320] Description of reagents to be used in the following embodiment:
[0321] Paraformaldehyde (Chemical Reagent Beijing Co., Ltd., analytical pure), paraformaldehyde powder was dissolved with ultrapure water to form 4% paraformaldehyde solution;
[0322] Methanol and dimethyl sulfoxide (Chemical Reagent Beijing Co., Ltd., analytical pure);
[0323] Hydrogen peroxide (Chemical Reagent Beijing Co., Ltd., 35%);
[0324] Methanol, dimethyl sulfoxide and 35% hydrogen peroxide were mixed in the ratio of 4:4:1 to form Dan's rinsing solution;
[0325] Bovine serum albumin (Sigma, #A1933), bovine serum albumin was dissolved with PBS solution to form 3% BSA solution;
[0326] Immunofluorescence primary antibody (Abcam, #ab17139);
[0327] Immunofluorescence secondary antibody (CST, #4408);
[0328] Hoechst staining solution (Beijing Solarbio Science & Technology Co., Ltd., #C0021);
[0329] The masses of primary tumor cells from pleural effusion of lung cancer obtained by culturing with the culture medium for primary tumor cells from pleural effusion of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 60 ng/mL; the final concentration of human recombinant protein bFGF was 30 ng/mL; the final concentration of human recombinant protein MSP was 25 ng/mL; the final concentration of cortisol was 40 ng/mL; and the final concentration of Y-27632 was 15 μM) were subject to immunofluorescence staining according to the following steps, the primary antibody was CK8+CK18, and epithelial-derived cells were characterized.
[0330] 1. The masses of primary tumor cells from pleural effusion of lung cancer in the culture dish were collected and washed once with PBS, and then the cell precipitation was resuspended with 4% paraformaldehyde and fixed at 4° C. overnight.
[0331] 2. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was resuspended with a precooled methanol solution and placed on ice for 1 hour.
[0332] 3. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was resuspended with Dan's rinsing solution and placed at room temperature for 2 hours.
[0333] 4. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cells were washed with 75%, 50% and 25% methanol solution diluted with PBS, 10 minutes each time.
[0334] 5. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was suspended with a 3% solution and sealed at room temperature for 2 hours.
[0335] 6. The primary antibody was diluted with a 3% BSA solution at a ratio of 1:500, the cell precipitation was resuspended with the antibody diluent, and the primary antibody was placed at 4° C. overnight.
[0336] 7. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was washed for 5 times with PBS solution, with 20 minutes each time.
[0337] 8. The secondary antibody was diluted with a 3% BSA solution at a ratio of 1:2,000, the cell precipitation was resuspended with the antibody diluent, and the secondary antibody was placed at room temperature for 2 hours.
[0338] 9. The cell solution was centrifugated at 800 g, the supernatant was discarded, and the cell precipitation was washed for 5 times with PBS solution, with 20 minutes each time.
[0339] 10. 100× Hoechst staining solution was added at a volume ratio of 1/100 for staining at room temperature for 20 minutes.
[0340] 11. The cell precipitation was washed twice with PBS solution, with 10 minutes each time. The staining of the cell masses was observed using a laser confocal microscope.
[0341]
TABLE-US-00029 TABLE 29 Immunofluorescence Staining Identification of Primary Cultures from Pleural Effusion of Lung Cancer Positive Rate of S/N Sample No. CK8/CK18 1 20170623WJD4442 0.750587399 2 20171212WPS8666 0.931396528 3 20180104FZH0918 0.756076105 4 20180329LYD7566 0.933623143 5 20180404QX8612 0.909249588 6 20180408ZMY8630 0.876574815 7 20180419WCY8644 0.931840881 8 20180504YAQ1360 0.919277775 9 20180501WZM1432 0.759422386 10 20180518YJD2931 0.877793597 11 20180523WYG2813 0.921129568 12 20180523YBM3283 0.838792271 13 20180614QX8612 0.771108906 14 20180828JP1921 0.824987208 15 20180912LGL3201 0.922425562 16 20180709XP0862 0.840305017 17 20180711JDL7423 0.91463045 18 20180810LAJ9251 0.923325274 19 20180817ZRS0912 0.905725702 20 20180821XHB2551 0.935186153
Embodiment 27. Primary Tumor Cell Cultures and Primary Tumor Tissues from Pleural Effusion of Lung Cancer
[0342] The DNA extraction mentioned in the following embodiment was performed with TIANGEN blood/tissue/cell genome Extraction Kit (DP304).
[0343] The library building mentioned in the following embodiment was performed with NEB DNA Sequencing and Library Building Kit (E7645).
[0344] The high-throughput sequencing mentioned in the following embodiment refers to the Illumina HiSeq X-ten sequencing platform.
[0345] 1. Pleural effusion samples of lung cancer were obtained, 20 mL of pleural effusion sample of lung cancer was firstly centrifugated before operations of in vitro culture taken, cell precipitation of pleural effusion was obtained for DNA extraction, library building and whole-genome high-throughput sequencing (WGS), and with a sequencing depth of 30× before in vitro culture operations were performed, the remaining pleural effusion samples of lung cancer were used for culturing in vitro primary tumor cells from pleural effusion of lung cancer (the specific method refers to that in the previously described embodiment).
[0346] 2. The pleural effusion samples of lung cancer were treated and cultured with the culture medium for primary cells for pleural effusion samples of lung cancer (Table 8, wherein the final concentration of human recombinant protein EGF was 60 ng/mL; the final concentration of human recombinant protein bFGF was 30 ng/mL; the final concentration of human recombinant protein MSP was 25 ng/mL; the final concentration of cortisol was 40 ng/mL; and the final concentration of Y-27632 was 15 μM) for a period of time to form cell masses with a diameter of more than 100 μm, which were recorded as P0-generation cells, followed by P1, P2, . . . , Pn successively according to the number of passages. 10.sup.6 cells were taken respectively from P1, P2, P3, P4 and P5-generation primary tumor cell cultures from pleural effusion of lung cancer for DNA extraction, library building and whole-genome high-throughput sequencing (WGS), with a sequencing depth of 30×.
[0347] 3. Copy number variation analysis (CNV) was performed based on the sequencing results of each group, and the copy number variations between cancer cells in pleural effusion of lung cancer and all generations of primary cell cultures from pleural effusion of lung cancer were compared. As shown in
Embodiment 28. Comparing Success Rates of Different Primary Cell Culture Media for Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0348] The operation methods and processes for culturing primary cells from all samples in this embodiment were identical (as mentioned above), and the only difference lied in the culture medium formula. Various tested primary cell culture media are shown in Table 30. Wherein Scheme D is the formula used in the present invention, with details in Table 8 (wherein the final concentration of human recombinant protein EGF was 60 ng/mL; the final concentration of human recombinant protein bFGF was 30 ng/mL; the final concentration of human recombinant protein MSP was 25 ng/mL; the final concentration of cortisol was 40 ng/mL; and the final concentration of Y-27632 was 15 μM).
TABLE-US-00030 TABLE 30 Primary Cell Culture Medium Formula For Test (100 mL) Final Culture Medium Reagent Brand Article No. Dosage Concentration Scheme A mTeSR ™1 medium Stemcell#05850 100 mL Scheme B Alveolar Epithelial ScienCell#3201 100 mL Cell Medium Scheme C Dual-antibody P/S Gibco#15140122 1 mL 1% HEPES Gibco#15630080 1 mL 10 mM 1,000 × human 1,000 × stock 250 μL 50 ng/mL recombinant protein solution EGF 1,000 × human 1,000 × stock 100 μL 20 ng/mL recombinant protein solution bFGF DMEM/F12 culture Gibco# 14170161 Added to medium 100 mL Scheme D See Table 8
[0349] After being prepared, the primary cell culture media were filtered and sterilized with a 0.22 μM syringe-driven strainer (Millipore SLGP033RS). The primary cell culture media can be stored at 4° C. for two weeks.
[0350] 20 pleural effusion samples of lung cancer were treated according to each of the four primary cell culture medium schemes, the sample treatment and culture operations were performed according to the methods described in embodiments 19, 20 and 21, and the success rates of those primary cell culture media for culturing primary tumor cells from pleural effusion of lung cancer were counted after 10 days of culturing, as shown in Table 31:
TABLE-US-00031 TABLE 31 Culturing in different media Primary cell culture medium scheme Success rate Scheme A 0% (0/20) Scheme B 0% (0/20) Scheme C 20% (4/20) Scheme D 85% (17/20)
[0351] It can be seen that primary cell culture media have an extremely great impact on the success rate of culturing primary cells from pleural effusion of lung cancer, and the culture medium for primary cells from pleural effusion of lung cancer used in the present invention (Table 8) can, to the greatest extent, stimulate the proliferation of cancer cells in the pleural effusion samples of lung cancer and improve the success rate of culturing primary tumor cells from pleural effusion of lung cancer.
Embodiment 29. Comparing Success Rates of Different Cell Digestion Solutions for Passaging Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0352] The operation methods and processes for passaging primary cells of all samples in this embodiment were identical (as mentioned above), and the only difference lied in the cell digestion solution formula. Various tested cell digestion solutions are shown in Table 32. Wherein Scheme D is the formula used in the present invention, and the details are shown in Table 6.
TABLE-US-00032 TABLE 32 Cell Digestion Solution Formula for Test (10 mL) Cell Digestion Final Solution Reagent Brand Article No. Dosage Concentration Scheme A Trypsin Gibco# 252,00056 10 mL 0.5M EDTA Invitrogen#AM9261 10 μL 5 mM Scheme B TrypLE ™ Gibco#12604013 Added to Express 10 mL Scheme C 10× 10× stock solution 1 mL 200 U/mL collagenase I 10× 10× stock solution 1 mL 200 U/mL collagenase II 20× 20× stock solution 0.5 mL 100 U/mL collagenase Gibco#21-040-CVR Added to IV 10 mL PBS Scheme D See Table 6
[0353] The cell digestion solution needs to be prepared just before use.
[0354] 20 successfully cultured pleural effusion samples of lung cancer were selected, and the primary tumor cells from pleural effusion of lung cancer obtained by culture were continuously passaged with the above four cell digestion solutions respectively according to the method described in Embodiment 22. Passaging (for no more than 10 times) was performed every time cancer cells amplified and formed cell masses with a diameter of 100 μm, and the maximum passaging number was recorded. The statistical results are as shown in Table 33:
TABLE-US-00033 TABLE 33 Culturing in Different Cell Digestion Solutions Scheme Scheme Scheme Scheme S/N Sample No. A B C D 1 20180912HEQ3227 0 2 5 9 2 20181029FJP6863 0 2 5 9 3 20181030YLM0526 1 3 6 10 4 20181109ZCY1117 0 0 2 10 5 20181112FSL8342 0 1 3 6 6 20181123RBH9525 1 3 7 10 7 20181130ZZC0128 0 1 3 6 8 20181224ZPB2339 0 2 6 10 9 20180513HB1783 0 2 4 8 10 20180606ZSD6376 0 2 5 10 11 20180607LYS8025 0 1 5 10 12 20180710LSW2025 1 4 7 10 13 20180724CRQ4027 0 0 3 6 14 20180830CDD0046 0 2 5 9 15 20180831HZM4008 0 1 4 7 16 20180904CRH4057 1 3 6 9 17 20180801YDH1008 1 2 5 10 18 20181126QSM6029 0 2 5 9 19 20180629LGQ0829 0 2 4 8 20 20180521LHF5893 0 2 7 10 Summary of passaging 0-1 0-4 2-7 More than number times times times 6 times
[0355] It can be seen that different cell digestion solutions have a very great impact on the success rate of passaging primary tumor cells from pleural effusion of lung cancer, and the cell digestion solution used in the present invention (Table 6) can mildly dissociate the cancer cells in the cell masses to continuously passage the samples and maintain the activity of primary tumor cells from pleural effusion of lung cancer.
Embodiment 30. Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer with Cell Culture Consumables of Different Materials
[0356] The operation methods and processes of primary culturing of all samples in this embodiment were identical (as mentioned above), and the only difference lied in the cell culture consumable material (unmodified) (Table 34).
TABLE-US-00034 TABLE 34 Effects of Unmodified Culture Consumables of Different Materials on Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer S/N Sample No. PS PC PMMA COC COP LAS 1 20180620YSF6868 Passed Passed Passed Passed Passed Passed 2 20180521LSM1885 Failed Failed Failed Passed Failed Passed 3 20180514ZCR1379 Failed Failed Passed Passed Passed Passed 4 20181203HFL0708 Failed Failed Passed Passed Failed Passed 5 20181201YXZ0503 Failed Failed Failed Failed Failed Failed 6 20181117SXH1455 Failed Failed Failed Failed Failed Passed 7 20181207AYD7020 Failed Failed Failed Failed Failed Passed 8 20181024XQH1632 Passed Failed Passed Passed Failed Passed 9 20181202XTN1215 Failed Failed Failed Failed Failed Passed 10 20180606YB2673 Passed Passed Passed Passed Passed Passed Success Rate 3/10 2/10 5/10 6/10 3/10 9/10 Notes: Polystyrene (abbreviated as PS), Polycarbonate (abbreviated as PC), poly-methyl methacrylate (abbreviated as PMMA), COC resin, Cyclo Olefin Polymer (abbreviated as COP), low-attachment-surface (abbreviated as LAS).
[0357] It can be seen from Table 34 that culture consumables of different materials have a certain impact on the success rates for culturing primary tumor cells from pleural effusion of lung cancer, wherein the success rate of low-attachment-surface (LAS) is the highest.
Embodiment 31. Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer with CYTOP-Modified Cell Culture Consumables of Different Materials
[0358] The operation methods and processes of primary culturing of all samples in this embodiment were identical (as mentioned above), the CYTOP modification methods were identical, and the only difference lied in the cell culture consumable material (Table 35).
[0359] Wherein the CYTOP modification method was that: firstly, pure oxygen etching was performed based on the cell culture vessel at a power of 20 W power for 3 minutes. Then the surface of a culture dish or culture plate was covered with an appropriate amount (taking a 96-well plate as an example, with 20 μL per well, an appropriate amount refers to complete coverage of the bottom of the culture dish) of 1% CYTOP solution (see Table 36 for the formula), and the vessel could be used after the CYTOP solution was completely dried in the air.
TABLE-US-00035 TABLE 35 Effects of CYTOP-modified Culture Consumables of Different Materials on Culturing Primary Tumor Cells from Pleural Effusion of Lung Cancer S/N Sample No. PS PC PMMA COC COP LAS 1 20190104RBH9525 Passed Passed Passed Passed Passed Passed 2 20190103QJF2041 Failed Failed Failed Failed Failed Failed 3 20190103ZXH8882 Passed Passed Passed Passed Passed Passed 4 20190215LY0508 Passed Passed Passed Passed Passed Passed 5 20190606LBD0034 Passed Passed Passed Passed Passed Passed 6 20190505FQ5060 Passed Passed Passed Passed Passed Passed 7 20190428YJH1590 Passed Passed Passed Passed Passed Passed 8 20190527KDY1723 Failed Failed Failed Failed Failed Failed 9 20190425SSS1683 Passed Passed Passed Passed Passed Passed 10 20190523ZYH2893 Passed Passed Passed Passed Passed Passed Success Rate 8/10 8/10 8/10 8/10 8/10 8/10
[0360] It can be seen from Table 35 that: CYTOP modification can effectively improve the culture success rates of various materials.
TABLE-US-00036 TABLE 36 1% CYTOP Solution (100 mL) Final Reagent Brand Article No. Dosage Concentration CYTOP Asashi 1 mL 1% glass#CTL-809M Fluorocarbon oil 3M# FC40 Added to 100 mL
[0361] The prepared 1% CYTOP solution can be stored at a normal temperature for a long time.
Example 32. Performing Chemosensitivity Assay with Primary Tumor Cells from Pleural Effusion of Lung Cancer
[0362] All the chemotherapeutic agents used in this embodiment, such as Taxol, Pemetrexed and Cis-platin, are Selleck products.
[0363] The Celltiter-Glo cell viability test kit mentioned in this embodiment is a Promega product.
[0364] An in vitro chemosensitivity assay was performed for the primary tumor cells from pleural effusion of lung cancer cultured by the present invention: primary cells were inoculated at a density of 10.sup.5/well in a 96-well low-attachment cell culture plate of standard size, and 5 drug concentration gradients were set for each drug, n=3. After dosing, the cells were incubated under the condition of 37° C. and 5% CO.sub.2 for 7 days. Following the end of drug action, the cell viability in each well was detected by the Celltiter-Glo cell viability assay kit. The experimental results are as shown in
Embodiment 33. Processing a Microplate Chip
[0365] In the embodiment, a microplate chip used for culturing the primary cells of lung cancer in the present invention was made from PMMA material (or PS, PC, COC, COP, LAS and other materials) by injection molding. The chip can be used for culturing primary cells of lung cancer and conducting in vitro chemosensitivity assay. The design drawing of the microplate chip is shown in
[0366] Specifically, in the process of practical application, the microplate chip structure (design drawing as shown in
Embodiment 34. Culturing Primary Cells from Lung Cancer Samples of Various Pathological Types
[0367] Primary cells were cultured from the surgical samples, puncture samples and pleural effusion samples of non-small-cell lung cancer adenocarcinoma, non-small-cell lung cancer squamous cell carcinoma and small cell lung cancer by the previously described methods, and the cultures are as shown in Table 37.
TABLE-US-00037 TABLE 37 Culturing Primary Cells from Lung Cancer Samples of Various Pathological Types Culture (number of successful cases/number of S/N Sample No. total cases) Adenocarcinoma Surgical sample 35/40 Puncture sample 4/5 Pleural effusion 33/40 sample Squamous cell Surgical sample 14/20 carcinoma Puncture sample 1/2 Pleural effusion 5/7 sample Small cell lung Surgical sample 4/6 cancer Puncture sample 2/3 Pleural effusion 7/10 sample
[0368] It can be seen from Table 37 that all the lung cancer samples of various pathological types can be used to culture primary cells of lung cancer at a higher success rate.
INDUSTRIAL APPLICATION
[0369] The present invention provides a method for culturing primary tumor cells from fresh solid tumor tissues of lung cancer or pleural effusion of lung cancer and the auxiliary reagents. The method has the following advantages: for solid tumor tissues of lung cancer, the amount of the tissue sample required is small, and only about 20 mg of surgical sample of lung cancer is required. For pleural effusion of lung cancer, the sample is easy to obtain, and the pleural effusion discharged from patients with lung cancer during the conventional treatment is utilized to the greatest extent, and there's no additional trauma or pain for the patients; the amount of the sample required is small, and only about 50 mL of pleural effusion of lung cancer is required; there's no need to process the samples immediately after collection, and the present method can guarantee a cell viability of more than 90% for up to 72 hours after the sample is ex vivo. The culture cycle is short, and it only takes 3-10 days to obtain the primary tumor cells with the order of magnitude of 10.sup.7. The culture stability is high, and the success rate of the method for culturing in vitro qualified surgical samples of lung cancer is as high as 70%-80%. The cell purity is high, and the proportion of cancer cells in the primary cell cultures of lung cancer obtained by the present method can reach up to 70%-95%, with less interference from miscellaneous cells. The primary cell cultures of lung cancer obtained by the method of the present invention can be used for various cell-level in vitro tests, next generation sequencing, construction of animal models, construction of cell lines and the like. It is predictable that this culture method will have a broad application prospect in the fields of lung cancer research, clinical diagnosis, and treatment.