43 results on '"Lee, Lydia"'
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2. Table 1 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
3. Figure 2 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
4. Figure 1 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
5. Figure 3 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
6. Figure 5 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
7. Figure 2 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
8. Figure 1 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
9. Figure 4 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
10. Table 2 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
11. Figure 5 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
12. Table 1 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
13. Figure 3 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
14. Supplementary Data from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
15. Supplementary Table 10 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
16. Data from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
17. Data from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
18. Figure 6 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
19. Figure 4 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
20. Table 2 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
21. Figure 6 from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
22. Supplementary Data from Deep Learning Enables Spatial Mapping of the Mosaic Microenvironment of Myeloma Bone Marrow Trephine Biopsies
23. Deep learning enables spatial mapping of the mosaic microenvironment of myeloma bone marrow trephine biopsies
24. Supplementary Table S2 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
25. Figure from Marrow-Infiltrating Regulatory T Cells Correlate with the Presence of Dysfunctional CD4+PD-1+ Cells and Inferior Survival in Patients with Newly Diagnosed Multiple Myeloma
26. Supplementary Table S1 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
27. Supplementary Figure S2 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
28. Supplementary Figure S4 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
29. Supplementary Text from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
30. Supplementary Figure S2 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
31. Supplementary Figure S1 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
32. Supplementary Figure S3 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
33. Supplementary Table S2 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
34. Supplementary Figure S1 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
35. Supplementary Figure S5 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
36. Supplementary Figure S4 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
37. Supplementary Figure S6 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
38. Supplementary Text from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
39. Supplementary Figure S3 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
40. Supplementary Figure S6 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
41. Supplementary Figure S5 from Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
42. Marrow-Infiltrating Regulatory T Cells Correlate with the Presence of Dysfunctional CD4+PD-1+ Cells and Inferior Survival in Patients with Newly Diagnosed Multiple Myeloma
43. Development of a Colon Cancer GEMM-Derived Orthotopic Transplant Model for Drug Discovery and Validation
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