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- Fundamental aspects
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1. Inflammation and tissue homeostasis
- Prof. Herman Waldmann
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2. Introduction to the immune system
- Prof. Herman Waldmann
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3. Hematopoiesis: the making of an immune system
- Prof. Paul J. Fairchild
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4. Inflammation: purposes, mechanisms and development
- Prof. Pietro Ghezzi
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5. Phagocytosis
- Dr. Eileen Uribe-Querol
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6. Regulated cell death mechanisms and their crosstalk with the immune system 1
- Dr. Luis Alberto Baena-Lopez
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7. Regulated cell death mechanisms and their crosstalk with the immune system 2
- Dr. Luis Alberto Baena-Lopez
- Innate immunity
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11. Cells of the innate immune system
- Prof. Kevin Maloy
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12. Microbial recognition and the immune response
- Dr. Dana Philpott
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13. Toll-like receptor signalling during infection and inflammation
- Prof. Luke O'Neill
- Intercellular mediators
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14. Chemokines
- Dr. James E. Pease
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15. Cytokines
- Prof. Iain McInnes
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16. IL-1 family cytokines as the canonical DAMPs of the immune system
- Prof. Seamus Martin
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17. Glycans at the frontiers of inflammation, autoimmunity and cancer
- Prof. Salomé S. Pinho
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18. Glycoimmunology
- Prof. Paula Videira
- Adaptive immunity B cells
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21. Antigen recognition in the immune system
- Prof. Herman Waldmann
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22. B cell biology
- Prof. Richard Cornall
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23. Antibody structure and function: antibody structure
- Dr. Mike Clark
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24. Antibody structure and function: antibody function
- Dr. Mike Clark
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25. Antibody genes and diversity
- Dr. Mike Clark
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26. In vivo antibody discovery and hybridoma technology
- Prof. Dr. Katja Hanack
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27. Antibody engineering: beginnings to bispecifics and beyond
- Dr. Ian Wilkinson
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29. The immunobiology of Fc receptors
- Prof. Mark Cragg
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30. Immunoreceptors
- Prof. Anton van der Merwe
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31. Affinity, avidity and kinetics in immune recognition
- Prof. Anton van der Merwe
- Adaptive immunity T cells
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32. The thymus and T cell development: a primer
- Prof. Georg Holländer
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33. Lineage decisions in the thymus: T cell lineage commitment
- Prof. Bruno Silva-Santos
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34. Lineage decisions in the thymus: αβ and γδ T cell lineages
- Prof. Bruno Silva-Santos
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35. CD4 T cell subsets
- Dr. Brigitta Stockinger
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36. Cytotoxic T lymphocytes
- Prof. Gillian M. Griffiths
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37. Gamma delta T-cells
- Prof. Bruno Silva-Santos
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38. Tfh and Tfr cells
- Prof. Luis Graca
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39. Tissue resident memory T cells (TRM)
- Dr. Marc Veldhoen
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40. Mathematical modeling in immunology
- Prof. Ruy M. Ribeiro
- The importance of the MHC in immunity
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41. The MHC and MHC molecules 1
- Prof. Jim Kaufman
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42. The MHC and MHC molecules 2
- Prof. Jim Kaufman
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43. Natural killer cells
- Dr. Philippa Kennedy
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44. Human NK cells
- Prof. Lorenzo Moretta
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46. NK cells in viral immunity
- Prof. Lewis Lanier
- Lymphocyte activation
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47. Signal transduction by leukocyte receptors
- Dr. Omer Dushek
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48. Immunological memory 1
- Prof. David Gray
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49. Immunological memory 2
- Prof. David Gray
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50. Studying immune responses “one cell at a time”
- Dr. Mir-Farzin Mashreghi
- Major cellular partners in immunity
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51. The mononuclear phagocyte system - tissue resident macrophages: distribution and functions
- Prof. Emeritus Siamon Gordon
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52. The mononuclear phagocyte system: tissue resident macrophages - activation and regulation
- Prof. Emeritus Siamon Gordon
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53. Dendritic cells: professional antigen presenting cells
- Prof. Paul J. Fairchild
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54. Mucosal immunology
- Prof. Daniel Mucida
- Immunological tolerance and regulation
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55. Self-tolerance
- Prof. Herman Waldmann
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56. Tolerance and autoimmunity
- Prof. Emerita Anne Cooke
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57. The balance between intestinal immune homeostasis and inflammation
- Prof. Dr. Janneke Samsom
- Translational immunology - immune deficiency
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58. Primary immunodeficiency disorders
- Dr. Smita Y. Patel
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59. Changes in innate and adaptive immunity during human ageing 1
- Dr. Roel De Maeyer
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60. Changes in innate and adaptive immunity during human ageing 2
- Dr. Roel De Maeyer
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61. The aging immune system
- Prof. Ana Caetano
- Translational immunology - protection against pathogenic microbes
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62. Immune responses to viruses
- Prof. Paul Klenerman
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63. HIV and the immune system
- Prof. Quentin Sattentau
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64. COVID-19: the anti-viral immune response
- Prof. Danny Altmann
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65. Bacterial immune evasion
- Prof. Christoph Tang
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66. The immunology underlying tuberculosis
- Prof. Thomas R. Hawn
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67. Innate immunity to fungi
- Prof. Gordon D. Brown
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68. Parasite immunity: introduction and Plasmodium
- Dr. Catarina Gadelha
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69. Parasite immunity: Leishmania and Schistosoma
- Dr. Catarina Gadelha
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70. Vaccination
- Dr. Anita Milicic
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71. The history of vaccines 1
- Prof. Emeritus Anthony R. Rees
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72. The history of vaccines 2
- Prof. Emeritus Anthony R. Rees
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73. The history of vaccines 3
- Prof. Emeritus Anthony R. Rees
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74. The science of vaccine adjuvants
- Dr. Derek O'Hagan
- Translational immunology - hypersensitivity, autoimmune disease and their management
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75. Hypersensitivity diseases: type 1 hypersensitivity
- Prof. Herman Waldmann
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76. Innate lymphoid cells in allergy
- Prof. Emeritus Shigeo Koyasu
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77. Hypersensitivity diseases: type II-IV hypersensitivity
- Prof. Sara Marshall
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78. Immune memory underlying lifelong peanut allergy
- Dr. Kelly Bruton
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79. Memory B cells in allergy: B cell activation and response
- Dr. Kelly Bruton
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80. Memory B cells in allergy: ontogeny, phenotype and plasticity
- Dr. Kelly Bruton
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81. B cells at the crossroads of autoimmune diseases
- Dr. Xiang Lin
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82. Interleukin-17: from clone to clinic
- Prof. Leonie Taams
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83. Autoimmunity and type 1 diabetes
- Prof. Emerita Anne Cooke
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84. What is new in type 1 diabetes?
- Prof. Åke Lernmark
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85. Antibodies to control or prevent type 1 diabetes
- Dr. Robert Hilbrands
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86. Monoclonal antibodies in haemato-oncology
- Prof. Mark Cragg
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87. Therapeutic antibodies
- Dr. Geoffrey Hale
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88. Endothelial cells: regulators of autoimmune-neuroinflammation
- Dr. Laure Garnier
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89. Neuroimmunometabolism
- Prof. Ana Domingos
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90. The immunology of multiple sclerosis
- Dr. Joanne Jones
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91. Ocular immunology: an overview of immune mechanisms operating in the eye
- Dr. Eleftherios Agorogiannis
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92. Understanding myasthenia gravis and advances in its management
- Prof. Henry J. Kaminski
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93. The immunology underlying rheumatic diseases
- Dr. Hussein Al-Mossawi
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95. Complement and lupus
- Prof. Marina Botto
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96. Immune mechanisms in liver diseases
- Prof. Paul Klenerman
- Translational immunology - transplantation immunology
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97. Principles of transplantation: overview of the immune response
- Prof. Emerita Kathryn Wood
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98. Factors influencing outcomes in clinical transplantation 1
- Prof. Emerita Kathryn Wood
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99. Factors influencing outcomes in clinical transplantation 2
- Prof. Emerita Kathryn Wood
- Translational immunology - cancer immunology
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100. Cancer immunology
- Prof. Tim Elliott
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101. Cancer immunotherapy
- Prof. Tim Elliott
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102. Myeloid-derived suppressor cells in cancer
- Prof. Dmitry Gabrilovich
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103. IL-2 in the immunotherapy of autoimmunity and cancer
- Prof. Thomas Malek
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104. Latest advances in the development of CAR & TCR T-cell treatments for solid tumours
- Dr. Else Marit Inderberg
Printable Handouts
Navigable Slide Index
Topics Covered
- Inflammation
- Tissue homeostasis
- Evolution of inflammation and immunity
- Acute and chronic inflammation
- Participants in inflammation and immunity
Links
Series:
Categories:
Therapeutic Areas:
Talk Citation
Waldmann, H. (2021, October 31). Inflammation and tissue homeostasis [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved January 25, 2025, from https://doi.org/10.69645/WAAM1501.Export Citation (RIS)
Publication History
Financial Disclosures
- Herman Waldman has ownership interests in the Absolute Antibody company.
A selection of talks on Immunology
Transcript
Please wait while the transcript is being prepared...
0:00
My name is Herman Waldmann.
I'm from the Sir William Dunn School of Pathology and I am
going to be coordinating this immunology series.
The point of this introductory lecture,
is to introduce you to the role of inflammation
and immunity in relation to tissue homeostasis.
0:21
In other words, I want to be discussing how the immune system fits into
the evolution of animals and the way animals function.
When we think about it, multicellular organisms have generated diverse cells to
perform different functions, and they specialize.
It's very important for those various functions that they are well
controlled and that requires mechanisms of sensing
the amount of the product they make and also being able to affect a change in
that product to ensure that the animal has adequate signals,
not too many, not too little to enable those cells to function properly.
For example, they can sense
glucose and they can generate insulin or glucagon, they can sense oxygen,
and generate erythropoietin in the case of higher animals.
Is very important though,
that these tissues that have specific functions have through evolution got to
protect themselves against perturbations that could be from the outside,
pathogens, toxins, or from inside,
some damage from cell death or ischemia and so on.
These functions also require
homeostasis mechanisms that have become called inflammation and immunity.
Protection of our tissues to enable them to function depends
on a further interaction of the tissues with
inflammatory cells and cells of the immune system with
feedback pathways that will ensure effective function.
The whole point being that the cells need to sense the presence of the perturbing signal,
and in turn deliver effective signals to get rid of
the disruptive agent and also having got rid of
the disruptive agent to enable tissue integrity,
to return, remodeling,
repair, and so on.
This need for protecting the tissues has driven
the evolution of what we call the innate and adaptive immune system.
The innate just protection against anything
and develop an adaptive protection against very specific targets,
which we referred to in immunology as antigens.
The important thing is that this protection of the tissues
mustn't penalize the host or the tissues that it's protecting.
It has to be balanced and itself subject to homeostasis.
Of course, pathogens and their toxins have been a key driver of
such homeostatic mechanisms controlling inflammation and immunity.