Panacea Journal of Medical Sciences 2022;12(2):430–435

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Panacea Journal of Medical Sciences

Journal homepage: http://www.pjms.in/  

 

Original Research Article

A study of critical value analysis at hematology and biochemistry sections of
laboratory in a multispeciality hospital

Shubha H.V1,*
1Dept. of Pathology, Sapthagiri Institute of Medical Sciences and research Centre, Chikkabanavara, Chikkasandra, Bangalore,
Karnataka, India

 

 

A R T I C L E I N F O

Article history:
Received 27-08-2022
Accepted 04-10-2022
Available online 17-08-2022

Keywords:
Critical value notification
Critical call out
Critical alert
Short message service (SMS)
Turn around time (TAT)

A B S T R A C T

Background: The issue of laboratory critical value (CV) reporting has gained importance in the recent
times due to the national focus on patient safety. Critical value notification (CVN) has become an essential
part of accreditation procedures for medical laboratories, including the universally accepted International
Organization for Standardization (ISO) 15189: 2012.
Aims and Objectives: Our study aimed to analyze the critical value data in hematology and biochemistry
sections of the laboratory, to compare the frequencies of critical values for different parameters and to
suggest measures for improving the effectiveness and operational efficiency of the critical value notification
process.
Materials and Methods: Our study was a retrospective, cross-sectional, descriptive study done over a
period of one year six months (January 2020 to June 2021). The parameters chosen for CVN included
platelets, hemoglobin and International Normalized Ratio (INR) from hematology section and creatinine,
glucose, sodium, potassium and calcium from the biochemistry section. A test result that was significantly
outside the normal range and that required immediate communication was considered as a “critical
value (CV)”. Both verbal (through telephone) and non-verbal [through short message service (SMS)]
communication processes for CVN were implemented in our lab. We also followed the practice of CV
“read-back” by the person who was informed over the phone.
Results: A total of 2199 critical values were reported. A maximum of 1224 (55.7%) critical values were
recorded from the emergency department. CVs were highest from biochemistry (1898, 86.3%) section.
Analyte most commonly notified was creatinine (1151, 52.3%). CVNs were maximum in the morning
shifts (1378, 62.7%).
Conclusions: Implementation of the critical alert short message service (SMS) send outs has greatly helped
us in reducing the CV turn around time (TAT). Our study has successfully demonstrated the importance of
both verbal and non-verbal communication processes for notification of CVs.

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1. Introduction

The identification and timely communication of critical
values are still considered as essential elements of good
laboratory performance. The issue of laboratory critical
value (CV) reporting has gained importance in the recent

* Corresponding author.
E-mail address: drshubhahv@gmail.com (Shubha H.V).

times due to the increasing focus on patient safety
worldwide. Critical value notification (CVN) has become
an integral part of accreditation procedures for medical
laboratories, including the universally agreed International
Organization for Standardization (ISO) 15189: 2012. 1 CVN
is of utmost importance to instantly communicate the CVs to
clinicians for faster diagnostic approach and quick changes
in the patient management decisions. The Joint Commission

https://doi.org/10.18231/j.pjms.2022.081
2249-8176/© 2022 Innovative Publication, All rights reserved. 430



Shubha H.V / Panacea Journal of Medical Sciences 2022;12(2):430–435 431

(JC) defines a critical test as “a test that requires immediate
communication of result irrespective of whether it is normal,
significantly abnormal or critical”. 2 This definition is also
shared by many other organizations such as the Clinical
and Laboratory Standards Institute (CLSI) and the Royal
College of Pathologists (RCP). 3,4 Critical value is instead
defined by the JC as “a test result that is significantly
outside the normal range and may represent life-threatening
values”. 2 In small laboratories, the selection of critical
value limit ranges, preparation of a standard list or target
turn around time (TAT) for reporting of critical results is
very difficult due to the absence of consensus in laboratory
community. 5 It is, therefore, important that the laboratories
must make an agreement on the list of parameters and
the critical value limits of each of them, which should be
established and followed by each laboratory. This helps
in eliminating the problem of diluting the urgency of the
critical value call due to expansion of critical call out lists. 5,6

The College of American Pathologists (CAP) checklist
states about the importance of documentation that the CV
results have been notified to caregivers. Moreover, the CAP
COM.30100 states that electronic transmission of CVs is
acceptable. The laboratories must confirm the receipt of
CV result by the intended recipient and no read back is
required. 7

2. Aims and Objectives

1. To analyze the critical value (CV) data in hematology
and biochemistry sections of the laboratory.

2. To compare the frequencies of critical values for
different parameters.

3. To suggest measures for improving the effectiveness
and operational efficiency of the critical value
notification (CVN) process.

3. Materials and Methods

The present study was of a retrospective, cross-sectional,
descriptive design spanning over a period of one year six
months (January 2020 to June 2021). In the present study we
aimed to analyze the critical value data in the hematology
and biochemistry sections of our laboratory and compare
the frequencies of critical values for different parameters.
A total of 75,156 tests were performed during the study
period. The test requests were received from out-patient
departments (OPD) which included master health checkups,
in-patient departments [Intensive care units (ICUs), wards
and operation theatres] and emergencies. Out of 75,156
tests, 16530 and 20638 tests were from hematology and
biochemistry sections respectively. A total of 2199 critical
values were reported from these two sections.

3.1. Critical value notification process

The list of parameters from hematology and biochemistry
sections which were selected for the critical value
notification (CVN) and also their critical value limit
ranges were developed after discussing with the treating
physicians, surgeons, ICU and emergency doctors as
per their requirements for management of patients.
Accordingly, the parameters which were selected by the
laboratory for CVN included platelets, hemoglobin and
International Normalized Ratio (INR) from hematology
section and creatinine, glucose, sodium, potassium and
calcium from the biochemistry section.

The analytical reliability of CVs were checked and then
after ruling out the pre-analytical errors, the laboratory
technologists ensure the validation of the result by repetition
of test or by recalibration of the parameter if necessary
and/or by checking the quality control (QC) results. Once
the result is validated, and it is in the critical range (upper
or lower), the laboratory technologists notify the value
to the responsible caregiver (treating physicians, surgeons,
ICU/ emergency doctors, nursing staff or the consultants)
telephonically and at the same time the result is also entered
in the critical value call out log sheet. Details such as
the accession number, parameter, care area, person’s name
who informs the critical value, person’s name to whom the
critical value is notified, contact number, date and time of
call out, the examination result conveyed with the measuring
unit and reference range, examination result confirmed by
“read back” are entered.

Laboratory also follows the practice of CV “read-back”
by the person who was informed over the phone. The critical
value call out log is then signed by the laboratory head/
pathologist in-charge.

In order to facilitate and speed up the process of CVN
especially of the OPD patients, we also have developed
an in-house Laboratory Information System (LIS) software
which automatically flags the test results requiring CVN as
the critical value limit ranges of the parameters requiring
CVN are tagged with the LIS. Short message service (SMS)
are sent to the concerned treating doctors whose phone
numbers are linked with the LIS. We also can monitor
whether the SMS is forwarded or failed to the responsible
caregivers. In case, if the SMS is not forwarded, then the
lab technologist notifies the CV to the concerned caregiver
telephonically and enters the details in the critical call out
log sheet.

3.2. Statistical analysis

The obtained parameters were evaluated using the
descriptive statistical analysis. The statistical analyses were
done using the IBM SPSS (Statistical Package for the Social
Sciences v 20.0) and Microsoft Office Excel 2007 software.



432 Shubha H.V / Panacea Journal of Medical Sciences 2022;12(2):430–435

4. R esults

The present study was a retrospective study conducted in
the hematology and biochemistry sections of laboratory at
Fortis multispeciality hospital, Bangalore. The lab received
blood samples from out-patient departments (OPDs)
including master health checkups, in-patient departments
[Intensive care units (ICUs), wards and operation theatres
(OTs)] and emergencies. A total of 2199 critical values were
reported by the lab. A maximum of 1224 (55.7%) critical
values were recorded from the emergency department
followed by IPD (900, 40.9%) and OPD (75, 3.4%)
departments (Table 1).

A total of 75,156 tests were performed in the lab
over a period of one year and six months (January 2020
to June 2021). The parameters which were selected by
the laboratory for CVN were platelets, hemoglobin and
International Normalized Ratio (INR) from hematology
section and creatinine, glucose, sodium, potassium and
calcium from the biochemistry section. The critical value
limit ranges of different parameters are shown in Table 2.

Out of 75,156 tests, hematology tests constituted a total
of 16,530 (21.9%) and biochemistry tests accounted for
20,638 (27.4%). Out of 16,530 hematology tests, platelets,
hemoglobin and INR together accounted for 13696 tests
and out of 20,638 biochemistry tests, creatinine, glucose,
sodium, potassium and calcium accounted for 15,566 tests.

Critical values constituted 2.92% of the total test results
(75,156) reported by the lab.

Majority of the critical values were resulted in the
biochemistry (1898, 86.3%) section. Hematology accounted
for only 13.7% (301 test results) of the critical alert values
(Table 3). The analytes most commonly notified for critical
value were creatinine (1151, 52.3%), followed by potassium
(350, 16%), sodium (200, 9.1%), glucose (167, 7.6%) and
platelets (165, 7.5%) (Table 3). Critical value notifications
were maximum in the morning shifts (1378, 62.7%) and
minimum in the night shifts (100, 4.5%) (Figure 1).

The following measures were implemented in our
laboratory for improving the effectiveness and operational
efficiency of the critical value notification process:

1. An in-house Laboratory Information System (LIS)
software was developed which automatically flags the
test results requiring CVN and sends short message
service (SMS) to the concerned caregivers. We also
monitored whether the SMS was forwarded or failed
to the responsible caregivers. In case, if the SMS
was not forwarded, then the lab technologist notified
the CV to the concerned caregiver telephonically
and also entered the details in the critical call out
log sheet. Implementation of the critical alert short
message service (SMS) send outs to deliver the CVs
greatly helped us in reducing the CV turn around time
(TAT) especially in the out-patient department area.

Electronic communication of CVs also has avoided the
possible errors in communication and has shortened the
notification times.

2. Incorporating the mechanism of delta checks (i.e.,
to detect any change in the present test result from
previous results) into LIS which serves as a second
flagging layer, in addition to an electronic critical value
alert.

3. Training the laboratory staff for the policy of
laboratory critical value notification process and
documenting the same in the log sheets.

4. Long and complex list of critical values were avoided
and a concise list was prepared as increased number
of calls may weaken the urgency of critical value call
leading to unnecessary interference for clinicians.

5. The established list of critical values were regularly
reviewed, revised and updated in consultation with the
clinicians.

Fig. 1: Distribution of critical value data in each shift

5. Discussion

The present study was conducted over a period of one
year six months (January 2020 to June 2021). A total of
75,156 tests were performed during the study period. The
critical value notification was highest in the emergency area
(55.7%). Majority of the critical values were resulted in the
biochemistry (1898, 86.3%) section. Hematology accounted
for only 13.7% (301 test results) of the critical alert values.
The analytes most commonly notified for critical value
were creatinine (1151, 52.3%), followed by potassium
(350, 16%), sodium (200, 9.1%), glucose (167, 7.6%) and
platelets (165, 7.5%).Table 4 shows the comparison of
frequencies of critical values of our study with that of the
others. Thus, this study focusses on the need for analysing
the critical value frequencies in laboratories to identify the
parameters with highest critical values. Laboratories must
list out the parameters for CVN and set the CV limit ranges
in consultation with the clinicians. This helps to modify
clinical management of the patients and thus can be very
useful for both clinicians and patients. Moreover, this will



Shubha H.V / Panacea Journal of Medical Sciences 2022;12(2):430–435 433

Table 1: Distribution of the critical values byclinical care areas.
Clinical care area Total no. of critical values Percentage
OPD with master health check ups 75 3.4
IPD (ICU, wards, OTS) 900 40.9
Emergency 1224 55.7
Total 2199 100

Table 2: List of critical value limit ranges of different parameters in hematology and biochemistry sections.
S.No. Parameter Lower limit Upper limit

Hematology
1. Platelets 40,000/cumm 10,00,000/cumm
2. Hemoglobin 6.0 g/dl 20 g/dl
3. INR >5

Biochemistry
1. Creatinine >3.0 mg/dl
2. Glucose 50 mg/dl 400 mg/dl
3. Sodium 120 mEq/L 160mEq/L
4. Potassium 2.5 mmol/L 6.0 mmol/L
5. Calcium 6.5 mg/dl 13.0 mg/dl

Table 3: Distribution of critical values for different parameters tested
S.No. Parameter Total test

volume
Critical test

results
Percentage of

critical test results
Percentage of test volume

with a critical result
Hematology
1. Platelets 5580 165 7.5 2.95
2. Hemoglobin 4916 66 3.0 1.34
3. INR 3200 70 3.2 2.18
Total hematology 13696 301 13.7
Biochemistry
1. Creatinine 8428 1151 52.3 13.65
2. Glucose 3421 167 7.6 4.88
3. Sodium 1678 200 9.1 11.91
4. Potassium 1704 350 16.0 20.53
5. Calcium 335 30 1.3 8.95
Total Biochemistry 15566 1898 86.3
Total 29262 2199 100

serve as an important tool to initiate a healthy interaction
between the clinicians and the laboratory staff and in turn,
will prove beneficial in the long term. 8

Appropriate and timely management of patients largely
depends on the clinical communication. Ambiguous
communication or failure to communicate on time can
cause delayed treatment and also the patient’s safety is
threatened. 11 Numerous reports have proved the ability of
information technology to speed up the process of critical
value reporting. 12,13 Automatic communication with the
responsible provider due to increasing use of information
technology (IT) has proved to reduce the CV reporting
time. In a study conducted by Lynn TJ et al., in order to
improve communication between clinical providers and the
laboratory, the secure text messaging (STM) for CVN was
implemented. 14 In our study too, the use of SMS to deliver
CVs was efficient and reliable. Our results are consistent
with the study conducted by Lynn TJ et al., that employed

technology to automate the CVN process.
An electronic reporting system potentially could create

dangerous delays in communication if not properly put
into use. The system needs to have an “acknowledgment”
function such that the laboratory can ensure that the
responsible caregiver received the result. Electronic systems
also require an intense procedure so that lack of
acknowledgment of the critical test result elicits an
alternative way for communication. 5 In the present study,
we monitored whether the SMS was forwarded or failed
to the responsible caregivers. In case, if the SMS was not
forwarded, then the lab technologist notified the CV to the
concerned caregiver telephonically and entered the details
in the critical call out log sheet.

One of the major challenges in CVN process lies in the
OPD area because unlike inpatients, there is no fixed patient
location to which the CV can be telephonically notified.5

Introduction of critical alert SMS send outs in OPD cases



434 Shubha H.V / Panacea Journal of Medical Sciences 2022;12(2):430–435

Table 4: Table showing comparison of our study with other studies
S. No. Study Duration Total

tests
Total
no. of

critical
values

Percent-
age of
critical

values to
total tests

Sections
included

No. of
analyt-es

Analyte with
highest frequency

1. Namrata
Bhutani et

al. 8

2
months

183056 11875 6.5 Emergency
biochemistry

8 (in
adults)

Potassium
(2933,8.3%)

2. Desai KN et
al. 9

24
months

90,000 19423 21.6 Hematology (H)
and Clinical

pathology (CP)

H-9 CP-2 Hematology-
Hemoglobin (5212,
26.8%) CP- Urine

ketone bodies
(3100, 16.0%)

3. Dighe AS et
al. 5

12
months

14000000 37503 0.25 Biochemistry
(BC) and

Hematology (H)

BC-14 H-6 BC-Potassium
(7955, 21.2%)

H-Partial
thromboplastin

time (PTT) (5467,
14.6%)

4. Agarwal R et
al. 10

25
months

478,980 1187 0.25 Clinical
chemistry

6 Sodium (249,
20.97%)

5. Present study 18
months

75,156 2199 2.92 Biochemistry
(BC) and

Hematology (H)

BC- 5 H-3 BC- Creatinine
(1151, 52.3%)

H-Platelets (165,
7.5%)

has helped a lot to inform the CV to the concerned doctor
in our study. Telephonic communication of the CV to
the clinicians definitely has reduced the time needed for
diagnosis and to commence treatment, hence decreasing the
associated morbidity and mortality.

It was also observed that the CVNs were highest in the
morning shifts (1378, 62.7%) and minimum in the night
shifts (100, 4.5%). This may be attributed to the increased
test volume during the peak working hours in mornings and
active communication process due to increased number of
technical staffs in the morning shifts. Similar findings were
observed in a study by Desai KN et al. 9

This study has also emphasized on the measures to
improve the CVN process. Agarwal R et al. have highlighted
on the importance of CVN policy which includes list of
parameters for which CV should be notified, laboratory staff
responsible for notifying CV and the person to whom CV
will be notified, TAT and the communication method. They
have also mentioned about the maintenance of a log book for
the same. 10 In the present study too we gave importance on
maintaining the critical call out logsheets which had similar
details as mentioned by Agarwal R et al.

In a study by Saffar H et al., it was suggested that
routine repeat of hematology and biochemistry critical
test result was not necessary and it may adversely affect
the patient safety measure. 15 CVN process implemented
through a well-planned approach, rather than a commitment
for clinical laboratories, is a right for the patient in order
to ensure safety. It also plays a pivotal role in healthcare

systems and has proved to be both cost saving and life
saving. 16

6. Conclusion

The efficient and timely communication of critical test
results is an essential responsibility of laboratories.
Information technology (IT) is increasingly becoming
an essential component of medical laboratories, thus
unwinding interesting perspectives also for the immediate
communication with the clinicians. The critical value
notification was highest in the emergency area (55.7%)
and in the biochemistry section (86.3%) in our study.
Implementation of the critical alert short message service
(SMS) send outs to deliver the CVs has greatly helped
us in reducing the CV turn around time especially in the
out-patient department area. Our study has successfully
demonstrated the importance of both verbal and non-verbal
communication processes for notification of CVs. It has also
highlighted on the significance of employing innovative new
measures to improve the CVN process.

7. Source of Funding

No financial support was received for the work within this
manuscript.

8. Conflict of Interest

The authors declare they have no conflict of interest



Shubha H.V / Panacea Journal of Medical Sciences 2022;12(2):430–435 435

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Author biography
Shubha H.V, Assistant Professor

Cite this article: Shubha H.V. A study of critical value analysis at
hematology and biochemistry sections of laboratory in a multispeciality
hospital. Panacea J Med Sci 2022;12(2):430-435.

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