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1. Q586B2 is a crucial virulence factor during the early stages of Trypanosoma brucei infection that is conserved amongst trypanosomatids

2. Ontogeny, functions and reprogramming of Kupffer cells upon infectious disease

3. The Role of MIF and IL-10 as Molecular Yin-Yang in the Modulation of the Host Immune Microenvironment During Infections: African Trypanosome Infections as a Paradigm

4. Targeting the tsetse-trypanosome interplay using genetically engineered Sodalis glossinidius.

5. Hepatocyte-derived IL-10 plays a crucial role in attenuating pathogenicity during the chronic phase of T. congolense infection.

6. The tumour microenvironment harbours ontogenically distinct dendritic cell populations with opposing effects on tumour immunity

7. Bone marrow-derived monocytes give rise to self-renewing and fully differentiated Kupffer cells

8. African Trypanosomiasis-Associated Anemia: The Contribution of the Interplay between Parasites and the Mononuclear Phagocyte System

9. Nanobodies As Tools to Understand, Diagnose, and Treat African Trypanosomiasis

10. MIF-Mediated Hemodilution Promotes Pathogenic Anemia in Experimental African Trypanosomosis.

11. Ly6C- Monocytes Regulate Parasite-Induced Liver Inflammation by Inducing the Differentiation of Pathogenic Ly6C+ Monocytes into Macrophages.

12. Development of a pHrodo-based assay for the assessment of in vitro and in vivo erythrophagocytosis during experimental trypanosomosis.

13. Ablation of NK Cell Function During Tumor Growth Favors Type 2-Associated Macrophages, Leading to Suppressed CTL Generation

16. MIF contributes to Trypanosoma brucei associated immunopathogenicity development.

17. A Trypanosoma brucei kinesin heavy chain promotes parasite growth by triggering host arginase activity.

19. Monocytes contribute to differential immune pressure on R5 versus X4 HIV through the adipocytokine visfatin/NAMPT.

20. Tsetse salivary gland proteins 1 and 2 are high affinity nucleic acid binding proteins with residual nuclease activity.

21. Affinity is an important determinant of the anti-trypanosome activity of nanobodies.

22. High affinity nanobodies against the Trypanosome brucei VSG are potent trypanolytic agents that block endocytosis.

23. Tip-DC development during parasitic infection is regulated by IL-10 and requires CCL2/CCR2, IFN-gamma and MyD88 signaling.

24. Identification of a tsetse fly salivary protein with dual inhibitory action on human platelet aggregation.

25. Trypanosoma brucei modifies the tsetse salivary composition, altering the fly feeding behavior that favors parasite transmission.

26. The role of B-cells and IgM antibodies in parasitemia, anemia, and VSG switching in Trypanosoma brucei-infected mice.

27. Macrophages, PPARs, and Cancer

28. Supplementary Tables S1-S2 from M-CSF and GM-CSF Receptor Signaling Differentially Regulate Monocyte Maturation and Macrophage Polarization in the Tumor Microenvironment

29. Data from M-CSF and GM-CSF Receptor Signaling Differentially Regulate Monocyte Maturation and Macrophage Polarization in the Tumor Microenvironment

30. Supplementary Figures S1-S9 from M-CSF and GM-CSF Receptor Signaling Differentially Regulate Monocyte Maturation and Macrophage Polarization in the Tumor Microenvironment

31. Supplementary Figures 1 through 5 from Tumor Hypoxia Does Not Drive Differentiation of Tumor-Associated Macrophages but Rather Fine-Tunes the M2-like Macrophage Population

32. Supplementary Figures 1-8, Video Legends 1-3 from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

33. Supplementary Methods from Tumor Hypoxia Does Not Drive Differentiation of Tumor-Associated Macrophages but Rather Fine-Tunes the M2-like Macrophage Population

34. Supplementary Methods from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

35. Supplementary Materials, Tables 1-4, Figures 1-10 from Different Tumor Microenvironments Contain Functionally Distinct Subsets of Macrophages Derived from Ly6C(high) Monocytes

36. Supplementary Video 1 from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

37. Data from Different Tumor Microenvironments Contain Functionally Distinct Subsets of Macrophages Derived from Ly6C(high) Monocytes

38. Supplementary Methods from M-CSF and GM-CSF Receptor Signaling Differentially Regulate Monocyte Maturation and Macrophage Polarization in the Tumor Microenvironment

39. Supplementary Tables 1-5 from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

40. Supplementary Video 3 from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

41. Supplementary Tables 1 and 2 from Tumor Hypoxia Does Not Drive Differentiation of Tumor-Associated Macrophages but Rather Fine-Tunes the M2-like Macrophage Population

42. Supplementary Video 2 from Nanobody-Based Targeting of the Macrophage Mannose Receptor for Effective In Vivo Imaging of Tumor-Associated Macrophages

43. Targeting the tsetse-trypanosome interplay using genetically engineered Sodalis glossinidius

45. Hepatocyte-derived IL-10 plays a crucial role in attenuating pathogenicity during the chronic phase of T. congolense infection

46. Reprint of: The non-mammalian MIF superfamily

47. Monocytic myeloid-derived suppressor cells home to tumor-draining lymph nodes via CCR2 and locally modulate the immune response

48. Molecular Imaging with Kupffer Cell-Targeting Nanobodies for Diagnosis and Prognosis in Mouse Models of Liver Pathogenesis

49. Neutrophils enhance early Trypanosoma brucei infection onset

50. Novel half-life extended anti-MIF nanobodies protect against endotoxic shock

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