https://doi.org/10.31449/inf.v44i2.3177 Informatica 44 (2020) 285–286 285
Artiﬁcial Intelligence Methods for Modelling Tremor Mechanisms
Vida Groznik
University of Primorska, Faculty of Mathematics, Natural Sciences and Information Technologies, Koper, Slovenia
University of Ljubljana, Faculty of Computer and Information Science, Ljubljana, Slovenia
E-mail: vida.groznik@famnit.upr.si
Thesis summary
Keywords: tremor, attribute visualisation, digital spirography
Received: May 28, 2020
The paper summarises a Doctoral Thesis in which we focus on two main goals: (1) building models for
differentiation between three most common tremors: Parkinsonian, essential and mixed type tremor and
(2) development of a novel method for attribute visualisation on series.
Povzetek:
ˇ
Clanek povzema vsebino doktorske disertacije, v kateri se osredotoˇ camo na dva glavna cilja:
(1) gradnja modelov za razloˇ cevanje med tremi najpogostejšimi tremorji: parkinsonskim, esencialnim in
mešanim tipom tremorja ter (2) razvoj nove metode za vizualizacijo atributov na vrstah.
1 Introduction
Tremor is an involuntary movement of the body and is one
of the most common movement disorders. It is primarily
associated with various diseases of the nervous system, in-
cluding Parkinson’s disease. Since there are more than 20
different types of tremors, differentiation between them is
important from the treatment point of view.
Spirography is a diagnostic method where the subject’s
task is to draw a left-twisted spiral while the doctor ob-
serves the process of drawing (speed, hesitation, etc.) and
the ﬁnal drawing. With the development of tablets digi-
talised spirography emerged, making it possible to store the
course of spiral drawing and the analysis of the acquired
time series.
In order to increase conﬁdence in such a system, we
would need to provide an explanation of the results to doc-
tors. One option is to visualize the anomalies and results
onto the drawn spirals. These visualizations must make
sense to physicians and, above all, they must be consistent
with their medical knowledge of the domain.
This paper summarises a Doctoral Thesis [1] which tries
to address the need for automatic differentiation of tremors
and visualisation of the decisions such system would give.
2 Diagnostic models for tremor
differentiation
In the thesis, we focus on differentiation between three
of the most common tremors: Parkinsonian, essential and
mixed type of tremor. For the purpose of building the di-
agnostic models, we used the digitalised spirography for
collecting the data needed.
The ﬁrst diagnostic model distinguishes between the
three tremors, based on clinical examination data, family
history and digital spirography. The process of building
a model was carried out using argument-based machine
learning technique which enabled us to build a decision
model through the process of knowledge elicitation from
the domain expert (a neurologist). The obtained model
consists of thirteen rules that are medically sensible. The
process of knowledge elicitation itself contributed to the
higher classiﬁcation accuracy of the ﬁnal model in com-
parison with the initial one [2, 5].
In the ﬁrst diagnostic model, attributes derived from the
spirography were included in more than half of the rules.
This motivated us to build a model based solely on the
digital spirography data. For the needs of constructing
an understandable model, we ﬁrst built several attributes
which represented domain medical knowledge. We have
built more than 500 different attributes which were used in
a logistic regression to construct the ﬁnal diagnostic model.
The model is able to distinguish subjects with tremors from
those without tremors with 90% classiﬁcation accuracy.
The ﬁnal diagnostic model is built into the freely available
PARKINSONCHECK mobile application [6].
3 Method for attribute visualisation
During the process of attribute construction, we wanted to
know what our attributes were detecting. Thus, we have de-
veloped a method for attribute visualisation on series. The
method not only helped us with attribute construction, but
it is also useful for visual interpretation of the diagnostic
model’s decisions. The visualisation method and conse-
quently the decision model were evaluated with the help of
three independent neurology experts. The results show that
286 Informatica 44 (2020) 285–286 V . Groznik
both the diagnostic model and the visualisation are mean-
ingful and cover medical knowledge of the domain.
Different visualisation approaches and their beneﬁts
have been published in several peer reviewed publications
[3, 4, 7].
4 Conclusion
The Thesis [1] describes the development of different di-
agnostic models for digitalised spirography systems. The
emphasis is given to elicitation of expert’s knowledge and
including that knowledge into the built-in attributes. To
increase physicians’ conﬁdence in such systems, a novel
method for attribute visualisation has been proposed. The
results were published in several peer-reviewed publica-
tions [2, 3, 4, 5, 6, 7].
References
[1] Groznik, V . (2018) Metode umetne inteligence za
modeliranje mehanizmov tremorjev: doktorska dis-
ertacija. Ljubljana. 139 pages, ilustr.
http://eprints.fri.uni-lj.si/4134/.
[2] Groznik, V ., Guid, M., Sadikov, A., Možina, M.,
Georgiev, D., Kragelj, V ., Ribariˇ c, S., Pirtošek, Z.,
and Bratko, I. (2013) Elicitation of neurological
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