727 results on '"Emdad, Luni"'
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52. Supplementary Figure S7 and S8 from The MDA-9/Syntenin/IGF1R/STAT3 Axis Directs Prostate Cancer Invasion
53. Data from The MDA-9/Syntenin/IGF1R/STAT3 Axis Directs Prostate Cancer Invasion
54. Supplementary Table 1 from Novel Role of MDA-9/Syntenin in Regulating Urothelial Cell Proliferation by Modulating EGFR Signaling
55. Supplementary Figure 7 from Novel Role of MDA-9/Syntenin in Regulating Urothelial Cell Proliferation by Modulating EGFR Signaling
56. Supplementary Figure 2 from Novel Role of MDA-9/Syntenin in Regulating Urothelial Cell Proliferation by Modulating EGFR Signaling
57. Supplementary Figure 5 from Novel Role of MDA-9/Syntenin in Regulating Urothelial Cell Proliferation by Modulating EGFR Signaling
58. Supplemental Materials from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
59. Supplemental Fig. 5 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
60. Supplementary Table 1 from BiP/GRP78 Is an Intracellular Target for MDA-7/IL-24 Induction of Cancer-Specific Apoptosis
61. Supplemental Fig. 6 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
62. Supplemental Fig. 8 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
63. Supplementary Figure 1 from Novel Mechanism of MDA-7/IL-24 Cancer-Specific Apoptosis through SARI Induction
64. Data from Novel Mechanism of MDA-7/IL-24 Cancer-Specific Apoptosis through SARI Induction
65. Data from Pancreatic Cancer Combination Therapy Using a BH3 Mimetic and a Synthetic Tetracycline
66. Supplementary Table S6 from Genetic Deletion of AEG-1 Prevents Hepatocarcinogenesis
67. Data from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
68. Supplementary Figure 1 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
69. Data from mda-7/IL-24 Induces Cell Death in Neuroblastoma through a Novel Mechanism Involving AIF and ATM
70. Supplementary Figure 7 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
71. Data from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
72. Supplemental Fig. 2 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
73. Supplementary Figure 4 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
74. Supplementary Figure 6 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
75. Supplemental Fig. 4 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
76. Supplemental Fig. 1 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
77. Data from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
78. Supplemental Table and Figure Legends from Genetic Deletion of AEG-1 Prevents Hepatocarcinogenesis
79. Data from Astrocyte Elevated Gene-1 Interacts with Akt Isoform 2 to Control Glioma Growth, Survival, and Pathogenesis
80. Supplementary Figure 3 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
81. Supplementary Figure 3 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
82. Supplemental Fig. 7 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
83. Supplementary Figures S1-S9 from Astrocyte Elevated Gene-1 Interacts with Akt Isoform 2 to Control Glioma Growth, Survival, and Pathogenesis
84. Supplementary Figure Legend from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
85. Supplemental Figures 1-8 from mda-7/IL-24 Induces Cell Death in Neuroblastoma through a Novel Mechanism Involving AIF and ATM
86. Supplementary Figure Legend from Novel Mechanism of MDA-7/IL-24 Cancer-Specific Apoptosis through SARI Induction
87. Supplementary Figure 5 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
88. Supplementary Figures S1-S5 from Genetic Deletion of AEG-1 Prevents Hepatocarcinogenesis
89. Supplementary Figure 2 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
90. Supplementary Methods and References from Genetic Deletion of AEG-1 Prevents Hepatocarcinogenesis
91. Supplementary Figure 1 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
92. Supplemental Fig. 3 from Pancreatic Cancer–Specific Cell Death Induced In Vivo by Cytoplasmic-Delivered Polyinosine–Polycytidylic Acid
93. Supplementary Figure 8 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
94. Supplementary Figure Legends 1-9 from Pancreatic Cancer Combination Therapy Using a BH3 Mimetic and a Synthetic Tetracycline
95. Supplementary Figure Legends from Astrocyte Elevated Gene-1 Interacts with Akt Isoform 2 to Control Glioma Growth, Survival, and Pathogenesis
96. Data from Genetic Deletion of AEG-1 Prevents Hepatocarcinogenesis
97. Supplementary Figure 4 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
98. Supplementary Figure 6 from MDA-9/Syntenin and IGFBP-2 Promote Angiogenesis in Human Melanoma
99. Supplementary Figure 2 from Novel Mechanism of MDA-7/IL-24 Cancer-Specific Apoptosis through SARI Induction
100. Supplementary Figure 5 from Oncogene AEG-1 Promotes Glioma-Induced Neurodegeneration by Increasing Glutamate Excitotoxicity
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