Connections of Reduced Performance Health Data for Severe
Persistent Uncontrolled Allergic Asthma Treated by Omazulimab
Stefanos Matsopoulos and Valentina Plekhanova
Department of Computing, Enineering and Technology, University of Sunderland, Sunderland, U.K.
Keywords: Association Rules, Asthma, Data Mining, Spirometry Data.
Abstract: An application of association rules mining method for the discovery of associations in abnormal quantitative
health data for inadequately controlled severe allergic Asthma treated by Omazulimab is presented. To the
best of authors’ knowledge, no formal approaches have ever been used for extraction of association rules
among dysfunctional elements in Spirometry datasets. Initially is provided an explanation of the procedures
used for diagnosing inadequately controlled severe allergic Asthma. Following this, it is conducted critical
evaluation of well-known ‘association rule’ mining techniques, in order to identify the one with the best
utility for discovery of associations among abnormal elements of Spirometry datasets. Apriori Algorithm is
applied to real-life Spirometry datasets to illustrate the contribution of application of association rule mining
techniques. This revealed the existence of association rules among dysfunctional Spirometry elements for
this disease. Moreover it has been identified that this disease is provoked by association of Spirometry
elements that do not function properly as these are provided by Spirometer. This is translated in human
factors as a dysfunction of small and medium airways of patients’. Furthermore Spirometry element FEV1,
is not as valuable parameter as the European Medical Agency supports. Finally it has been observed that
Omazulimab treatment improves respiratory function and makes the connection among associated elements
weaker.
1 INTRODUCTION
Asthma is a disease that affects a large portion of
global population. Although asthma is separated into
different categories according to its severity, with
the most dangerous type being ‘poorly controlled
severe allergic Asthma’. This type of Asthma may
have mortal effects if not treated, or if patients do
not get the proper treatment in time, which occurs
only after hospitalization (Bousquet et al, 2007).
Immunoglobulin E (IgE) is a responsible factor
for severe allergic Asthma. During the last decade a
treatment has been discovered, called Omazulimab,
which is able to stabilize IgE. The appropriate
dosage is calculated by a practitioner and its use
leads to the reduction of exacerbations and
hospitalization (Nowak, 2006). Furthermore this
treatment can improve the patients’ Quality of Life
and reduce the risk of effects caused by Asthma
(Nowak, 2006).
The difference between inadequately controlled
severe allergic Asthma with other types of Asthma is
its severity. It has plenty of exacerbations and it is
not treated with the same medication as other types
of Asthma. The use of Inhaled Corticosteroids (ICS)
and Long-Acting-b2-Agonistics (LABAs) are not
effective on this type of Asthma. It has to be treated
with Omazulimab which has the ability to reduce
high number of free-IgE that patients suffer from
(Tzortzaki et al, 2012).
For an individual to be evaluated by a
practitioner as a patient who requires treatment with
Omalizumab, there are minimum medical
requirements that have to be met. These will be
discussed below. An important requirement that has
to be fulfilled is an abnormal FEV1 value (air
exhaled in the first second) (Tzortzaki et al, 2012).
Spirometry is a significant examination for the
measurement of lung function. It is used to measure
patients’ respiratory health and is helpful in
assessing conditions such as Chronic Obstructive
Pulmonary Disease and Asthma (Stout et al, 2012).
Spirometry provides an outcome which consists
of several numerical parameters. Each parameter
represents functionality of a different part of the
human respiratory. Also this examination is used to
276
Matsopoulos S. and Plekhanova V..
Connections of Reduced Performance Health Data for Severe Persistent Uncontrolled Allergic Asthma Treated by Omazulimab.
DOI: 10.5220/0004763802760286
In Proceedings of the International Conference on Health Informatics (HEALTHINF-2014), pages 276-286
ISBN: 978-989-758-010-9
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
measure response to treatment of conditions which
Spirometry detects (Stout et al, 2012).
In general results above 80% predicted,
according to the ideal, are considered normal, while
results under 80% are considered abnormal and will
be discussed below.
Spirometry data are collected and used for the
discovery of associations of abnormal Spirometry
results/values. This paper is based on the analysis of
data through Data Mining Techniques. These
techniques require quantitative-numerical data for
concluding to a result. These are given by
Spirometry examinations, which are the only
examinations that provided quantitative data during
treatment. They are used for representation of
patients’ clinical image and after appropriate
analysis with ‘data mining’ techniques will lead to
associations of abnormal Spirometry parameters
(Nowak, 2006).
Except Spirometry data analysis, further analysis
of health examinations by practitioner has to be
taken into consideration when dealing with
inadequately controlled severe allergic Asthma. This
action leads to higher diagnostic accuracy. Forthwith
the problem will be approached and examined only
by a quantitative point of view and not overview of
all health examinations. The reason for approaching
this subject by a different point of view is because it
has been found that Omalizumab treatment is not
effective on all patients for unclear reasons (Slavin
et al, 2009). After appropriate management and
analysis of Spirometry data, this paper focuses on
‘hidden’ information which exists beneath
Spirometry examination results and cannot be
analysed in detail without an appropriate technique.
In order to understand the nature of the problem,
relevant information and techniques that are being
used in traditional diagnosis and treatment
procedures are required to be briefly introduced for
the disease.
The structure of this paper is as follows. In the
second section key aspects of severe allergic
Asthma, with poorly controlled symptoms are
analysed as are the methods used for diagnosing and
evaluating Spirometry results.
Moreover in the third section there is a critical
evaluation of data mining techniques. In the fourth
section characteristics of the sample and simulation
of the technique used are presented. Finally the last
section focuses on recommendations for appropriate
use of this technique.
The following research questions will be
addressed in this paper:
Research Question 1: Are there any ‘data
mining’ techniques that can find ‘association rules’
in Spirometry Data?
Research Question 2: Is there a ‘data mining’
technique that could be useful in the discovery of
associations among Spirometry parameters for
severe allergic Asthma inadequately controlled?
2 BACKGROUND
OF INFORMATION
MANAGEMENT IN ASTHMA
DISEASE: KEY ASPECTS
As defined by multiple authors Asthma is an
inflammatory disorder of the lung-function and its
airways. It involves multiple inflammatory cells and
the interaction of a big amount of different
mediators of the lungs (Holgate et al, 2009).
Asthma is divided into mild and moderate, that
will not be further analysed in this paper and severe
persistent allergic Asthma, with inadequately
controlled symptoms. (Korn et al, 2009).
2.1 Severe Allergic Asthma
Inadequately Controlled: Key
Aspects
Severe allergic Asthma with inadequately controlled
symptoms can be characterized by the presence of
IgE antibodies against allergens that are common
such as animal dander or house dust (Slavin et al,
2009).
This can lead to lack of oxygen and incorrect
lung function leading to hospitalisation or increased
risk of death. (Nowak, 2006). Furthermore there are
multiple exacerbations during a small period of time
that can decrease the patients’ Quality of Life.
The use of Omazulimab treatment, which
contains Anti-Immunoglobulin E (anti-IgE), is
useful for patients’ who suffer from this type of
Asthma (Tzortzaki et al, 2012).
Though it is unclear why the use of Omalizumab
is not effective on all patients (Slavin et al, 2009).
The relationship between clinical symptoms and free
IgE has not been studied adequately. Consequently it
is difficult to predict the characteristics of the
patients that will be positively affected by the
treatment (Holgate et al, 2009).
2.2 Minimum Medical Requirements to
Initiate Omazulimab Treatment
For an individual to be taken under consideration for
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277
Omazulimab treatment some minimum medical
requirements have to be met. Patients have to be
older than 12 years old and have a positive skin
prick test or have reactivity to a perennial
aeroallergen (Korn et al, 2009). Moreover lung
function and especially FEV1 has to be lower than
80% as supported by the European Medical Agency
(Korn et al, 2009). Additionally the number of
severe asthma exacerbations that individuals may
suffer from, no matter what amounts of ICS and
LABAs is being used, has to be observed. Finally
patients must have a treatable IgE over 30 IU/ml,
which is measured before treatment starts.
Nevertheless the most important factor is the
practitioners’ evaluation on the patients’ overall
health and their need for treatment.
2.3 Utility of Spirometry in Severe
Allergic Asthma Inadequately
Controlled
As discussed above, one of the minimum
requirements for receiving Omazulimab treatment is
maintaining a FEV1 percentage less than 80% of the
‘normal’ measurement. ‘Normal’ is calculated by a
Spirometer based on age, gender, height and weight
(Stout et al, 2012). Every 2 to 4 weeks, depending
on patient’s dosage a Spirometry examination is
performed (Holgate et al, 2009). With this
examination a practitioner will be able to evaluate
the patient’s improvement. Furthermore Spirometry
is a ‘mirror-indicator’ of a patients’ respiratory
function and cannot be examined by any other
quantitative test (Stout et al, 2012).
2.4 Traditional Procedures on
Diagnosis of Improvement during
Treatment
Traditionally practitioners do not have a specific
technique which can be used for accurate
identification and evaluation of patients’ health.
Instead there is a procedure that has to be followed.
After evaluation and comparison of different
examinations a decision is made based only on the
practitioners’ opinion. There is no relevant technique
for an in-depth analysis of the examination results.
Forthwith, studies show that after a number of
exacerbations (Nowak, 2006) Spirometry
examination is the most important factor for the
evaluation of respiratory performance.
Due to the fact that IgE is examined only before
treatment starts, Spirometry is the only examination
that can reveal the patients’ lung function and
overall respiratory health (Bousquet et al, 2007).
Also based on previous research, (Tzortzaki et al,
2012) the only factors that are important and are
taken into consideration are Forced Vital Capacity
(FVC), Forced Expiratory Volume 1 (FEV1) and
Peak Expiratory Flow (PEF). However not all
authors take into account PEF measurements, for the
evaluation of patients’ respiratory function
(Tzortzaki et al, 2012). Although the research of this
paper will not only focus to only to these three
elements. Contrariwise in this paper PEF factor and
all factors that are provided by a Spirometry
examination will be considered.
A diagnosis is made by a practitioner and
improvement of respiratory performance is
evaluated. This occurs after a procedure that entails
the evaluation of a patients’ health, the number of
exacerbation and the percentage of FEV1 and FVC
according to the ‘normal’ measurement which is
provided by a spirometer.
Previous research has shown (Korn et al, 2009)
that secure and accurate measurement of results can
be assessed after at least 16 weeks of treatment. On
the other hand only 12 weeks of treatment can create
a secure overview of treatments’ outcomes (Slavin et
al, 2009).
2.5 The Proposed Scenario for
Examination of Spirometry
Elements
In this paper we consider the following scenario for
examination of Spirometry elements: each patient
has a number for Spirometry examinations taken on
different dates. Each Spirometry examination
consists of elements which measure parts of the
respiratory system. Elements such as FEV1
represent the percentage of function of different part
of human respiratory, according to the ‘ideal’
function that each individual should have. The
‘ideal’ is created based on each individual personal
characteristics, which will be analysed below. All
abnormal (parameters) elements, which will be
analysed below, will be added to the proposed
technique. After simulation of the technique to the
Spirometry data a combination of abnormal
elements (parameters) will be revealed.
This procedure approaches each patient
separately, as a different database. Each patient
provides an association of dysfunctional elements.
Following a statistical analysis is taking place which
leads to associations of abnormal Spirometry
elements that are met to most of patients. The
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following issues could be addressed: patients could
have different number of days for examinations;
different Spirometry elements but some could be the
same as in the previous examination days.
3 ASSOCIATION RULES
AND SPIROMETRY DATA
Quantitative data that are relevant to measurement of
Spirometry elements, are used for a consideration of
examination results. They are divided into before
and during a treatment period. The results are then
further analysed in order to make the final judgment
on the patients’ health improvement. This work
examines Spirometry data to find if there is an
association among Spirometry abnormal parameters.
Identified associations could be used for better
diagnosis and/or Asthma prediction.
This section presents well known techniques of
‘data mining’ which are used in analysis of
associations from the perspective of application to
Spirometry data. ‘Association analysis’ is used for
discovering interesting or uncovered relationships
hidden in data sets. ‘Association rules’ are used for
data of multiple nature/types and each one of them
has different criteria for significance of outcomes
(Lee et al, 2005), (Guang-Yuana et al, 2011).
Let us define the following key aspects: let I =
{i
1
,i
2
, i
3
,…, i
n
} be the set of all Spirometry elements,
e.g. Forced Expiratory Flow when 50% and 25% of
total air are blown (MEF 50, MEF 25 respectively),
Forced Expiratory Flow between 25 percent and 75
percent of the Vital Capacity (MMEF 75/25), FEV1
(i.e. items) in a Spirometry dataset for one patient
during examination period of time and T = { t
1
, t
2
,
t
3
,…, t
m
} be the set of examination results relevant
to Spirometry data elements for one patient (i.e.
“transactions”). Each Spirometry examination ti
contains a subset of k-items (i.e. a k- itemset) chosen
from I.
We are interested in associations of abnormal
Spirometry elements and we seek to find association
rules that define an implication A → B, where A is
MEF 50 and B is MEF 25. A and B are disjoint
itemsets, i.e., A∩B=Ø.
The strength of an ‘association rule’ can be
measured in terms of its ‘support’ and ‘confidence’.
‘Support’ determines how often a rule is applicable
to a given i.e., patient Spirometry dataset, while
‘confidence’ determines how frequently items in B
appear in Spirometry dates that contain A. A
‘support’ measure in Spirometry data identifies rules
that have very low occurrence on examination
results. For this reason, ‘support’ can be used to
eliminate uninteresting rules in Spirometry data. On
the other hand ‘confidence’ can be defined as the
probability of element/item A to be found at the
same time in combination with element/item B,
where A and B are Spirometry elements such as
MEF 50 and MEF 25 respectively. Both ‘support’
and ‘confidence’ measures have to be equal or
bigger than the one that ‘user’ has specified as
minimum. Otherwise items and combinations of
them are not taken into account (Lee et al, 2005).
Furthermore ‘confidence’ measures the reliability of
the inference/implication made by a rule. For a given
‘association rule’, the higher the ‘confidence’, the
more likely it is for an elements/items such as
Spirometry elements to be present in a patient
Spirometry dataset, that contains elements such as
MEF 50 and MEF 25. That is how, ‘confidence’
determines how frequently items in
transactions/Spirometry dates, appear in a patient
Spirometry dataset that contains dysfunctional
elements.
Subsequently, three ‘association rules’
techniques are further analysed. The reason for this
selection is because they are the most well-known
and used ‘association rules’ techniques (Cokpinar
and Gundem, 2012). These are: Apriori Algorithm,
Frequent Pattern (FP) Growth and Sampling
algorithm. Each one has advantages and
disadvantages, which are further discussed, although
it is highly important to adopt the nature/type of
Spirometry data and the nature of the problem for
the production of a significant outcome.
3.1 Apriori Algorithm
Apriori Algorithm is a procedure that scans the
frequent Itemset of Spirometry data to reveal
associations that satisfy minimum ‘support’.
Consequently this algorithm generates new
Candidates and re-scans the initial database to find
more associations among elements/items at one at a
time/scan (Yu et al, 2010). Finally it terminates
when no more associations/combinations can be
found among elements. For example it checks only
for element A if it satisfies minimum ‘support’ then
for B, C and so on. In its second scan it examines for
elements that have passed minimum ‘support’ in the
first step only. It generate combinations of A and B,
A and C and it continues for all elements of the
sample, where A, B and C are elements such as
MEF 50, MEF 25 and MMEF 75/25 respectively. In
a new candidate combinations of two elements that
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279
satisfy minimum ‘support’ are stored. In its next
scan it searches for combinations of 3 elements and
stores them again. This procedure continues until no
more combinations of abnormal elements that satisfy
minimum ‘support’ can be found. Consequently all
Itemsets that do not satisfy minimum ‘confidence’
are abandoned. Its final outcome is a set of
combined Items that fulfil minimum requirements.
One of its great advantages is that it has great
attention to detail and increases accuracy
accordingly to sample size. Improved accuracy can
be achieved to bigger samples. (Ykhlef, 2011).
One of the drawbacks of the Apriori Algorithm
that has been observed by researchers is (Umarani
and Punithavalli, 2011) the need of an entire Dataset
scan for each item added on the Itemset. This results
in slow implementation and high execution time.
Moreover because of its delay more electricity is
needed and because of technical equipment such as
Computers and storage space there is an increase of
cost (Liu et al, 2012). Another problem that is
encountered is the need for additional storage space
and this is due to the creation of new Itemsets.
Storing is significantly important for future analysis
and evaluation through Apriori. As a result,
acquisition of technical equipment (Computer,
Storage space) will lead to an additional cost and
may be unaffordable. A basic influential factor is the
size of the Itemset that is used for analysis (Nahar et
al, 2012). This problem is also encountered if there
is a small ‘support’, set by the ‘user’, which will
lead to the creation of multiple new Itemsets
(Umarani and Punithavalli, 2011). Consequently, the
smaller the sample the faster and cheaper the
implementation will be.
3.2 Frequent Pattern Growth
Algorithm
In Frequent Pattern Growth Algorithm the procedure
to solve the problem is divided into two steps
(Umarani and Punithavalli, 2011). In the first step
the database is scanned only once and an FP-tree is
created. In each branch of FP-tree Items
/Spirometry elements from dataset/Spirometry
examination results from the dataset are added and
stored by their names. In every new element a new
sub-branch is created and stored with a Transaction
ID (TiD). A unique ‘path’ of each transaction is also
created. The size of FP-tree is at least as a big as the
original Database.
In the second step it recursively mines all the
patterns from the FP-tree that was built in the first
step and concludes on the result. It follows the
prefixed path based on a specific search e.g. path
that contains a specific element as FEV1 does. This
leads to results that satisfy ‘support’ by exclusion of
TiD that do not satisfy ‘support’ and ‘confidence’.
The creation of smaller structures (FP-tree), if
not the same size as the entire database, is analysed
(Chen et al, 2011) is one of the advantages of FP-
Growth Algorithm. Also it creates a methodology
that does not demand the creation of multiple
Candidate Itemsets. Finally it reduces the search
space that is needed because of its methodology.
Therefore only two patterns of development are
needed, with smaller execution time (Lin et al,
2011). This results in faster analysis of Spirometry
examination of patients who have large amount of
examinations.
One of its drawbacks is that it needs the same
amount of storage and memory capacity as Apriori
does (Liu et al, 2012). It also has high cost because
of high demand of technical equipment (Computer,
Storage space, Electricity). Moreover there are
crossing authors opinions about Aprioris’
implementation speed (Ke et al, 2013), (Umarani
and Punithavalli, 2011). Meanwhile it has high
efficiency; its complexity in each step (Duneja and
Sachan, 2012) results in the presence of a great
barrier for individuals/practitioners who lack the
experience in modelling aspects; to calculate
findings and execute proper analysis of data.
Finally every new Spirometry dataset of each
patient is added to the previous database. Some
patients may have thousands of Spirometry
examinations which could lead to a massive
Database. As it has been discussed, FP-growth is
based on the development of a FP-tree. This leads to
bigger samples which have reduced mining
performance (Lin et al, 2011). Thereafter there are
some patients with a lot of Spirometry datasets.
Lower mining performance which can lead to lower
significance of results is not desirable for nature of
Spirometry Data and Health research that needs high
accuracy.
3.3 Sampling Algorithm
Sampling algorithm does not have a specific
structure as Apriori and FP-growth algorithms do.
Instead it is based on a different algorithm, it is
based on the nature of Data. By appropriate
algorithm it generates an accurate sample size for
implementation initially. It provides an outcome
significance and accuracy of sample size. If it is not
appropriate it is modified and repeats this step. After
identification of appropriate sample size, the final
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280
outcome is provided. Analysis of the sample takes
place by other Association Rules techniques such as
Apriori or FP Growth Algorithm (Chen et al, 2011).
As is revealed by its name it uses a sample of the
entire database and analyses it (Umarani and
Punithavalli, 2010).
Its methodology is divided into a number of steps
that are depended on the algorithms that will be used
for implementation.
Initially the selection of the sample takes place
during step one (Umarani and Punithavalli, 2010).
The selection of the sample that leads to accurate
results differs in each type of data. The most
efficient technique can be revealed only after its
implementation. A random selection from the
database can be found if it satisfies ‘support’ by
implementing it by giving a slightly lower minimum
‘support’ than the one that the ‘user’ specified (Chen
et al, 2011). If it is not satisfied then more Data are
being added to the sample and the sampling
technique is re-implemented. The procedure
terminates when the sample satisfies minimum
‘support’ of the ‘user’.
Consequently the sample is analysed by an
‘association rule’, like Apriori or FP-growth and
results are provided after implementation (Ackan et
al, 2008).
Advantages that have been identified are the
decreased use of storage space, the low cost because
of the lower demand of technical equipment
(computer, storage space). Moreover it is
implemented faster than the total analysis of the
database because less Data have to be analysed
(Umarani and Punithavalli, 2010).
Each algorithm has particular strengths and
weaknesses, relevant to the nature/type of data that
are being used. The same rule applies for the
Sampling Algorithm on Spirometry data. Although
the Sampling algorithm has disadvantages on its
own thus the possibility of data that the sample is
consisted to be similar. This could result in faulty
outcomes of the analysis. Moreover quality and
accuracy of outcome depends on the database size.
Databases of bigger size have higher accuracy and
better quality than smaller ones. This is not
appropriate and effective on nature/type of
Spirometry data because some patients have plenty
of examinations and others have few.
3.4 Critical Comparison of Techniques
in Relation to Data Needs
Apriori and FP-Growth have high efficiency, quality
of outcome and pay attention to detail. These
advantages do not apply to the Sampling algorithm.
On the other hand they have high cost and long
implementation time, which can lead to delayed
results.
For an outcome of high significance medical data
need to have accuracy of results. As a result, the
most important factor for the selection of the most
appropriate algorithm is based on its accuracy,
quality and attention to detail of the data. Each
sample method needs to be implemented in order to
find the most suitable for Spirometry type of data.
Based on these requirements, Sampling Algorithm is
excluded because it lacks of these requirements.
Moreover, the need for mathematical and data
analytical knowledge for implementing the sample
algorithm process, are additional reasons for not
selecting this algorithm for the analysis of this type
of data.
Likewise FP-growth will not be selected for
analysis of Spirometry data because of its high
complexity during implementation. Furthermore
exceptional mathematical and ‘data mining’
knowledge is required by the ‘user’. Also it has
similar cost as Apriori.
Concluding based on the above comparisons, the
best suited algorithm that will be used for analysis of
our Data is the Apriori algorithm. The reason for this
decision is that it fulfils limitations such as accuracy
and quality of outcome in better significance than
the FP Growth and Sampling algorithm. Moreover
the ability to analyse big Datasets, based on size, it
affects positively the outcome (Amato et al, 2011).
The larger the sample the more accurate the
outcome. Also it is important to the ‘user’ because
multiple stored data (Transactions) from previous
years are needed for analysis. So as time passes, the
sample becomes bigger. Furthermore it can be
adopted by Spirometry Data with no limitations.
The Apriori algorithm is used as a guide for
finding associations among elements of Spirometry
data that are dysfunctional/abnormal (<80%) such as
MEF 50 and MEF 25. Additionally ‘support’
measure helps to prune candidate Itemsets
discovered during frequent Itemset generation on
Spirometry dates/transactions.
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4 APPLICATION OF APRIORI
ALGORITHM TO REAL-LIFE
SPIROMETRY DATA SAMPLE
4.1 Sample Characteristics of Patients
All Data were collected from the General Hospital
of Ioannina ‘Hatzikosta’ in Greece. The sample that
was chosen for analysis consists of 20 patients; 13 of
which are women and 7 are men. All patients’ are
residents in the region of Epirus and are under
treatment with Omazulimab in the General Hospital
‘Hatzikosta’. This sample of 20 patients is consisted
by 559 Spirometry examinations that were taken for
analysis; 12 of which (2, 14% of total sample) have
not been taken into consideration for analysis due to
the lack of total Spirometry elements indications.
This was caused by mechanic failure of the
Spirometer. Moreover examinations before the 12
th
week of treatment are not being taken into
consideration as explained below (10, 7% of total
sample). Furthermore each patient had a different
number of examinations. The average number of
examinations per patients is almost 28 (27, 9 is the
exact number) with the minimum number of
examinations being 9 per patient and maximum
being 60 per patient.
Moreover the average IgE level of our sample is
535, 65 with lowest being 140 and the highest 1476.
Also the average age of our patients was 64 (63, 8)
with youngest being 48 years of age and oldest being
78. Finally the average treatment period of sample
was almost 21 months (21, 15 is the exact number)
with shortest being 7 and longest period being 40
months per patient. Although averages have been
computed for the total sample, a portion of our
patients (10 out of 20) are still under treatment and
others have completed the treatment. Finally the
examinations that have been collected are from July
of 2001 until July of 2012. Finally 10 out of 20
patients have completed the Omazulimab treatment.
So ‘after treatment’ period examinations were not
further analysed for higher significance of results.
4.2 Process Followed for Analysis of
Spirometry Data based on Study
and Disease’s Requirements
Data were collected from 20 patients in three
periods: Spirometry examination before
Omazulimab’s treatment, after 12 weeks of
treatment and after treatments’ completion. The first
period consists of Spirometry examinations that
have been taken before Omazulimab’s treatment, 31,
3% of the sample (175 out of 559) as shown in Table
1. The percentage of each element, on each patient
who has not proper function is presented.
The second period is composed by Spirometry
examinations taken after 12 weeks of treatment until
the completion of the treatment and represents 51,
8% of total sample. The effectiveness of
Omazulimab is visible and proves the previous
researches (Slavin et al, 2009). In the second table it
is presented ‘during treatment’ period and shows the
percentage of examinations that each Spirometry
element is abnormal (>80%).
The last period consists of Spirometry
examinations taken after the treatments’ completion.
Although this period is not taken into consideration
for analysis due to lack of examinations, as only
50% of the sample (10 out of 20 patients) has
completed the treatment. Something that is
translated to 6, 08 % of total sample examinations
(34 out of 559).
Each element given by Spirometry as healthy
and functional has to have at least 80% function
performance for the ‘ideal’ measurement (National
Heart Lung, and Blood Institute, 2007). This is given
for each element separately by the Spirometer. Only
elements that fulfilled this requirement were taken
into consideration. The identification of associations
among elements that are not fully functional and are
responsible for this disease is being researched.
Information about each patient is presented by a
dataset, from where associations of elements
occurred after analysis of Spirometry examinations.
Each date of a Spirometry examination was set as a
Transaction and elements in it were set as Items.
Below 80% were taken into consideration (set as 1)
and above 80% were not (set as 0). Following this
allocation each patients’ Spirometry examinations
(dataset) have been imported and analyzed with
Apriori. The process that has been followed is
briefly described in section 3.1. After this analysis
combination of abnormal Spirometry parameters for
each patient has been discovered. Each patient has
been analysed twice as different Datasets for before
and during treatment period were used.
The provided technique has only been used as an
additional technique for practitioner to make more
accurate diagnose and evaluation patients’ health on
top of other Medical findings.
‘Support’ measurement has been set to 66, 6%
for having significance of result, as abnormal
elements have to be more of a half times in
examinations sample. Additionally ‘confidence’
measurement has been set to 100% because the
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Table 1: ‘Before’ treatment period.
Patients
Number
VC
IN
VC
EX
FEV
1
FVC
FEV 1 %
VC MAX
MEF
75
MEF
50
MEF
25
PEF
MMEF
75/25
FVC
IN
Out
of
1 22.72 22.72 63.63 9.09 22.72 14 100 100 22.72 100 22.72 22
2 0 0 0 0 0 0 100 100 0 100 0 2
3 4.76 38.09 28.57 28.57 4.76 66.66 100 85.71 57.14 100 0 21
4 37.5 37.5 37.5 37.5 12.5 50 75 100 25 75 37.5 8
5 50 50 50 50 25 50 75 100 50 75 50 4
6 78.94 94.73 100 94.73 31.57 100 100 100 100 100 78.94 19
7 12.5 0 0 0 0 50 100 100 25 100 12.5 8
8 50 0 100 0 0 50 100 100 50 100 50 2
9 0 0 0 0 0 0 100 100 0 100 0 1
10 0 0 33.33 0 0 33.33 100 100 0 100 0 3
11 38.46 30.76 38.46 26.92 19.23 65.38 61.53 80.76 42.3 69.23 38.46 26
12 0 0 0 0 0 0 100 100 0 100 0 1
13 0 0 0 0 0 77.77 66.66 55.55 66.66 66.66 11.11 9
14 50 50 50 50 0 100 100 100 100 100 25 4
15 50 50 50 25 0 25 50 50 0 75 50 4
16 5 5 5 0 0 30 80 70 15 85 5 20
17 100 100 100 100 100 0 100 100 100 100 100 3
18 66.66 33.33 33.33 33.33 0 33.33 66.66 100 33.33 66.66 66.66 3
19 100 100 100 100 40 100 100 100 100 100 100 5
20 10 20 10 20 0 80 100 100 70 100 10 10
Table 2: ‘During’ treatment period.
Patient
Number
VC
IN
VC
EX FEV1 FVC
FEV1 %
VC MAX
MEF
75
MEF
50
MEF
25 PEF
MMEF
75/25
FVC
IN
Out
of
1 10 20 30 0 0 50 100 100 30 100 20 10
2 0 0 0 0 5 15 70 100 0 90 5 20
3 0 20 20 20 0 40 100 100 60 100 0 5
4 100 100 100 100 9.09 100 100 100 27.27 100 100 11
5 14.29 14.29 14.29 14.29 0 14.29 100 100 14.29 100 14.29 7
6 100 100 100 100 0 100 100 100 100 100 100 6
7 0 0 0 0 0 0 100 100 0 100 0 1
8 54.17 54.17 87.50 45.83 0 66.67 100 100 8.33 100 54.17 24
9 23.53 0 0 0 0 0 23.53 88.24 0 58.82 23.53 17
10 6.25 3.1 9.38 3.13 0 21.88 46.88 96.88 18.75 71.88 12.5 32
11 0 0 5.56 0 0 38.89 77.78 88.89 0 88.89 0 18
12 0 0 0 0 0 100 100 100 0 100 0 5
13 0 0 0 0 0 100 100 100 83.33 100 0 6
14 0 31.,03 27.59 13.79 0 100 100 100 93.10 100 10.34 29
15 0 0 0 0 0 0 0 100 0 0 0 4
16 0 2.78 0 0 0 44.44 94.44 100 33.33 97.22 0 36
17 100 100 100 100 0 100 100 100 100 100 81.82 11
18 37.5 31.25 50 25.00 0 93.75 100 100 0 100 43.75 16
19 86.67 100 100 86.67 86.67 100 100 100 100 100 86.67 15
20 5.88 0 5.88 0 0 70.59 100 100 29.41 100 5.88 17
ConnectionsofReducedPerformanceHealthDataforSeverePersistentUncontrolledAllergicAsthmaTreatedby
Omazulimab
283
nature of data demands high accuracy.
Although 20 associations occurred (one of each
patient/Dataset) only patients that met minimum
‘support’ and ‘confidence’ measurement criteria
were statistically evaluated. And separately for each
period which led to associations of Spirometry
elements that are mostly met among patients.
Patients that failed to meet the required minimum
criteria were not considered in the process of
statistical analysis for achieving improved accuracy
and significance of final results.
Finally a comparison of associations/
combinations, before and during treatment periods
has been made. This led to an outcome which
revealed the amount of associations of ‘before
treatment’ period that have been healed by the use of
Omazulimab in ‘during treatment’ period.
4.3 Discussion of Results from Patients’
Spirometry Data Analysis
It has been found that in ‘before’ treatment period
there were three patients who although satisfied the
‘support’ indicator through the full process of
analysis, the association of Spirometry
parameters/elements did not fulfil ‘confidence’
indicator. This resulted in the exclusion from the
second step of analysis which is the Statistical
analysis of the sample. Also one patient had only
one element that fulfilled ‘support’ indicator. This
concluded to an end of his/her analysis because there
were no associations to be found. Additionally the
patient has also been excluded from second step of
analysis.
An association of elements that has been found
to 50% (8 out of 16) of sample that satisfied
‘support’ and ‘confidence’ with no other elements
on it, is consisted by the elements MEF 50, MEF 25
and MMEF 75/25. From which 75% (6 out of 8) had
100% Support. Also this combination has been
found in associations with other elements to 93, 75%
(15 out of 16) of sample. Also it has satisfied
Support and Confidence limitations.
In ‘during’ treatment period two patients had
only one element that fulfilled ‘support’ indicator.
This concluded to end of analysis because there
were no associations to be examined. Also they were
excluded from second step of Statistical analysis.
The same association/combination of elements
has been found in ‘before’ and in ‘during’ treatment
period. It is consisted by MEF 50, MEF 25 and
MMEF 75/25 has been found to 44, 45% (8 out of
18) of sample. It also satisfies ‘support’ and
‘confidence’ limitation. Although it has been found
at the same height as ‘before’ treatment period 37,
5% (3 out of 8) of patients are different. Furthermore
it has been found that associations that have 100%
‘support’ have been reduced to 62, 5% (5 out of 8).
Furthermore this combination is met in associations
with other elements to 94, 44% (17 out of 18) of
sample that satisfied ‘support’ and ‘confidence’.
Another significant finding that has been
revealed from this work is the importance of FEV1
for diagnosis of this disease. It has been revealed
that although FEV1 is an element that is a
prerequisite medical requirement for beginning of
treatment, as also a significant measurement for
evaluation of it, it is not as dysfunctional as it had
been initially supported. The reason of this outcome
is because it has not fulfilled ‘support’ indicator to
most of patients neither ‘before’ nor ‘during’
treatment period. Although it has been met to 25%
(4 out of 16) of associations on ‘before’ treatment
period and in 22, 22% (4 out of 18) to ‘during’
treatment period, it has not significant appearance. It
was expected to be found to all datasets and to be
highly significant as it is one of the minimum
Medical requirements to begin Omazulimab
treatment according to European Medical Agency
(Tzortzaki et al, 2012)
Furthermore 100% ‘confidence’ had been
demanded because of Data nature. It has been
indicated by some factors that there is a possibility
for some Spirometry elements/parameters with
lower than 100% ‘confidence’ to fulfil needs of
analysis. It has been found to some elements and
there is high possibility to indicate individuals that
suffer from severe allergic Asthma inadequately
controlled and it is not reducing significance of
finding.
4.4 Critical Evaluation of the
Outcomes
After implementation of Apriori Algorithm and
analysis of sample, we identified an association of
elements. It is the same in ‘before’ and ‘during’
treatment period. The association that is mostly on
both periods is consisted by MEF 50, MEF 25 and
MMEF 75/25 elements. Importance of results is
being provided in more detail in section 3, where
‘Support’ and ‘Confidence’ measures are discussed
in the context of their application to Spirometry data.
The meaning of this finding in health value is that
when a patient has low flow speed of air moving out
of his lungs at the time of 50% of FVC is blown it
has also low flow of air blown when 25% of FVC is
blown and his/her small and medium airways are not
HEALTHINF2014-InternationalConferenceonHealthInformatics
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as functional as they had to be based on the ‘ideal’.
Patients who fulfil other medical requirements
are indicated by this association of elements as
patients who require treatment with Omazulimab.
The reason is that they suffer or will suffer in future
by severe allergic Asthma inadequately controlled.
It has been found the same association of
elements to both periods and revealed that treatment
has a positive effect on this association of elements.
Level of dependence among these elements became
weaker. Elements are not that close correlated after
12 weeks of treatment or more. Furthermore it has
been proved that treatment has positive reaction
except medical view point also by Spirometry Data
point of view.
Encounter to less than 25% of sample, on both
periods, of FEV1 has reduced its utility as a
minimum medical requirement for start of
Omazulimab treatment.
Furthermore associations of elements that
provoke severe allergic Asthma inadequately
controlled are MEF50, MEF25 and MMEF75/25.
This association/combination of Spirometry
elements it has been found as a ‘stand-alone’
combination. Although it has been met in
associations with other elements in both ‘before’ and
‘during’ treatment periods.
In addition it has been revealed that Omazulimab
treatment has positive reaction upon this association
as it makes it weaker. Furthermore ‘confidence’ of
100% there is a possibility to be lower to some
Spirometry elements. Although this does not affect
significance and utility of the result. Finally it has
been revealed that FEV1 element has lower
significance on disease recognition as also to
evaluation of it as it has been concerned by authors
in previous section.
5 RECOMMENDATIONS
Initially it has to be clearly understood that the
proposed technique is only to be used as an add-on
tool for better evaluation of health. Even though it
produces an outcome of associations that can
forecast and evaluate patient’s health, other health
examinations have to be taken under consideration.
Additionally the final decision for patient’s health
and treatment must be taken after practitioner’s
overall evaluation. This occurs after combination of
multiple examinations needed as also requirements
that have to be filled.
Through this research both the research questions
that have been set for investigation have been
answered positively. It has been proved that there
are data mining techniques that can find ‘association
rules’ in Spirometry datasets. Moreover it has been
investigated and proved that Apriori algorithm could
be used as most appropriate ‘data mining’ technique
to discover associations among abnormal Spirometry
data. Detailed discussion on how and why this
algorithm is the most suitable for this type of data
are provided in section 3.
Additionally the proposed tool examines and
evaluates patient’s health from Data perspective.
There have to be as many as possible Spirometry
examinations for increased accuracy. A reason for
this is because the algorithms’ process takes into
consideration from 2 to millions of examinations for
analysis. Moreover as it has been discussed
respiratory health is affected by multiple factors
such as weather, daytime, age, weight, etc. With a
small amount of Data the significance may be
reduced but this instance can be overcome by
techniques for small data samples such as Kernel’s
methods and Support Vector Machine (SVM).
Additionally in regular periods, when a
significant amount of Spirometry examinations are
gathered, process of comparison of Data from
different patients has to be carried out. This is
because factors such as climate, global temperature
and multiple factors that affect respiratory and
cannot be measured, change. This could result in
change of associations that provoke severe allergic
hardly controlled Asthma. For avoidance of radical
changes in the association found it has to be checked
in regular periods.
Furthermore because of different environmental
characteristics around globe, technique may have to
be undertaken to samples from different places of
the world. This is for avoiding misleading guidance
from technique caused on environmental changes.
These and some other aspects could be taken into
account and addressed in future work.
Even though this subject it has been approached
by a specific perspective it has been revealed that it
is ‘open’ to be adopted and analysed by different
perspectives.
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