Differences in Brain Activity of Skilled and Novice Nurses during
Blood Collection
Naoki Taira
1
, Yukie Majima
1
, Seiko Masuda
1
, Tsuneo Kawano
2
, Masanori Akiyoshi
3
,
Kenji Adachi
4
, Kazuma Mihara
1
and Ryoma Namba
5
1
Graduate School of Humanities and Sustainable System Sciences, Osaka Prefecture University, Japan
2
Graduate School of Science and Engineering, Setsunan University, Japan
3
Department of Information Systems Creation, Faculty of Engineering, Kanagawa University, Japan
4
Department of Computer Science and Intelligent Systems, Graduate School of Engineering,
Osaka Prefecture University, Japan
5
College of Sustainable System Sciences, Osaka Prefecture University, Japan
Keywords: Blood Collection, Cerebral Blood Flow, FNIRS, Nursing Skills, Tacit Knowledge.
Abstract: Nursing skills are highly implicit. No effective method has been established for passing them on to the next
generation of nursing workers. This research represented an attempt to formalize the skills of skilled nurses.
To evaluate human mental state and emotions objectively, we clarified differences in brain activity between
skilled and novice nurses at the time of collecting blood from a patient. As a result, many skilled nurses tried
to use their own knowledge for the blood vessels they faced for the first time, irrespective of the blood
collection success or failure. However, some novice nurses face subsequent blood collection without
reflecting on the clear factors leading to success or failure.
1 INTRODUCTION
In recent years, the population of Japan has been
decreasing and rapidly aging. Concomitantly, demand
for workers in the medical and nursing fields is
increasing. Moreover, the sophistication and
complexity of medical and nursing technologies are
accelerating (Japan Cabinet Office, 2016). Therefore,
developing human resources and improving skills in
medical and nursing fields is important. The high
turnover rate of nurses, especially the early retirement
of new graduate nurses, has been a long-standing issue
(Japan Nursing Association, 2018). According to a
survey conducted by the Japan Nursing Association
cites take many factors that are related to nursing skills,
a gap between abilities at the end of basic nursing
education and abilities required at nursing sites and to
be required higher nursing skills than before, as one
cause of turnover(Japan Nursing Association, 2004).
For this reason, review of the education contents and
the mode of education in basic nursing education is
necessary. However, in the acquisition of nursing skills,
a need exists to formalize tacit knowledge because it is
difficult to transfer and pass on tacit skills such as
“skills” and “knacks” possessed by skilled nurses to the
next generation of workers (Naohisa, K. et al., 2004).
Thus, we attempt to clarify and formalize the skills
(tacit knowledge) possessed by skilled nurses.
In this paper, we especially focused on the blood
collection and aim to clarify the difference in brain
activity between skilled nurses and novice nurses
during blood collection.
2 RELATED RESEARCH
2.1 Tacit Knowledge of Nursing Skills
There are two types of tacit knowledge: "cognitive
aspect" and "technical aspect"(Yujiro, N. et al., 1996).
In the case of nursing skills, it is necessary to formalize
both of them. Most of the research on the cognitive
aspect is that there are subjective and qualitative
approaches such as interviews with nurses. In the
research on the technical aspect, we focused on skin
development and pressure, which are the movements
of auxiliary fingers during blood collecting, and tried
to clarify tacit knowledge by comparing the skills of
Taira, N., Majima, Y., Masuda, S., Kawano, T., Akiyoshi, M., Adachi, K., Mihara, K. and Namba, R.
Differences in Brain Activity of Skilled and Novice Nurses during Blood Collection.
DOI: 10.5220/0009165506990704
In Proceedings of the 13th Inter national Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2020) - Volume 5: HEALTHINF, pages 699-704
ISBN: 978-989-758-398-8; ISSN: 2184-4305
Copyright
c
2022 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
699
nurses and nursing students (Takeshi, M. et al., 2018),
(Naoki, U. et al., 2018).
2.2 Biological Information
Biological information is generated during activities
controlled by human autonomic nerves without human
consciousness. Such information is related to the
person’s mental and physical state. Examples of
biological information include pulse, respiratory rate,
and brain waves.
2.2.1 Biological Information:
Electroencephalogram
We especially examined brain waves in biological
information and conducted a study measuring brain
waves during nursing skills implementation. The
electroencephalogram expresses a person's mental
state and emotions more prominently than other
biological information. The study suggested that the
voice of a skilled nurse while performing intravenous
injection leads the patient to a relaxed state (Tsuneo, K.
et. al., 2016).
2.2.2 Biological Information: Cerebral Blood
Flow
In this research, we newly focused on cerebral blood
flow, which is one of biological information. It has
been reported that the activate parts on the left and right
sides of the brain reportedly differ and table 1 presents
the respective brain characteristics. Cerebral blood
flow is used as an objective index to evaluate
technology and content in various fields (Lei, H. et. al.,
2012), (Shinsuke, M. et. al., 2012). For this research,
we estimate brain activity based on changes in
oxygenated hemoglobin concentration in the cerebral
blood flow. In earlier study, we measured cerebral
blood flow during five consecutive blood collecting
sessions, and qualitatively considered the state of brain
activity flow during each blood collecting by skilled
nurses and novice nurses (Takahito, T., 2018).
Table 1: Brain functions and features.
Right
brain
Called “image brain,” it is activated
when thinking according to the image
and emotion
Left
brain
Called “Language Brain,” it is activated
when you think about things logically
and understand the lan
g
ua
g
e
Therefore, this research further expanded the field
of view, we particularly focused on the success and
failure of blood collecting through five sessions.
We aimed to elucidate the state of brain activity
flow when nurses succeeded or led from failure to
success of blood collecting.
3 EXPERIMENT
3.1 Outline of Experiment
For the present research, we specifically examine the
“blood collection technique” that is frequently used in
nurse’s daily work and measure the brain activity
during puncture. Blood collection was performed using
arm models for blood collection simulation. A patient
role-player was set in front of subjects to give a sense
of realism of blood collection. The nurse was able to
collect blood while talking with the patient. Table 2
shows the experimental location and period. Fig. 1
portrays the experimental environment.
This research was conducted with the approval of
the Ethics Committee of the Graduate School of
Sustainable System Sciences, Osaka Prefecture
University.
Table 2: Experiment place and period.
Implementation period
4 days from November to
December 2018
Implementation location
practice room in Hospital
A
Figure 1: Experiment environment.
3.2 Subject of Experiment
Subjects were 19 active nurses working at a hospital
who agreeded to collaborate. Table 3 shows the ladder
levels and the number of nurses. The ladder level is a
nurse development and evaluation system and axis
established by the Japan Nursing Association. It
includes five levels of competence and career, ranging
from a novice to an experienced practitioner: higher
numbers denote higher nursing practice capabilities.
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For the present research, we referred to the ladder level
set by the hospital at which the target nurses work and
divided them into two groups: novice nurses and
skilled nurses.
Table 3: Nurse ladder lebel.
Implementation
category
Ladder
level
Number of
people
Total
Novice nurse
9
9
0
Skilled nurse
4
10
4
2
Total 19
3.3 Used Equipment
3.3.1 Cerebral Blood Flow Meter
For analyzing brain activity, we used a wearable
optical topograph (NIRS WOT-220; Hitachi Ltd.), a
cerebral blood flow meter, to measure changes in
oxygenated hemoglobin concentrations in cerebral
cortical blood flow. This cerebral blood flow meter has
10 channels, each of which measures oxygenated
hemoglobin in the cerebral blood flow.
Figure 2: Wearing a cerebral blood flow meter.
3.3.2 Arm Model for Blood Collecting
Simulation
For the blood collecting simulation, we used an arm
model (LM-086; Koken Co. Ltd.), from which a nurse
can select blood vessels to collect blood. Several types
of blood vessel models can be used. Fig. 3 shows the
arm model. Fig. 4 shows the type and difficulty of
blood vessel models.
Figure 3: The arm model with the blood vessel model.
We explained in advance that exchanging multiple
simulation model. However, participants did not know
from which blood vessel model they will collect blood.
Figure 4: The type and difficulty of the blood vessel model.
4 ANALYTICAL METHOD
We examined the brain activity of nurses based on
changes in hemoglobin concentrations in the cerebral
blood flow obtained from experiments. The data are
graphed. Features are extracted from the graph. The
analytical procedure is presented below.
4.1 Channel Selection
Ten channels of the cerebral blood flow meter were
divided into two areas, the left brain and the right brain.
Then the average values of channels operating
normally from each area were calculated. Normal
operation required that to satisfy the two conditions:
(1) the device is in the “Normal” state during
calibration, and (2) the measured value does not detect
an extreme abnormal value.
4.2 Graph Smoothing
It is difficult to interpret the overall characteristics even
when graphed because the raw data obtained from the
cerebral blood flow meter are noisy. Therefore, it
might be necessary to smooth the graph by applying
some processing in order to make it easy to ascertain
the graph characteristics.
4.2.1 Graph Smoothing in Earlier Study
Earlier study removed noise on the raw data using the
moving average method in order to facilitate
interpretation of the characteristics of the graph.
Subsequently, smoothing was performed by reducing
the number of data by calculating root mean square
(RMS) values. However, if RMS is applied to raw data
that might be negative, then the output would be a
positive value, which cannot represent brain activity
accurately. Therefore, for this research, data smoothing
was attempted by the following procedure.
Differences in Brain Activity of Skilled and Novice Nurses during Blood Collection
701
4.2.2 Graph Smoothing in This Research
High frequencies above a certain threshold are often
noise generated by the experimental environment and
the life activity of the subject because cerebral blood
flow gradually reflects changes in neural activity over
time. Therefore, this time, noise was removed by
application of Low Pass Filter.
4.3 Normalization
Analyses of Cerebral blood flow were made based on
the amount of hemoglobin concentration change in
each nurse because individual differences exist in the
absolute amount of hemoglobin concentration change
in the cerebral blood flow. The amount of change was
expressed as a value of 0-1.
5 RESULTS AND DISCUSSION
One graph shows the transition of oxygenated
hemoglobin concentration during five blood
collections. The vertical blue line mark in the graph
shows the following time points during one blood
collection: (1) start of blood collection, (2) needle
insertion, (3) needle removal, and (4) end of blood
collection. In addition, the nurse ID and type of blood
vessel model are shown in the graph. Each trial is
separated by a red bold vertical line. The success ()
and failure (×) of blood collection are shown at the top
of the graph.
5.1 Patterns of Skilled Nurse Success
The pattern monitored in Figure 7 is often seen by
skilled nurse who completely succeeded in all blood
collections. The transition of oxygenated hemoglobin
concentration in both of right brain and left brain were
highest at the first time and gradually decreased from
the second to the fifth blood collection. In addition, the
time required for blood collection was the longest at
the first time and gradually decreased.
Figure 7: Example of a pattern of skilled nurse success.
Accordingly, it is considered that a skilled nurse
who has high ladder level and high blood collection
technique is gradually able to succeed in blood
collection without considering because deep
considering about success factor when succeed for the
first time, they can grasp the knack.
5.2 Patterns of Novice Nurse Success
The pattern monitored in Figure 8 is often seen by
novice nurse who completely succeeded in all blood
collections showed the different graph from that of
skilled nurse success pattern. The transition of
oxygenated hemoglobin concentration did not
gradually decreased from the second to the fifth like a
skilled nurse. The transition of oxygenated hemoglobin,
especially in the left brain, was flat from the first to the
fifth blood collection.
Accordingly, it is considered that someone of
novice nurses who has low ladder level and low blood
collection technique was not able to succeed blood
collection without deep considering from the second
time on too because they could not understand the
success factor even when succeeded.
Figure 8: Example of a pattern of novice nurse success.
5.3 Patterns Leading to Success from
Failure of Skilled Nurse
The pattern monitored in Fig. 9 is often seen by skilled
nurse who failed once the first or second blood
collection and succeeded more than three times
thereafter. The pattern was similar to the pattern of
skilled nurse success. The transition of oxygenated
hemoglobin concentration was the highest at the first
time and gradually decreased from the second to the
fifth blood collection.
Figure 9: Example of a pattern leading to success from failure
of skilled nurse.
Accordingly, it is considered that a skilled nurse
who has high ladder level and high blood collection
technique is thereafter able to success blood collection
because they finded and improved the cause of failure
by deep considering about it when failed.
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5.4 Patterns Leading to Success from
Failure of Novice Nurse
The pattern monitored in Fig. 10 is often seen by
novice nurse who failed once the first or second blood
collection and succeeded more than three times
thereafter. The pattern was similar to the pattern of
leading to success from failure by skilled nurse but the
transition of oxygenated hemoglobin concentration
was different from that when skilled nurses failed in
blood collection.
Accordingly, it is considered that a skilled nurse
who has low ladder level and low blood collection
technique collected blood at the first time without deep
considering because not finding success factor, they
could not understand what should do when they
collected blood.
Figure 10: Example of a pattern leading to success from
failure of novice nurse.
6 CONSIDERATION
This research clarified differences in brain activity
between skilled nurses and novice nurses during blood
collecting from the viewpoint of changes in
oxygenated hemoglobin concentration in the cerebral
blood flow. Results indicate that many skilled nurses
tried to use their own knowledge for the blood vessels
they faced for the first time, irrespective of the blood
collection success or failure. However, some novice
nurses face subsequent blood collection without
reflecting on the clear factors leading to success or
failure. Therefore, the brain continues to be active
every time, even if the failure continues or succeeds.
From the above, one can infer that, at the time when
the first blood collection is completed in the future, the
nurses are encouraged to reflect on their performance.
From that point forward, the skilled nurse and the
novice nurse will specifically examine what points to
connect to the next blood collection analyses and will
verify the difference. Results demonstrate such
reflection and subsequent success are necessary
experiences to clarify the tacit knowledge of skilled
nurses in nursing techniques that are difficult to
verbalize.
7 FUTURE WORK
We think to use another biological information like
gaze and pressure and develop index that can measure
nursing skills proficiency based on all of biological
information.
ACKNOWLEDGMENTS
This research was supported by JSPS KAKENHI
16H05571, 17H04433, 17K19845, 19K22774. We
deeply appreciate the nurses, including those of
Hospital A, for their cooperation with this research.
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