Healthcare intelligence risk detection systems

doi:10.4236/ojpm.2013.38062

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Vol.3, No.8, 461-469 (2013) Open Journal of Preventiv e Me dic ine

http://dx.doi.org/10.4236/ojpm.2013.38062

Healthcare intelligence risk detection systems*

Reza Safdari, Jebraeil Farzi#, Marjan Ghazisaeidi, Mahboobeh Mirzaee, Azadeh Goodini

Department of Health Information Management, School of Allied Medical Sciences, Tehran University of Medical Sciences, Tehran,

Iran; #Corresponding author: j-farzi@razi.tums.ac.ir

Received 21 August 2013; revised 28 September 2013; accepted 8 October 2013

which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

ABSTRACT

Background: Today, in healthcare field that is

changing rapidly, decision-makers encounter

with ever-increasing inquiries on clinical and ad-

ministrative information to realize customers’ le-

gal and clinical requirements. Therefore, making

decisions on healthcare has changed into a vital,

complex and unstructured issue. The present

paper mainly focuses on describing decision-

making advantages, possible risk to improve ef-

ficiency of decision-making on healthcare, and

especially medical procedures. Methods: The

present research is a review study, which has

been carried out by searching through the au-

thentic scientific sources, including Pubmed,

Google scholar, Iranmedex, and other informa-

tion sources. While defining care intelligence,

here, we introduce Knowledge Discovery Data-

base, the Clinical Support Systems, and Intelli-

gence Risk Detection Model and provide the

conceptual model. Other issues studied in this

paper include the Risk Possibility Assessment

T echnique, Risk Possibility Detection using know-

ledge management techniques, and expert sys-

tems. Result s & Conclusion: Modeling the Intelli-

gence Support System is necessary for design-

ing Real-Time Risk Detection Information Sys-

tems in clinical measures. As taking medical

procedures involves complex decision-makings

and possibility of high risk, operational applica-

tion of the techniques derived from knowledge

and data mining models under study will play a

crucial role in increasing possibility of success

of the measure and pro moti ng safe ty of patients .

Keywords: Risk Detect ion Sy stems; Decisi on

Support; Healthcare Intelligence

1. INTRODUCTION

An effective decision is vital in all healthcare activities.

However, decision-making in this field is complex and

unstructured; therefore, it is necessary for a decision

maker to collect multi-spectral data and information to

make an effective decision at the time he/she confronts

with multiple options. Unstructured decision-making in

complex and dynamic atmospheres is a challenging issue

and a decision maker encounters with low-level informa-

tion almost in every situation [1]. Needs for the pertinent

knowledge, useful data and information are crucial and

in fact, knowledge controlling values, tools acceptance,

and knowledge management methods, technologies and

tactics are essential to guarantee the efficiency and ade-

quacy of decision-making process [2]. By recognizing

this issue, Wickremesinghe and Schaffer [1] developed

Intelligence Continuum. It is a regular method to enable

application of principles and tools of KM, which is nec-

essary for improving decision-making on healthcare,

being confident of the favorability of the results obtained

from the decision-making, and maximizing its advantage

for patients. Therefore, this idea was developed in the

present paper and specially focused on medical proce-

dures; this is a field which is not only remarkable, but

also requires several risks and vital decision-making

processes and in fact it is a suitable atmosphere to de-

scribe advantages of this method. This paper focuses on

the way the Intelligence Risk Detection Model affects in

real-time and appropriately on healthcare support systems.

2. METHODS

The present research is a review study, which has been

carried out by searching the Health, Intelligence Risk

Detection and Systems keywords through the authentic

scientific sources, including Pubmed (13 Item without 11

unrelated works), Google scholar (4 Item without 3 un-

*Competing interests: The author(s) declare that they have no compet-

ing interests.

Authors’ contributions: RS, JF, MG, MM and AG contributed to

conception and design, analysis and interpretation of data, and drafting

and revising the manuscript. JF, MG, MM and AG acquisition of data.

All authors read and approved the final manuscript.

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469

462

related works), Iranmedex (3 Item), and other informa-

tion sources. While defining care intelligence, here, we

introduce Knowledge Discovery Database, the Clinical

Support Systems, and Intelligence Risk Detection Model

and provide the conceptual model. Other issues studied

in this paper include the Risk Possibility Assessment

Technique, Risk Possibility Detection using knowledge

management techniques, and expert systems.

3. BACKGROUND AND

RELATED WORKS

Before the conceptualize the model we must explain

the aspects of model and related works as HI, intelli-

gence tools, risk assessments and applied systems of

model.

3.1. HI

The concept of intelligence is very extensive. As this

concept entered the business fields, extensive concepts

have formed in this concern, including competitive intel-

ligence, care intelligence, business intelligence, and mar-

keting intelligence. A major part of the sources related to

intelligence is concentrated on industrial organizations

and they have not taken into consideration sufficiently in

the field of health; therefore, to have a better under-

standing, we discuss the differences and similarities be-

tween it and other fields [2,3] (Table 1).

Therefore, healthcare intelligence helps administrative

and clinical management to know the capabilities avail-

able in health network. It facilitates administrative and

clinical decision-making through combining all kinds of

measurement principles on different kinds of internal and

Table 1. Comparing characteristics of healthcare and other

fields.

Differences Similarities

Management is concentrated in

most fields; however, it has

various clinical and

administrative fields on

health department.

All departments require

improvement in charge, quality

and delay through integrated

processes.

Most departments have a certain group of customers with limited

varieties of products. Healthcare requires multiplicity of actors with

distinguished needs.

Following the success of “Focus on Customer Method” in other

fields, the focus in healthcare is mainly on patient; however, the

variety of customers of other departments is also mentioned.

Most industrial systems have

principles of precise

measurement. Feelings and

choices of individuals are also

taken into consideration

in healthcare.

Like other fields, healthcare takes

advantage of system

combination.

external actors, which is caused by a wide variety of

processes [1,3-5] (Figures 1 and 2).

3.2. Intelligence Tools

The intelligence tools are very wide and varied. These

tools, also called “computational intelligence”, include

the following techniques:

1) Expert Systems: “Expert Systems” were formed

since the mid-sixties and they have extensive applica-

tions in different fields of business today. Expert Sys-

tems are made of the following two main elements:

a) Theoretical Understanding of Issue

Collecting creative terms of problem solving are ob-

tained from experience. Deduction ability is the strong

point of an expert system and it is exactly the very factor,

which make an expert system intelligent. Deduction in-

cludes obtaining results of theorems.

Therefore, in order to make a deduction, there should

be a theorem and a result; the latter was achieved from

that theorem [5].

2) Artificial Neural Networks: Artificial Neural Net-

works were introduced since 1940s by Mcculloch and

Pitts. As these models were inspired by biology, artificial

neurons in the neural networks receive sum of data from

the rest of neurons or external stimuli. Here, artificial

neurons’ action is similar to the one of brain neurons.

Then, they transfer the modified data to the other neu-

rons or external outputs; this process is similar to human

brain function. Transfer of information from one neuron

to another neuron is a method for activation and/or reac-

tion to a specific neuronal response based on the data or

stimuli it receives [4].

3) Fuzzy Logic, Fuzzy Sets and Fuzzy Systems:

Fuzzy Sets are defined based on a membership function,

which is the image of a universal set in the range of [zero

and one]. Each element has a grade of membership. A

fuzzy set is made by generalization of classical sets the-

ory. In classical sets theory the membership of elements

in a set is assessed in binary terms. An element either

belongs or does not belong to a set. By contrast, fuzzy set

theory permits the gradual assessment of the membership

of elements in a set [6].

4) Rough Sets: This concept was introduced by Paw-

lak in 1982. Rough sets theory is based on estimation of

concepts (sets) using the available knowledge in an in-

formation system. Its application on lost values is con-

sidered as one of the strong points of this theory. Rough

sets theory calculates two sets of upper and lower ap-

proximations for processing incomplete data [5].

5) Evolutionary Algorithms: Evolutionary algorithm

is the algorithm, which is a subset of the evolutionary

calculation and is placed in the subdivision of artificial

intelligence. This algorithm uses different mechanisms,

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469

463

Figure 1. Processes of healthcare field [3,4].

OPEN A CCESS

Figure 2. Framework of technology in healthcare intelligence.

including production, leap, composition, and selection.

Selected solutions for optimization problems play the

role of components and, among these components and

people, cost function decides which solutions are re-

mained. These algorithms are frequently used in different

parts of control systems, design, scheduling, optimization,

data restoring, and management [5,7].

a) Combined Techniques: Most of the above tech-

niques can be combined with respect to terms of use to

achieve a new method; for instance, both fuzzy systems

and neural networks can be used simultaneously in

health business.

b) Data Mining, Web Mining: “Data Mining” is a term,

which is used to describe knowledge discovery from

databases. Data Mining is a process that uses statistical,

mathematical, artificial intelligence and machine learning

techniques to extract and identify useful information and

knowledge on large databases. According to the new

definition, “It is a process to find mathematical patterns

among large sets of data”. These patterns may include rules,

dependencies, procedures or models of anticipation [7].

Web Mining can also be defined as exploration and

analysis of the information of interest and useful infor-

mation on a web and about web, which is usually defined

by the web-based tools. The term “Web Mining” was

first used by Etzioni (1996) [6].

6) MAS: AOP is an approach in programming, the

importance of which is ever increasing and some know it

as a more developed form of the Object-Oriented Pro-

gramming. The agent is a software entity, which is

placed on a dynamic environment and is able to recog-

nize characteristics and conditions of the environment

and act autonomously (independently) to achieve a goal

[5].

3.3. Applied Systems of Model

In the following section, general topics about key

scopes of decision support systems, risk detection system,

expert system and their importance for designing risk

detection design is discussed to improve healthcare deci-

sion-making process.

3.3.1. Expert Systems

Expert systems (knowledge-based systems) are also

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469

464

known as Rule-based Systems. Analyses and programs of

these systems are based on If-Then. The algorithm de-

signed for expert systems is programmable and/or is de-

signed in the form of shells in which the rules and

knowledge should be created and executed. Expert sys-

tems protect knowledge, increase optimization, improve

quality of services and products, do activities in danger-

ous working environments, provide high reliability, dis-

tribute knowledge through its rapid transfer, and reduce

costs in an organization [5].

One of the knowledge-based systems is KDD which is

defined as an important recognition process for authentic,

new, and probably useful and understandable patterns in

data [8,9]. One of the most common applications of

KDD in the field of healthcare is IC. Intelligence Con-

tinuum includes application of data extraction methods,

BI and KM, so that offering favorable healthcare would

be easier in IC model [1].

3.3.2. DSS

Decision Support Systems is a subdivision of Opera-

tion Research, which were created due to the quantifica-

tion techniques of complex issues of management. DSS

includes OR application in supporting management deci-

sion-making processes [5].

Although some studies have been carried out about

DSS in the field of healthcare, DSS applications in clini-

cal and diagnosis activities became 10 times bigger dur-

ing recent decades [10]. Principally, the present research

encompasses the clinical and medical aspects and fo-

cuses on how to apply IT and improve decision-making

efficiency for physicians. Specifically, the computer-

based decision support systems merely focus on the

software designed for this purpose to help clinical deci-

sion-making, and features of patients are in accordance

with computer knowledge basis to carry out patient’s

specific assessment and/or recommendation to physi-

cians [11]. In addition, computer registration of patient’s

information, internet, common decision-making proc-

esses, and new rules facilitate medical decision-making

supporting systems [12]. Consequently, to conduct our

present research, sources containing CDSS and MDSS

are equally related and computer systems are used for

supporting decision-making of healthcare specialists.

Decision making about medical procedures for pa-

tients is considered as a complex and multilateral meas-

ure in most cases. Patients may have various symptoms;

however, this measure is mainly operational. Here, com-

plete anatomic restoration of an organ can be considered

as an example. If it is decided to carry out restoration

later, the risks and advantages of medical procedures in

proportion to the possible risks of taking no measure

should be weighed up. In addition, making a decision on

an alternative treatment using drugs or taking a measure

or a combination of both depend on several factors [1,2].

Decision-making process on medical procedure can be

divided into 3 steps. In the first step or the step prior to

taking measure, a physician acquires sufficient informa-

tion about a patient and his/her medical conditions and

decides whether such a measure is the best option as far

as his profession is concerned or not. When the decision

is made and prior to taking a measure, the patient should

decide on the acceptance and rejection of the physician’s

decision with respect to the anticipated results. When the

patients and physicians are in accord, in step two, the

decision-makings on the unique situations are considered

during a measure. Finally, in the step after medical

measure or step 3, decision are mainly made at two lev-

els: the first level, the strategies for guaranteeing suc-

cessful result for a patient during post-care period and

step b, the lessons that should be applied for future cases.

In order to overcome this complexity, we define two

steps of decision-making within three different and key

processes of decision-making on performing the clinical

measures. The first type of decision-making is called

medical decision-making, which is mainly related to

physician. The second type of decision-making is called

personal decision-making, which is mainly related to

patients because some of the results of a medical proce-

dure are related to the quality of life of patients in which

the patient’s decision-making is vital.

Although, DSS is usually discussed well in healthcare

field, unfortunately, acceptance of these solutions is at a

low level due to unwillingness of physicians to use

computer systems for these purposes [13]. Special atten-

tion should be paid to the guarantee of clinical applica-

tion of the pertinent approach. Real-time risk detection

system is probably useful and suitable and, in turn, its

application and acceptance are reinforced.

3.3.3. Intelligence Risk Detection Framework

in Healthcare

A physician’s performance is usually assessed indi-

rectly, using care results in a hospital, relevant tools, and

probability of risk. Although determination of risk prob-

ability is important for assessing performance and com-

paring results for people or organizations, today, the

present methods pay attention to more extended field of

care. This seems to be rather misleading and physician’s

performance is assessed after a procedure and usually 30

days after the procedure. The weak results may be due to

technical errors, nurses’ errors, drug’s errors and/or care

and the supervision lower than the standard level [14].

With respect to the study of resources, it can be real-

ized that observing these criteria using risk probability

indicators has been under development since 1980 and

several conditions and health plans have been applied

according to the plans for selecting type of medical

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469 465

measure [15]. Such systems are based on several factors,

including diagnosis, earlier application, demographic

conditions, chronic diseases and personal evaluation

about health and/or executive condition. For instance,

GRAM is a hierarchical and clinical model of the

healthcare application [16]. This model was studied on

100,000 people who were selected randomly from sev-

eral HMO. This model uses the data related to population,

diagnostic qualification, and cost. This system classifies

diseases according to clinical features and the relevant

reactions toward disease. There are 350 diagnostic

grades, which are classified into 9 groups. This model

has not been used yet [2]. Analytical study of the similar

systems shows that there are some constraints, the most

important of which are as follows:

1) Concentration on risk factors related to cost man-

agement and financial issues instead of issues of medical

procedures;

2) Application of risk regulatory framework instead of

risk disclosure framework;

3) Without performance for application of new risk

factors;

4) Lack of attention to some approaches to assess sys-

tem.

In conclusion, with respect to these constraints using

the current systems and by careful consideration of di-

agnosis of possible risk in the field of healthcare, espe-

cially measures, it can be realized that application of

some of IT-based methods, such as expert systems/

knowledge discovery is a data mining function and per-

formance of the current methods for risk assessment are

improved significantly.

To find the relationships between risk factors and rela-

tionships between these factors and results of medical

procedures, an intelligent model would be very efficient

and effective. This means that optimization of a physi-

cian’s performance by applying the effect of possible

risk factors on clinical procedures is considered as a sig-

nificant advantage in intelligence risk detection model.

Due to the diversity of population of patients based on

diagnosis, symptoms, type of the implemented proce-

dures, patient’s age at the time of procedure, and other

necessary factors, assessment of risk probability for

medical procedures is a challengeable issue [17].

With respect to this issue, analysis of the results

achieved for risk probability of the medical procedure

leads to improvement of the performance of physicians

and care centers. Although assessment of risk probability

is an essential issue in decision-making of healthcare

processes, most researchers studying in the field of

healthcare believe that there are a few intelligent systems

with real-time risk assessment factor.

3.4. Risk Assessment

In order to assess the improvement of clinical proce-

dures, it should be noted that identification of possible

risk factors is a useful method [14]. To identify possible

risk factors, it is necessary to develop a multidimensional

model to make evaluation of possible risk accurately. In

the studies carried out, different methods have been de-

vised to study the aspects of the issue and evaluate pos-

sible risk factors; each of them needs different levels of

participation of specialists [10,13].

In the first method, some of the possible factors of

special risks are presented with the presence of some

experts in a concentrated team. Then, the specialists

identify the principle aspects of the risk, which are used

for decision-making in medical procedures. The layers of

these factors provide the risk factors for risk assessment

checklist. In another method, physicians are requested to

fill out risk assessment checklist by assessing risk factors

and define the relationships between these factors or the

relationships between these factors and some actual and

anticipated results and ranges of risks to determine key

performance indicators (KPI). In addition, the methods

recommended by clinical specialists are also presented

and they are requested to assess reaction to these issues

[1,2] (Figure 1).

Risk Detection Using Expert Systems

To apply the intelligent technology in the process of

risk assessment, we recommended using data mining

techniques after discovering knowledge. In studies, dif-

ferent kinds of health data also have a considerable effect

on the technique used for data mining [7]. In fact, after

the end of the step of data collection, some appropriate

procedures should be defined, including sharing and

neural networks. To apply necessary methods of data

mining, development and application of the model is

created after the process of risk assessment of a small

database, which encompasses patients’ data. Some parts

of data show risk factors. Then, following steps (1 to 6)

should be applied [7,9,18].

Step 1. Business Understanding: It includes problem

objective, evaluation of current condition, definition of

data mining objectives, structure of sets of data, and

creation of a project scheduling.

Step 2. Data Understanding: This step includes prepa-

ration of preliminary data sets, data description, explora-

tion of data, and assessment of data quality. Exploration

of data, including statistical parameters, can also occur at

the end of this step. Models like clustering can also take

place during this step to recognize patterns in data.

Step 3. Data Preparation: This step includes selecting

and changing the relevant features, cleaning data, com-

piling data and discussing findings with experts during

data preparation. A deeper search in data can be per-

formed in this step. In addition, other models may be

used to extract the patterns based on the business under-

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469

466

antee continuous improvement of the anticipated capa-

bilities [1,2,13].

standing.

Step 4. Modeling: Web mining software tools like

(Visualization) and (Clustering Analysis) are useful for

preliminary analysis. Tools like recognizing public rules

are able to extract preliminary correlation rules. When a

more understanding of the data is achieved by recogniz-

ing the pattern, which is obtained with respect to the

outputs of the preliminary models, more specialized

models can be used in terms of the type of data.

As risk factors are effective in reducing people’s qual-

ity of life, the importance of a correct design of deci-

sion-making processes in medical procedure has become

significantly important. The way to follow procedures

always involves innovation in medical technologies;

therefore, by indentifying these risk factors, healthcare

axes can be classified into four key components [1,2,4,

13]:

Step 5. Evaluation: The results obtained from the

models, which were used at the earlier steps are evalu-

ated at the early stages using the performance evaluation

set and within the defined issue and the defined objec-

tives. This will lead to identifying the following needs.

1) Physiological issues with respect to the importance

of quality of life;

2) Technological issues based on new technologies and

their performance;

Step 6. Deployment: Deployment includes arranging a

discussion with experts about data extraction to study the

accuracy of the discussed theorems and to discover the

possible or knowledge patterns from the results of data

extraction. Therefore, if new risk factors or patterns are

discovered, they will discuss the findings with deci-

sion-makers to determine appropriate procedures.

3) Biomechanical issues with respect to health condi-

tion of patients to perform remedial action;

4) Financial issues on costs of these technologies with

quality and type of remedial action;

Consequently, we discuss IRD Model to support deci-

sion-making for a better treatment for this population of

patients during medical procedures and after it. This can

provide better results for the patients and their families.

Of course, a different attitude was adopted toward the

models proposed in literatures [1,2,13] in terms of gen-

erality of issue and scope of discussion, which needs a

detailed account [4].

4. IRD PROPOSED MODEL

Figure 3 shows the steps of risk assessment. The out-

put of risk assessment process helps to determine the

important risk factors of healthcare and to anticipated

results based on the relevant factors. The anticipated re-

sults enable physicians to decide on the care/treatment/

medical plan. To make the final decision, measures are

taken to provide patients with necessary information on

the care plan. Any conflict in making decision on proce-

dure and patients indicates a high level of risk and is

considered as a negative consequence for the procedure.

Such a conflict is used to evaluate possible risk in the

future for the same patient or the other patients in the

system. After medical procedures, the actual results are

also compared with the anticipated results. This com-

parison is an evaluation approach for the model to guar-

To develop such a model in terms of its theatrical and

operational aspects, it is necessary to combine three key

scopes of expert system, risk detection system and deci-

sion support system (Figure 4).

According to the decision-making process framework,

two types of decision-makings (personal decision-mak-

ing and decision-making based on medical procedures)

are defined. This model (Figure 3) leads to detecting

real-time possible risk factors and anticipation of results

of medical procedures. The results in personal and

medical decision-makings are of paramount importance

[19].

Figure 3. Conceptual model for risk assessment [2].

OPEN A CCESS

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469 467

Figure 4. Intelligence risk detection model.

In the relevant conceptual model, the actual results are

compared with the anticipated results to evaluate risk

detection process. Therefore, actual results sometimes

present new risk factors or new measurement. Healthcare

intelligence reporting tools are the best solutions for cre-

ating final report. They show the most important items,

apply them in the process of risk possibility evaluation,

and these evaluations are repeated subsequently.

5. DISCUSSION

This study discusses the general framework to com-

bine real-time and intelligent risk detection by supporting

decision-making in the field of healthcare. Medical pro-

cedures were also selected due to the complex entity of

decision-making in this field and several risk factors of

this type in decision-makings.

Lack of interaction between college researchers and

those who are active in healthcare industry make detec-

tion of possible risks difficult. In addition, it limits op-

portunities to apply data mining techniques, reduces

value of knowledge discovery, and weakens the way data

are extracted in the field of detecting healthcare risks.

Detection of possible risks of measures has many di-

mensions and aspects whose major focus is mainly on

pathological process, physiological variables, some de-

ductions related to public health, social paradigm, and

quality of life [20]. Consequently, detection of risk fac-

tors is not easy in all aspects; however, evaluation of risk

probability, principally performed by participation of

experts, would be possible based on the new techniques.

Here, we try to discuss some of its main dimensions.

Some limited studies have been carried out to study

the direct advantages of real-time risk detection and an-

ticipation of result to promote decision-making process

in the healthcare field [2,3]. The advantage of this model

is its continuation, as actual and anticipated results

should be compared regularly to correct risk factors,

which leads to improving anticipations in the future. The

important characteristics of the IRD model in combining

3 solutions of IT to remove a clinical problem is related

to the definition and evaluation of patients’ results which

are combined with some scales of evaluation. It should

be noted that the theoretical framework of a problem,

which were developed in the present study using the

thoughts of other researchers [1,2,4,8,13], can be evalu-

ated in the following studies; however, evaluation of

operability of the model will bring about the following

challenges:

1) Applications of IRD Model;

2) Long time developments in healthcare field to

develop capabilities for intelligence models in risk

detection [2];

3) Its major application in case studies;

4) Hospitals’ incentives to execute a project.

6. CONCLUSION

The present paper mainly focuses on describing risk

possibility decision-making to improve efficiency of de-

cision-making in the field of healthcare, and specifically

medical procedures. Today, in the field of healthcare that

is changing rapidly, decision-makers encounter with

ever-increasing inquiries on clinical and administrative

information to realize customers’ legal and clinical re-

quirements [21]. Therefore, making decisions on health-

care has changed into a vital, complex and unstructured

issue [4]. Intelligence risk detection is a challenging field

within health profession [3]. This is not only due to the

fact that it is difficult to experiment with a project and

create samples from educational contents, but also due to

the fact that the field of healthcare has a variety of ser-

vices, scopes, reasons, and irregular relations [1]. We

discussed the application of expert systems and knowl-

edge management in anticipating care results and detect-

ing possible risks of medical procedures at high levels.

The discussed model is based on two steps of (medical

and personal) decision-making processes [22] and in-

cludes a type of decision support systems, which is suit-

able for anticipating the high quality results of healthcare

process [5]. The results update the system to detect pos-

sibility of risk more accurately and adaptively and abili-

ties of anticipating the results are compared with the

fixed model. The present study emphasizes on the im-

portance of risk detection, anticipation, knowledge dis-

covery, and decision on the process of decision-making

to perform clinical procedures on patients. During fol-

lowing steps, it can be applied in appropriate clinical

environments. Therefore, modeling an intelligent support

system is vital for the majority fields of healthcare, espe-

cially for high-risk and complex decision-making cases.

Therefore, it is necessary to design real-time risk detec-

tion information systems in clinical procedures and con-

duct further studies in this field. As taking medical pro-

cedures involves complex decision-makings and possi-

bility of high risk, operational application of the tech-

niques derived from knowledge and data mining models

under study will play a crucial role in increasing possi-

bility of success of the measure and promoting immunity

R. Safdari et al. / Open Journal of Preventive Medicine 3 (201 3) 461-469

468

of patients.

7. ACKNOWLEDGEMENTS

We would like to thank Ahmad Soltani, expert of Health Information

Management at research center for Health Information Management,

for his contributions to the research presented here. We would also like

to thank the reviewers for their insightful comments.

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ABBREVIATIONS

KM: Knowledge Management;

HI: Healthcare Intelligence;

MAS: Multi-Agent Systems;

AOP: Agent-Oriented Programming;

DSS: Decision Support Systems;

CDSS: Clinical Decision Support Systems;

MDSS: Medical Decision Support Systems;

GRAM: Global Risk Assessment Model;

IRD: Intelligence Risk Detection;

KDD: knowledge discovery in databases;

IC: Intelligence Continuum;

BI: Business Intelligence.