2. Objectives
Support of medical decision making: for the single patient
provide a correct diagnosis
selection of an optimal therapy
correct assessment of prognosis
optimal patient`s management in medical institution
3. Knowledge-Based Methodology knowledge level
modelling of mental processes; linguistically communicated
modelling based on symbols (linguistic concepts = abstract concepts)
objective and subjective knowledge (definitional, causal, statistical, and heuristic knowledge)
measurements and observational level
measured and observed data
data-to-symbol conversion
9. Fuzziness in Medicine vagueness of medical concepts
gradual transition from one concept to another
uncertainty of medical conclusions
uncertainty of co-occurrence of vague medical concepts
incompleteness of medical data and medical theory
partially known data and partially known explanations of medical phenomena
10. ��FuzzyKBWean:�A Fuzzy Control System for�Weaning from Artificial Ventilation
C. Schuh, M. Hiesmayr, K.-P. Adlassnig
Department of Medical Computer Sciences
Department of Cardiothoracic and Vascular Anaesthesia and Intensive Care
University of Vienna Medical School and Vienna General Hospital
11. Objective mechanically ventilated patients after cardiothoracic surgery in an Intensive Care Unit (ICU)
proposals for changes of the ventilator settings during the three phases of mechanical ventilation (stabilization, weaning, and finally extubation of the patient)
open-loop system: integration into the patient data management system (PDMS) ; time resolution: 1 minute
closed-loop system as a long-term objective: integration into the ventilator (auto-mode)
14. Structure of FuzzyKBWean
15. Methods phase-dependent fuzzy sets
linguistic If/Then rules
If: patient’s physiological parameters and ventilator measurement parameters (in a defined context)
Then: proposals for changes of ventilator settings
fuzzification step
arithmetic, statistical, comparative, logical, temporal, and control operators
defuzzification step
center of gravity method
verification by the attending physician, i.e., open-loop
16. Ed27.gifEd27.gif
18. Fuzzy Control
19. Knowledge Base
20. PATIENT:
23. Results – 1 23 variables
74 fuzzy sets (phase-dependent)
16 If/Then rules
4 rules checking for measurement errors and validity
3 rules for ventilation (normal range, hypoventilation, hyperventilation)
4 rules for oxygenation (stabilization, oxygenation normal, hypoxia, severe hypoxia)
4 rules for intermediate states (increased EtCO2, decreased EtCO2, phase changes)
1 rule for extubation
24. Weaning Rule Wean_1 If
mean EtCO2 during the last 30 minutes
is contained in fuzzy set EtCO2_wean_normal
and if
rule Wean_1
has not been activated
during the last 30 minutes
and if
EtCO2 is valid
and if
EtCO2 is normal
Then
PIP -3
25. Results – 2 10 prospectively randomized patients
FuzzyKBWean reacted correctly 131 (SEM 47) minutes earlier than the attending physician
adjustment of ventilation parameters was more reliable than adjustment of oxygenation (EtCO2 is more reliable as SpO2)
phase-specific rules often proposed too small changes of the ventilator settings
temporal rule blocking, fuzzy set adaptations, employing thresholds to avoid oscillations
26. Results – 3�Delay of Staff Reaction in Case of Hyperventilation
27. Discussion methodology
minimal number of therapeutically significant classes per variable
gradual transition between variable classes
adequat consideration of inherent vagueness of medical concepts
intuitive If/Then rules on the knowledge level
physician`s medical knowledge was transfered to FuzzyKBWean
clinical trial
periods of deviation from the target parameters are shorter
contribution to patient`s safety and comfort
closed-loop: recognition of artifacts and information obtained by direct observation of the patient
28. CADIAG-II:�A Hospital-Based Consultation System for�Internal Medicine Klaus-Peter Adlassnig, G. Kolarz
Department of Medical Computer Sciences
University of Vienna Medical School
29. Objectives diagnostic hypotheses, confirmed and excluded diagnoses
indication of rare diseases
proposals for further examinations
ranked according to invasiveness and costliness
pathological findings not yet accounted for
search for further diagnoses
correct and complete differential diagnoses
at minimal risk for the patient and costs for the health care system
31. CADIAG-II: Methods patient data
symptom, signs, and test results are modelled as context dependent fuzzy sets
diseases or diagnoses takes values in [0,1]
knowledge representation
symptom and disease hierarchies
crisp rule and fuzzy set based data-to-symbol conversion
symptom/disease, symptom/symptom, disease/disease relationships, and complex diagnostic rules with frequency of occurrence and strength of confirmation
inference mechanism
manifold application of the compositional rule of fuzzy inference
38. Examples Example 1 (indicating):
IF elevated amylase level in serum
THEN acute pancreatitis
WITH (?O = very often [?O = 0.90], ?B = strong [?C = 0.70]).
Example 2 (necessary and sufficient):
IF rheumatoid arthritis and
splenomegaly and
leukopenia less than 4 giga/l
THEN Felty’s Syndrom
WITH (?O = always [?O = 1.00], ?C = confirming [?C = 1.00]).
40. Inference Mechanism
51. Results Rheumatology
more than 200 disease profiles, more than 2.000 findings
more than 50.000 finding-disease-relationships
more than 160 complex rules
Hepatology and Gastroenterology
more than 100 disease profiles, more than 1.000 findings
more than 30.000 symptom-disease-relationships
more than 40 complex rules
52. Evaluation
53. MedFrame/CADIAG-IV:�A Consultation System Framework �for Internal Medicine and Related Areas Klaus-Peter Adlassnig
Department of Medical Computer Sciences
University of Vienna Medical School
54. Objectives CADIAG-IV
positive and negative diagnostic hypotheses, confirmed and excluded diagnoses
positive and negative therapy proposals, necessary and excluded therapies
MedFrame
shell for medical knowledge-based systems
knowledge-based telemedicine service
55. MedFrame/CADIAG-IV:�Methods extension of CADIAG-II:
symptoms, diseases, and therapies
context-sensitive data-to-symbol conversion and patient specific adaptation of the knowledge base
extended knowledge representation with step-by-step knowledge acquisition refinement
MedFrame
client/server architecture, WWW compatible
integrated patient data and medical knowledge base
56. MedFrame Structure
59. Symptom-Disease Relationships
61. MedFrame/CADIAG-IV:�Discussion mainframe CADIAG-II to Medframe/CADIAG-IV
integrated patient data and medical knowledge base
patient data and knowledge transfer
theoretical extensions
extension of the relationship, rule, and inference concept
medical extensions
rheumatology, hepatology, gastroenterology, radiology, neurology
HEPAXPERT, TOXOPERT in MedFrame
62. Conclusions knowledge-based systems are becoming part of medical practice
computational intelligence in medicine
vagueness, uncertainty, and incompleteness of medical data and medical knowledge demand a flexible and extended formal framework
medical knowledge representation and inference
fuzzy set theory and fuzzy logic provide an appropriate solution
