Running head: ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
Annotated Bibliography on Technology in Nursing
Learner’s Name
Capella University
Managing Health Information and Technology
Annotated Bibliography on Technology in Nursing
August, 2019
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
1
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
2
Technology in Nursing
Pulse oximetry is one of the most common methods of measuring the percentage of
oxygen saturation in blood (Narayen et al., 2016). Pulse oximeters play a crucial role in critical
care settings by detecting low levels of oxygen saturation. Pulse oximeters are also adopted by
anesthesiologists in recovery, emergency, and pediatric wards; operation theatres; and neonatal
units (Hendaus, Jomha, & Alhammadi, 2015). This annotated bibliography provides insight into
how pulse oximeters are used, their limitations and accuracy, and patient outcomes.
Annotated Bibliography
Hendaus, M. A., Jomha, F. A., & Alhammadi, A. H. (2015). Pulse oximetry in bronchiolitis: Is it
needed? Therapeutics and Clinical Risk Management, 11, 1573–1578.
https://dx.doi.org/10.2147%2FTCRM.S93176
This article discusses the use of pulse oximetry in pediatric wards. The authors state that
hospitals in the United States admit a significant number of children every year with
bronchiolitis and other respiratory problems. These problems are usually monitored with
the help of a pulse oximeter, an instrument used to measure the saturation of oxygen in
the blood. Oxygen saturation levels are used by health care providers to evaluate a
patient’s respiratory status and are one of the deciding factors for a patient’s discharge.
Pulse oximetry is frequently used in pediatrics (in pediatric intensive care units and
pediatric wards) and in emergency departments. Pulse oximeters are used to monitor
oxygen saturation during resuscitations, while estimating perfusion, while detecting
pulsus paradoxus, and while screening infants for congenital heart disease. Though the
source does not fully explain why the limitations occur, it identifies several cases in
which pulse oximeters are likely to be inaccurate. Pulse oximeters have certain
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Commented [A1]: Comprehensive information regarding the
types of pulse oximetry devices, selection criteria, decision makers,
and associated costs is not available in the selected papers. The two
types of pulse oximeters and their advantages over the others is
provided; however, information on the various types of pulse
oximeters is not available and the associated costs are not provided.
This paper does mention that this technique is cost-effective which
can fulfill the required criteria.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
3
limitations due to inadequate signals. Inadequate signals occur in cases of anemia, bright
external light, dark skin, nail polish, low perfusion, and intravenous dye. Pulse oximeters
show low readings in cases of venous pulsations such as severe right heart failure,
tricuspid regurgitation, and blood pressure cuffs or tourniquets above the site of the pulse
oximeter. Pulse oximeters might not detect hypoxemia in patients with elevated arterial
oxygen tension levels because of the sigmoidal shape of the oxyhemoglobin dissociation
curve. Also, pulse oximeters provide unreliable readings in cases of methemoglobinemia.
The source highlights several limitations, which will help readers exercise caution when
using pulse oximeters. However, despite these limitations, the use of pulse oximeters in
pediatrics is recommended because they are handy and allow for noninvasive measuring
of arterial oxygen saturation.
Commented [A2]: Meets criterion 3 as it deals with
organizational factors that influence the selection of a technology in
health care setting.
Jubran, A. (2015). Pulse oximetry. Critical Care, 19(1), 272.
https://dx.doi.org/10.1186%2Fs13054-015-0984-8
This article provides insight into the principles, accuracy, functioning, and outcome of
pulse oximeters. It discusses the potential advantages of multiwavelength pulse oximeters
over conventional pulse oximeters. Multiwavelength pulse oximeters are capable of
estimating the blood levels of carboxyhemoglobin and methemoglobin, whereas
conventional pulse oximeters assume that dyshemoglobins such as carboxyhemoglobin
and methemoglobin are absent because they can only distinguish between hemoglobin
and oxyhemoglobin. Hence, physicians prefer to use multiwavelength pulse oximeters for
more accurate results. In hospital settings, the transfer rate from a postsurgical care floor
to the intensive care unit (ICU) is an important factor that influences the use of pulse
oximeters. The resource reviews a study by Ochroch et al. in which patients were
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Commented [A3]: Deals with criterion 3: Organizational factors
that influence the selection of a technology in health care setting.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
4
monitored by pulse oximeters either continuously (oximeter group) or intermittently
based on clinical needs as judged by a physician or a nurse (control group). The rate of
ICU transfers for pulmonary complications was lower in the oximeter group than in the
control group. Additionally, for patients who did require ICU transfers, the estimated cost
of treatment from enrollment to the completion of the study was lower for the oximeter
group ($15,481) than for the control group ($18,713) despite the patients in the oximeter
group being older and having higher comorbidity. The reduction in pulmonary transfers
to the ICU in the oximeter group was speculated to be the result of early recognition and
treatment of postoperative pulmonary complications. As cited in Jubran, another study by
Moller et al. indicates that anesthesiologists considered pulse oximetry to be of immense
value as it guides clinical management. Anesthesiologists recommend the use of pulse
Commented [A4]: Deals with criterion 3: Organizational factors
that influence the selection of a technology in health care setting.
oximeters because they believe that maintaining oxygenation within limits might help
prevent irreversible injury. Pulse oximetry is, therefore, a key part of the standard
protocol for monitoring critically ill patients.
Narayen, I. C. et al. (2016). Aspects of pulse oximetry screening for critical congenital heart
defects: When, how and why? Archives of Disease in Childhood – Fetal and Neonatal
Edition, 101(2), F162–F167. http://dx.doi.org/10.1136/archdischild-2015-309205
This article describes how pulse oximetry is being implemented worldwide for the
screening of critical congenital heart defects (CCHD). The use of pulse oximetry to
screen for CCHD is highly recommended because it is effective, quick, simple, and costeffective. The authors state that training parents and caregivers and using tools that are
computer based can improve pulse oximetry screening. Pulse oximetry helps detect
significant pathology and is reliable for keeping track of CCHD, which requires constant
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Commented [A5]: Fulfills the rubric criteria: Justify the
implementation and use of a selected technology in a health
care setting.
And also fulfills: Describes organizational factors influencing
the selection of a technology in the health care setting.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
5
diagnosis and immediate medical intervention. In almost every infant with CCHD,
clinically undetectable hypoxemia is identified by pulse oximeters. Early studies of
neonatal pulse oximetry screening for CCHD showed accurate details. As a result, the
U.S. Secretary of Health and Human Services advised adding CCHD screening to the
recommended uniform screening panel. According to a meta-analysis of 13 screening
studies, pulse oximetry screening reported a specificity of 99.9 percent, a sensitivity of
76.5 percent, and a false positive rate of 0.14 percent. Therefore, the authors concluded
that the universal screening criteria were met by pulse oximetry screening. Pulse
oximetry screening shows no difference in accuracy when pre-ductal and post-ductal
pulse oximetry measurements are performed. The authors also observed that pulse
oximetry screening done 24 hours after birth increases the risk of late detection of CCHD
in infants but decreases the false positive rate. Therefore, the use of pulse oximeters can
be crucial for the early detection of CCHD and helps reduce mortality and improve
postoperative outcomes.
Nitzan, M., Romem, A., & Koppel, R. (2014). Pulse oximetry: Fundamentals and technology
update. Medical Devices: Evidence and Research, 7, 231–239.
https://doi.org/10.2147/MDER.S47319
This article offers comprehensive insight into how pulse oximetry works; particularly, it
looks at the techniques involved in measurement, the limitations of using the techniques,
and the accuracy that can be expected while determining oxygen saturation. Oxygen
saturation (SaO2) is the measurement of the percentage of oxygen in hemoglobin. Pulse
oximeters detect the significant decline of oxygen in the respiratory function of patients.
Measurements of oxygen saturation in pulse oximeters (SpO2) are often inaccurate when
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Commented [A6]: Fulfills the rubric criteria: Justify the
implementation and use of a selected technology in a health
care setting.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
6
critically ill patients receive supplemental oxygen. The difference between SpO2 and
SaO2 determines the accuracy of a pulse oximeter. Though the outcome of pulse oximetry
in measuring SaO2 in sick patients is 3–4 percent inaccurate, pulse oximeters quickly
detect the abrupt drop of SpO2 in anesthetized patients and in patients in intensive care
units. Despite the limitations of pulse oximetry, SpO2 values obtained from the pulse
oximeter are considered reliable for the detection of deterioration in respiratory function.
Further, pulse oximetry has the advantage of being a noninvasive technique to measure
oxygen saturation. Studies suggest that pulse oximetry should not be the only method to
monitor SaO2 in the neonatal intensive care unit because of infants’ vulnerability to
Commented [A7]: Fulfills the criteria: Justifies the
implementation and use of a selected technology in a health
care setting. Provides an in-depth and well-researched
analysis of the impact of the technology on quality care and
patient safety.
retinopathy of prematurity, which is induced by the high partial pressure of oxygen in
arterial blood. The authors conclude that technological advancements in pulse oximeters
over the years have enabled them to diagnose and monitor patients better.
Conclusion
Despite their limitations, pulse oximeters are recommended for monitoring oxygen
saturation levels in patients with respiratory problems. The use of pulse oximeters helps reduce
the rate of pulmonary transfers of patients from a postsurgical floor to the ICU. They play a
crucial role in screening infants for CCHD, and therefore, the use of pulse oximeters in pediatric
wards is highly recommended. Pulse oximetry helps in the early detection of certain diseases,
thereby preventing irreversible damage to organs and reducing the rate of mortality. Pulse
oximeters are a cost-effective resource in hospitals. They can easily detect a significant decline
of oxygen in the respiratory function of patients. The rate of transfers to the intensive care unit
due to pulmonary complications was significantly lower in patients who were continuously
monitored using pulse oximeters than in patients who were intermittently monitored using pulse
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Commented [A8]: Fulfills criteria 3: Describes organizational
factors influencing the selection of a technology in the health
care setting.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
7
oximeters. The readings obtained from pulse oximeters are reliable and help make immediate
adjustments to a patient’s oxygen supply, which can help prevent irreversible damage or death.
The limitations of conventional pulse oximeters are overcome by multiwavelength pulse
oximeters, which can estimate the levels of carboxyhemoglobin and methemoglobin in blood.
Medical practitioners in interdisciplinary teams, such as pediatricians, pulmonologists, and
anesthesiologists, can collectively use the readings obtained from pulse oximetry to assess the
condition of a patient before administering treatment. Hence, pulse oximetry is valuable in
hospital settings, helping medical practitioners decide the correct course of treatment and provide
immediate and effective care to patients.
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
ANNOTATED BIBLIOGRAPHY ON TECHNOLOGY IN NURSING
8
References
Hendaus, M. A., Jomha, F. A., & Alhammadi, A. H. (2015). Pulse oximetry in bronchiolitis: Is it
needed? Therapeutics and Clinical Risk Management, 11, 1573–1578.
https://dx.doi.org/10.2147%2FTCRM.S93176
Jubran, A. (2015). Pulse oximetry. Critical Care, 19(1), 272.
https://dx.doi.org/10.1186%2Fs13054-015-0984-8
Narayen, I. C., Blom, N. A., Ewer, A. K., Vento, M., Manzoni, P., & te Pas, A. B. (2016).
Aspects of pulse oximetry screening for critical congenital heart defects: When, how and
why? Archives of Disease in Childhood – Fetal and Neonatal Edition, 101(2), F162–
F167. http://dx.doi.org/10.1136/archdischild-2015-309205
Nitzan, M., Romem, A., & Koppel, R. (2014). Pulse oximetry: Fundamentals and technology
update. Medical Devices: Evidence and Research, 7, 231–239.
https://doi.org/10.2147/MDER.S47319
Copyright ©2019 Capella University. Copy and distribution of this document are prohibited.
Annotated Bibliography on Technology in Nursing
Scoring Guide
CRITERIA
NONPERFORMANC
E
BASIC
PROFICIENT
DISTINGUISH
ED
Analyze
current
evidence on
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team.
Does not
analyze
current
evidence on
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team.
Identifies but
does not
analyze
current
evidence on
the impact of
a selected
patient care
technology on
patient safety,
quality of
care, and the
interdisciplina
ry team.
Analyzes
current
evidence on
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team.
Provides a
rigorous,
scholarly, and
perceptive
analysis of
current
evidence on
the impact of
a selected
patient care
technology on
patient safety,
quality of
care, and the
interdisciplina
ry team.
Integrate
current
evidence about
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team into a
recommendati
on.
Does not
integrate
current
evidence about
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team into a
recommendati
on.
Integrates
some
evidence
about the
impact of a
selected
patient care
technology on
patient safety,
quality of
care, and the
interdisciplina
ry team into a
recommendati
on, but the
work lacks
detail or is
missing
critical
information.
Integrates
current
evidence about
the impact of a
selected
patient care
technology on
patient safety,
quality of care,
and the
interdisciplinar
y team into a
recommendati
on.
Integrates
wellresearched
and current
evidence
about the
impact of a
selected
innovative
patient care
technology on
patient safety,
quality of
care, and the
interdisciplina
ry team into a
recommendati
on. Provides
clear insight
into the
potential
CRITERIA
NONPERFORMANC
E
BASIC
PROFICIENT
DISTINGUISH
ED
implications
of the
technology on
patient safety
and quality of
care.
Describe
organizational
factors
influencing the
selection of a
technology in
the health care
setting.
Does not
describe
organizational
factors
influencing the
selection of a
technology in
the health care
setting.
Identifies but
does not fully
describe
organizational
factors
influencing
the selection
of a
technology in
the health care
setting.
Describes
organizational
factors
influencing the
selection of a
technology in
the health care
setting.
Provides a
scholarly,
comprehensiv
e, and wellresearched
description of
organizational
factors
influencing
the selection
of a
technology in
the health care
setting.
Justify the
implementatio
n and use of a
selected
technology in
a health care
setting.
Does not
justify the
implementatio
n and use of a
selected
technology in
a health care
setting.
Explains but
does not
justify the
implementatio
n and use of a
selected
technology in
a health care
setting.
Justifies the
implementatio
n and use of a
selected
technology in
a health care
setting.
Justifies the
implementatio
n and use of a
selected
technology in
a health care
setting.
Provides an
in-depth and
wellresearched
analysis of the
impact of the
technology on
quality care
and patient
safety.
CRITERIA
NONPERFORMANC
E
BASIC
PROFICIENT
DISTINGUISH
ED
Create a clear,
wellorganized, and
professional
annotated
bibliography
that is
generally free
from errors in
grammar,
punctuation,
and spelling.
Does not
create a clear,
wellorganized, and
professional
annotated
bibliography
that is
generally free
from errors in
grammar,
punctuation,
and spelling.
Provides an
annotated
bibliography
that has errors
in grammar,
punctuation,
and spelling
and exhibits a
lack of
preparation.
Creates a
clear, wellorganized, and
professional
annotated
bibliography
that is
generally free
from errors in
grammar,
punctuation,
and spelling.
Creates a
clear, wellorganized, and
professional
annotated
bibliography
that is free
from errors in
grammar,
punctuation,
and spelling.
Follow APA
style and
formatting
guidelines for
all
bibliographic
entries.
Does not
follow APA
style and
formatting
guidelines for
citations and
references.
Partially
follows APA
style and
formatting
guidelines for
citations and
references.
Follows APA
style and
formatting
guidelines for
all
bibliographic
entries.
Follows APA
style and
formatting
guidelines for
citations and
references
with flawless
precision and
accuracy.
Resources:
Patient Portal Considerations: Health Literacy and Accessibility.
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Elkind, E. C., & Higgins, K. M. Patient portal considerations. Nursing
Management, 49(3), 9–11.
This article explores the need for a collaborative team approach to helping patients take a
more active role in their health care by utilizing the patient portal.
Heath, S. (2018). Using NLP to improve patient oortal use, patient health
literacy. Retrieved from https://patientengagementhit.com/news/using-nlp-to-improvepatient-portal-use-patient-health-literacy
Heath reviews research that demonstrates natural language processing (NLP) as a
practical solution for patient portal use to better engage patients with personal health
information.
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o
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o
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Heath, S. (2018). Patient recall suffers as patients remember half of health info. Retrieved
from https://patientengagementhit.com/news/patient-recall-suffers-as-patients-rememberhalf-of-health-info
This article reviews a study out of Brown University School of Public Health on the
shortcomings of patients’ memories when given information by their doctors.
Heath, S. (2017). Simpler medical language key for patient portal lab result
notes. Retrieved from https://patientengagementhit.com/news/simpler-medical-languagekey-for-patient-portal-lab-result-notes
Heath reports on a study that showed the need to simplify medical language in patient
portals.
Lyles, C. R., Fruchterman, J., Youdelman, M., & Schillinger, D. (2017). Legal, practical,
and ethical considerations for making online patient portals accessible for all. American
Journal of Public Health, 107(10), 1608–1611.
This article explains the need to improve the accessibility of portals for more vulnerable
patient populations, especially patients with limited health literacy or limited English
proficiency, and individuals with disabilities.
Sustained Utilization of Patient Portals:
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o
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o
•
o
•
o
•
Elkind, E. C., & Higgins, K. M. Patient portal considerations. Nursing
Management, 49(3), 9–11.
This article explores the need for a collaborative team approach to helping patients take a
more active role in their health care by utilizing the patient portal.
Heath, S. (2018). Using NLP to improve patient oortal use, patient health
literacy. Retrieved from https://patientengagementhit.com/news/using-nlp-to-improvepatient-portal-use-patient-health-literacy
Heath reviews research that demonstrates natural language processing (NLP) as a
practical solution for patient portal use to better engage patients with personal health
information.
Heath, S. (2018). Patient recall suffers as patients remember half of health info. Retrieved
from https://patientengagementhit.com/news/patient-recall-suffers-as-patients-rememberhalf-of-health-info
This article reviews a study out of Brown University School of Public Health on the
shortcomings of patients’ memories when given information by their doctors.
Heath, S. (2017). Simpler medical language key for patient portal lab result
notes. Retrieved from https://patientengagementhit.com/news/simpler-medical-languagekey-for-patient-portal-lab-result-notes
Heath reports on a study that showed the need to simplify medical language in patient
portals.
Lyles, C. R., Fruchterman, J., Youdelman, M., & Schillinger, D. (2017). Legal, practical,
and ethical considerations for making online patient portals accessible for all. American
Journal of Public Health, 107(10), 1608–1611.
o
This article explains the need to improve the accessibility of portals for more vulnerable
patient populations, especially patients with limited health literacy or limited English
proficiency, and individuals with disabilities.
Workflow and Data Mining:
•
o
•
o
•
o
•
o
•
o
•
o
Baek, H., Cho, M., Kim, S., Hwang, H., Song, M., & Yoo, S. (2018). Analysis of length
of hospital stay using electronic health records: A statistical and data mining
approach. PLoS ONE, 13(4), 1–16.
This study explores factors associated with length of hospital stay based on electronic
health records.
USF Health. (n.d.). Data mining in healthcare. Retrieved from
https://www.usfhealthonline.com/resources/healthcare/data-mining-in-healthcare/
This article explains how health care providers are using electronic health records to
improve the efficiency and quality of their organizations using data mining.
Heath, S. (2018). AMIA outlines data use guideline for patient-centered care,
PGHD. Retrieved from https://patientengagementhit.com/news/amia-outlines-data-useguideline-for-patient-centered-care-pghd
Heath explains the AMIA data use guidelines for patient-centered care specifically in
regard to how medical professionals can look at the social determinants of health.
Heath, S. (2017). E-consent forms useful for patient data sharing in research. Retrieved
from https://patientengagementhit.com/news/e-consent-forms-useful-for-patient-datasharing-in-research
The author reports on a study that shows that e-consent tools for patient data sharing in
research need more assurances of data security.
de Leoni, M., van der Aalst, W. M. P., & Dees, M. (2016). A general process mining
framework for correlating, predicting and clustering dynamic behavior based on event
logs. Information Systems, 56, 235–257.
This study examines different process mining research techniques and proposes a new
framework.
Meenan, C., Erickson, B., Knight, N., Fossett, J., Olsen, E., Mohod, P., . . . Langer, S.
G. Workflow lexicons in healthcare: Validation of the SWIM lexicon. Journal of Digital
Imaging, 30(3), 255–266.
The authors of this study measured workflow steps in a real-world clinical setting to
determine how accurately departmental information systems captured patient flow.
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