Case 14 Flashcards
What are component causes?
Factors that work together with the necessary cause to produce disease.
Overcrowding and TB
What is a necessary cause?
A factor that must be present for a disease to occur.
What is a sufficient cause?
A combination of factors that is sufficient to cause disease in at least some people
Levels of causation: upstream factors
Social - gender, race, SES
Population: income inequality, lack of social cohesion, inadequate medical services
Levels of causation: downstream factors
Physiological: genetics, sex, age
Behavioural: smoking, diet, exercise, alcohol
Ecological model: levels of causation
Biological
Behavioural
Societal
Structural
Evidence based practice
Assess your patient Ask the right question Access the evidence Appraise the evidence Apply the evidence Audit your clinical practice
Which study designs are best for evaluating potential harms?
Case reports can’t draw generalisable conclusions
Case control prone to bias and confounding
Trials not useful for long term effects
Cohort studies with a large representative sample, objective measures of exposure and outcome and good long term follow up are good
Systematic reviews of all the good evidence are best
Is an apparent association real?
Bias?
Confounding?
Chance?
Is the association causal? Bradford Hill
Bradford hill criteria
Does cause precede effect? What is the strength of the effect? Is there a dose-response effect? Is there biological plausibility? Has the effect been consistently shown in similar studies in different populations?
Acute leukaemia non-specific presenting features
Unwell Tired Aches and pains Fever Often little to find on exam but may have bleeding, sepsis, pallor
NB if symptoms persist/get worse
Acute leukaemia specific features
Bone marrow infiltration: anaemia, bleeding, infections
Tissue infiltration: gum hypertrophy, lymphadenopathy, splenomegaly, CNS disease (ALL)
Tests used toc lassify acute leukaemia
Morphology (peripheral blood and bone marrow) Cytochemistry Immunophenotype ( flow cytometry) Genetic abnormalities (FISH, PCR)
Leukaemia initial diagnosis
FBC
Differential count
Morphological review of peripheral blood slide
Leukaemia definitive diagnosis
Bone marrow aspirate/trephine biopsy
Aspirate provides cells for cytogentic/molecular studies
Leukaemia additional non-diagnostic tests
LP to exclude CNS disease
HIV test
DIC screen
Electrolytes and renal function
Supportive therapy
Packed red cell transfusion for anaemia
Platelet transfusion for thrombocytopaenia
Hydration and allopurinol for tumour lysis syndrome
Prevention and treatment of infections
Anti emetics to prevent chemo-associated nausea
Primary lymphoid organs
Bone marrow
Thymus
Main Th1 cytokines
IL-2, TNF beta, IFN gamma
Cell mediated response
Main Th2 cytokines
IL-4, IL-10
Antibody response
A chromosomal translocation may result in
Fusion protein product
Aberrant expression of normal protein
Karyotype analysis
Direct morphological observation of chromosomes under a microscope
Requires cells to be in metaphase
Therefore cell culture is performed before analysis
FISH
Uses fluorecent-labelled genetic probes which hybridize to different parts of the genome and allow visualization of karyotype abnormalities
How is acute leukaemia defined?
> 20% blasts in blood or BM at presentation
Abnormalities leading to build up of leukaemic cells
Increased rate of proliferation
Avoidance of apoptosis
Block in differentiation
Modes of action of antibodies
Neutralisation
Opsonisation
Agglutination
Activation of classical complement pathway
General properties of immunity
Specificity
Versatility
Memory
Tolerance
Secondary lymphoid tissues
Lymph nodes Spleen Tonsils MALT BALT
T cell mediated killing
Perforin release
Release of granzyme proteases
Fas ligand
NK cell killing
NK cells are inhibited by class 1 MHC which are not expressed at normal levels on cancer or virally infected cells
Perforin release
Macrophage activation
Structure of the lymph node
Dense connective tissue capsule pierced by afferent lymphatics with valves.
Fibrous trabeculae
Subcapsular space flows into paratrabecular sinuses - lined with macrophages.
Outer cortex with follicles, inner cortex, medulla
Medullary sinuses surrounded by medullary cords.
One efferent lymphatic vessel
Where do most lymphocytes enter the lymph node?
High endothelial venules in the inner cortex
Where in the lymph node are plasma cells found?
In the medullary cords where they can secret antibodies directly into the medullary sinusoids without leaving the lymph node
What is the function of follicular dendritic cells?
Mature activated B cells migrate to the germinal centre where they must interact strongly with whole antigen presented by FDCs in order to proliferate or else they accumulate in the mantle zone and undergo apoptosis and phagocytosis by macrophages.
Structure of the thymus
Fibrous capsule
Two lobes, divided into incomplete lobules by fibrous trabeculae containing trabecular arterioles
Cortex contains thymic epithelial cells organised in a 3D network supported by collagen fibres
Thymic epithelial cells populate the medulla. Some form Hassal’s corpuscles which produce thymic stromal lymphopoeitin which optimises negative selection
Blood thymus barrier
Double basal lamina
Endothelial cells linked by tight junctions
Thymic epithelial cells surround capillaries and are linked tightly by desmosomes
Macrophages engulf foreign antigen
General organisation of the spleen
Surrounded by a fibrous capsule. Capsule-derived trabeculae penetrate the stroma carrying trabecular arteries and veins
No cortex/medulla. No afferent lymphatics
Stroma consists of reticular fibres supporting the red and white pulp
Component of the splenic white pulp
Central arteriole
PALS
Corona containing B cells and APCs
Germinal centre
Red pulp
Interconnected network of splenic sinusoids lined by elongated endothelial cells.
Splenic cords separate splenic sinusoids.
Splenic cords contain plasma cells, macrophages and blood cells.
Vascularisation of the spleen
Splenic artery enters at the hilum Trabecular arteries Central arteriole + radial arterioles + marginal sinus Penicillar artery Macrophage sheathed capillaries Splenic sinusoids or red pulp stroma
How is the classical complement pathway activated?
Binding of C1 to an antigen bound antibody
