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Reliability of Transcutaneous Bilirubin Devices inPreterm Infants: A Systematic Review
abstractBACKGROUND AND OBJECTIVE: Transcutaneous bilirubin (TcB) devicesare widely used for the estimation of serum bilirubin levels in term andnear-term infants. Our objective was to review the diagnostic accuracyof TcB devices in preterm infants.
METHODS: Medline, Embase, Cochrane library, Cumulative Index toNursing and Allied Health Literature, and Scopus were searched (fromdatabase inception date until December 2012). Additional citationswere identified by using the bibliographies of selected articles andfrom conference proceedings. The studies were included if theycompared TcB with total serum bilirubin in preterm infants beforephototherapy and presented data as correlation coefficients or as Bland-Altman difference plots. Data were extracted by 1 reviewer and checkedfor accuracy by the second reviewer. An assessment tool (qualityassessment of diagnostic accuracy studies) was used for risk of biasassessments.
RESULTS: Twenty-two studies met the inclusion criteria; 21 studiesreported results as correlation coefficients, with pooled estimatesof r = 0.83 for each site of measurement. Pooled estimates ininfants ,32 weeks’ gestation were similar to the overall pretermpopulation (r = 0.89 [95% confidence interval: 0.82–0.93]). For the 2commonly used TcB devices (ie, JM103 and BiliCheck), the resultswere comparable at the forehead site, although the JM103 deviceexhibited better correlation at the sternum. Analysis of the Bland-Altman plots (13 studies) revealed negligible bias in measurementat the forehead or sternum site by using either the JM-103 orBiliCheck device; however, the JM-103 device exhibited betterprecision than the BiliCheck (SD for TcB – total serum bilirubindifferences: 24.3 and 31.98 mmol/L, respectively).
CONCLUSIONS: The TcB devices reliably estimated bilirubin levels inpreterm infants and could be used in clinical practice to reduce bloodsampling. Pediatrics 2013;132:871–881
AUTHORS: Gaurav Nagar, MD,a Ben Vandermeer, MSc,b
Sandra Campbell, MLS,c and Manoj Kumar, MD, MSca
aDivision of Neonatology, Department of Pediatrics, bAlbertaResearch Center for Health Evidence, and cJohn W. Scott HealthSciences Library, University of Alberta, Edmonton, Alberta,Canada
KEY WORDSBland-Altman difference plots, correlation coefficient, meta-analysis, systematic review, transcutaneous bilirubin
ABBREVIATIONSCI—confidence intervalr—correlation coefficientTcB—transcutaneous bilirubinTSB—total serum bilirubin
Dr Nagar contributed to all stages of the review and wrote thefirst draft of the manuscript; Mr Vandermeer providedstatistical support to the project and helped with data analysis;Ms Campbell was involved with the planning and conducting ofthe literature search for this study; and Dr Kumar contributed toall stages of the review and reviewed all drafts of themanuscript. All authors approved the final manuscript assubmitted.
www.pediatrics.org/cgi/doi/10.1542/peds.2013-1713
doi:10.1542/peds.2013-1713
Accepted for publication Aug 21, 2013
Address correspondence to Manoj Kumar, MD, MSc (ClinicalEpidemiology), Department of Pediatrics, Edmonton ClinicalHealth Academy, Room 3-528, 11405 87 Ave NW, Edmonton, AB,Canada T6G 1C9. E-mail: [email protected]
PEDIATRICS (ISSN Numbers: Print, 0031-4005; Online, 1098-4275).
Copyright © 2013 by the American Academy of Pediatrics
FINANCIAL DISCLOSURE: The authors have indicated they haveno financial relationships relevant to this article to disclose.
FUNDING: Dr Nagar was supported by a postgraduate traineegrant from the Women and Children’s Health Research Instituteat the University of Alberta, Edmonton, Alberta, Canada.
POTENTIAL CONFLICT OF INTEREST: The authors have indicatedthey have no potential conflicts of interest to disclose.
PEDIATRICS Volume 132, Number 5, November 2013 871
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Jaundice is common in the newbornperiod, with a majority of neonatesdeveloping visible jaundice within thefirst few days of birth.1,2 In a significantproportion, this development does notpossess any risks to the newborn;however, up to 10% of term and 25% ofnear-term neonates develop significantserum bilirubin levels requiring treat-ment.3 Optimal diagnosis and manage-ment of neonatal hyperbilirubinemiarequire clinical examination and esti-mation of serum bilirubin. On clinicalexamination, the newborn jaundice isnoted to have cephalocaudal pro-gression.4 However, visual assessmentof serum bilirubin has been shown tocorrelate poorly with measured bili-rubin levels in recent studies.2,5,6 Bloodsampling for estimation of serum bili-rubin is one of the most common testsordered in the neonatal units. Theblood sampling is often done by heelprick and is painful, with potential long-term consequences.7
Transcutaneous bilirubin (TcB) devicesestimate serumbilirubin noninvasively.These devices work by directing lightinto the skin of the neonate and mea-suring the intensity of specific wave-lengths returned.8 The number ofwavelengths varies depending on theTcB device. These devices have beenshown to correlate well with serumbilirubin levels in term and near-terminfants.9–13 The American Academy ofPediatrics recommends the use of TcBdevices for the evaluation of jaundicein infants .35 weeks’ gestation.14
Hyperbilirubinemia in preterm infantsis more prevalent, more severe, and itscourse more protracted than in termneonates,15 likely from slower post-natal maturation of hepatic bilirubinuptake and conjugation mechanisms.16
In addition, delay in initiation of enteralfeedings may limit intestinal motilityand bacterial colonization, resulting inenhancement of bilirubin enterohepaticcirculation. Although the existing
guidelines allow use of TcB devices forthe evaluation of jaundice in term andnear-term neonates,14 the accuracy ofTcB devices for estimation of serumbilirubin in preterm infants remainsunclear.
The objective of the current systematicreview was to assess the diagnosticaccuracy of TcB devices compared withthe total serum bilirubin (TSB) mea-surement in preterm infants during theneonatal period.
METHODS
Search and Selection
Weexecuted a sensitive search strategyof the following databases: Medline,Embase, Cochrane library, CumulativeIndex to Nursing and Allied Health Lit-erature, and Scopus (from the date ofinception of the database to December2012) by using both Medical SubjectHeadings and key words such as: ((expInfant, Newborn/ or exp Intensive CareUnits, Neonatal/ or exp Neonatal Nurs-ing/ or nicu.mp. or exp Infant, Newborn,Diseases/ or exp Infant, Premature/ orneonat*.mp. or exp Neonatal Screening/or exp Premature Birth/ or pre-term.mp. or preterm*.mp. or post-term*.mp.) and (bilitest* or bilimed* or biliblitz*or bilicheck* or bilichek* or tcbr or
icterometer* or bilirubinometer*).mp.and ((exp Hyperbilirubinemia, Neo-natal/ or (bilirubin* or hyperbilirubin*).ti,ab. or exp Hyperbilirubinemia, He-reditary/ or exp Jaundice, Neonatal/)and transcutaneous* or non-invasive*or noninvasiv* or minolta or skin* ortissue).mp.)) and ((blood or capillar* orplasma* or prick* or “heel poke*”or serum or tsbr or tsb).mp. or expBlood/or exp Capillaries/ or exp Serum/or exp Plasma/)). Additional terminol-ogy and predefined database limitswere added to restrict the referencesto those related to infants ,1 monthof age. English language restrictionwas applied. Conference proceedingsand bibliographies of included stud-ies were searched for additionalstudies.
Studies were included in the review ifthey enrolled preterm (,37 weeks’gestation) infants and compared TcBresults with TSB estimation during theneonatal period. We excluded pilotstudies (defined a priori as those en-rolling #20 subjects), studies enroll-ing preterm infants along with terminfants if they did not provide separatepreterm data, and studies evaluatingTcB devices in subjects receiving pho-totherapy (Supplemental Information).
FIGURE 1Flow of studies through the selection process.
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TABLE1
Characteristicsof
theIncluded
Studies
Author
(Reference),Year
PopulationCharacteristics;
Ethnicity
M/N
TcBSite
TcB:Device
ComparisonMethod
TSB:Method
Maximum
Interval
BetweenTests,min
Comments
Badiee
etal21(2012)
Iran;Persian
63/63
FBiliCheck
r,BA
DS10
Separatedataprovided
for#30
wk
(18infants)and.30
wk(45
infants)GA
GA(range):25–33
wk
Ahmed
etal20(2010)
UnitedKingdom;m
ixed
ethnicity
183/57
FBiliCheck
r,BA
Diazo
15–30
Results
for1assessmentpersubject
also
provided
GA(range):26–34
wk
Siuetal34(2010)
Hong
Kong;Chinese
110/30
F,S
JM-103
r,BA
DS10
110measurementsateach
site
GA(range):27–34
wk
Stillovaetal36(2009)
Slovakia;w
hite
32/32
F,S,A
JM-103
r,BA
DS10
32measurementsat
each
site
GA(range):25–31
wk
Schm
idtetal33(2009)
UnitedStates;m
ixed
ethnicity
131/90
SJM
-103
r,BA
Diazo
45Results
for1assessmentpersubject
also
provided
GA(3
subgroups):
24–28
wk
39/30
29–31
wk
43/29
32–34
wk
49/31
Karenetal26(2009)
Switzerland;m
ixed
68/51
SBilim
edr,BA
Diazo
15Studyalso
enrolledterm
infants;
show
nhere
aredatafor
preterminfants
GA(2
subgroups):
28–33
wk
21/13
34–36
wk
47/38
Namba
andKitajim
a29(2007)
Japan;Japanese
351/50
FJM
-103
rDS
60Allsubjectshadbirthweight,1500
gGA:,
34wk
Stillovaetal35(2007)
Slovakia;w
hite
44/44
F,S,A
JM-103
r,BA
DS10
44measurementsat
each
site
GA(range):32–34
wk
DeLuca
etal23(2007)
Italy;ethnicitynotmentioned
340/340
FBiliCheck
r,BA
DS10
GA(range):30–36
wk
SanpavatandNuchprayoon3
2(2007)
Thailand;ethnicitynotm
entioned
249/196
FJM
-103
r,BA
DS60
GA(range):30–35
wk
Jangaard
etal25(2006)
Canada;m
ajority
white
65/33
FBiliCheck
BADS
TcBmeasuredbefore
orsoon
afterTSB
Studyhadmultiplegroups;datashow
nhere
areforpreterminfantsnot
receivingphototherapy
GA(range):notstated
Mean6
SD:30.86
2.5wk
Nanjundasw
amyetal31(2005)
UnitedStates;ethnicitynotmentioned
70/70
FBiliCheck
rDS
30Show
nhere
areprephototherapydata
GA(range):25–35
wk
Willem
setal39(2004)
Holland;m
ajority
white
93/24
FBiliCheck
r,BA
Diazo
30Agreem
entstatistic
provided
basedon
1datasetp
ersubject
GA(range):26–29
wk
Szaboetal37(2004)
Switzerland;m
ajority
white
107/69
F,S
BiliCheck
JM-102
r,BA
DSTSBmeasured
soon
afterTcB
107measurementsateach
sitewith
Bilicheck
device.JM-102
onlytested
atsternum(107
measurements)
GA(range):34–36
wk
S
Karolyietal27
(2004)
Germ
any;ethnicity
notmentioned
212/124
SJM
-102
rDiazo
10Allsubjectshadbirth
weight,
1500
g(VLBW)
GA(range):23–33
wk
Yasuda
etal40(2003)
Japan;ethnicity
notm
entioned
75/24
FJM
-103
r,BA
DS30
Studyalso
enrolledterm
infants;data
show
nhere
areforpreterminfants
GA(range):27–36
wk
JM-102
Knüpferetal28(2001)
Germ
any;majority
white
245/135
FBiliCheck
rDiazo
60Datashow
nhere
areforpreterm
infantsnotreceiving
phototherapy
GA(range):23–36
wk
Bhutanietal9(2000)
UnitedStates;m
ixed
ethnicity
163/45
FBiliCheck
rHPLC
30Studyalso
enrolledterm
infants;data
show
nhere
areforpreterminfants
GA(range):35–36
wk
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The outcome of interest was agree-ment statistic between TcB and TSBmeasurements, provided either as thecorrelation coefficient or as the meanand SDs of absolute difference plots(Bland-Altman difference plots).17
Data Extraction and Assessment ofRisk of Bias
Titles, abstracts, and citations wereindependently assessed by 2 reviewersfor inclusion based on predefined se-lection criteria. Data from includedstudies were extracted on a specificallydesigned data extraction form by 1reviewer and checked for accuracy by asecond reviewer. Risk of bias assess-ments were conducted according tothe QUADAS-2 tool.18 This tool consistsof 4 key domains: patient selection,index test, reference standard, andflow and timing. Each study is as-sessed for risk of bias in each of thedomains and for concerns regardingapplicability in the first 3 domains.Disagreements were resolved by con-sensus among the members of the re-view team.
Data Analysis
A meta-analysis was performed on theavailabledata fromboth thecorrelationcoefficients between measurements ofTcB and TSB and the Bland-Altman dif-ference plots. All correlationswerefirstconverted to Fisher z scores beforebeing pooled. The resulting pooledFisher z scores were then transformedback into standard correlation coef-ficients for ease of interpretation. ForBland-Altman difference plots, we pooledthe mean TcB – TSB differences andvariance across eligible studies for esti-mation of bias and SDs, respectively, byusing methods as described by Peytonand Chong.19
A priori subgroup analyses were plan-ned toexplore the influenceof the siteofTcB measurement and the type of TcBdevice used. Data pertaining to all TcBTA
BLE1
Continued
Author
(Reference),Year
PopulationCharacteristics;
Ethnicity
M/N
TcBSite
TcB:Device
ComparisonMethod
TSB:Method
Maximum
Interval
BetweenTests,min
Comments
DonzelliandPratesi24
(2000)
Italy;Caucasian
82/51
SJM
-102
rDS
10Show
nhere
areprephototherapy
data;study
also
provides
data
foroneassessmentp
ersubject
GA(range):24–36
wk
Bhardw
ajetal22(1989)
India;ethnicity
notm
entioned
90/30
FMinolta
Air-Shields
bilirubinmeter
rDS
TCBandTSBmeasured
atthesametim
eThestudyhad3
equalgroupsof
10subjectseach
with
3readingpersubject
GA:,
37wk(range
notstated):3
subgroupswith
meanGA
of29.2,33.2,and35.1wk
TanandMylvaganam
38(1988)
Singapore;Chinese
614/40
F,S
Minolta
Air-Shields
bilirubinmeter
rDS
TSBmeasuredsoon
aftertheTcB
614measurementsateach
site
GA:M
ean6
SD:29.96
2.9wk
Palmer
etal30(1982)
Australia;ethnicitynotm
entioned
(fair-skinnedinfants)
30/30
S,A
Minolta
bilirubinmeter
rDiazo
Notm
entioned
Studyalso
enrolledterm
infants;
datashow
nhere
areforpreterm
infantsnotreceivingphototherapy.
Thirtymeasurementsateach
site
GA:,
37wk
A,abdomen;BA,Bland-Altm
andifferenceplots;DS,directspectrophotom
etry;F,forehead;GA,gestationalage;HPLC,high-perform
ance
liquidchromatography;M,totalnumberofpaired
measurements;N,num
berofsubjects;S,sternum
;VLBW,verylow
birthweight.
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devices were included for most of theanalyses; however, for comparison ofindividual TcB devices, we restrictedour analyses to the 2 commonly useddevices in current clinical practice (ie,JM-103 and BiliCheck). Additional sen-sitivity analyseswereplanned toassessthe accuracy of TcB devices in infants,32 weeks’ gestational age and forsingle measurements per enrolledsubject data.
Meta-analyses were performed by us-ing Review Manager Version 5.2 soft-ware (The Nordic Cochrane Centre, TheCochrane Collaboration, 2011; Copen-hagen, Denmark). I2 statistic was cal-culated for each analysis to quantifyheterogeneity across studies. Forestplots were created by using SPlusSoftware version 3.4 (TIBCO SoftwareInc, Palo Alto, CA).
RESULTS
We identified 22 studies9,20–40 providing3527 paired measurements of TcB and
TSB in 1628 patients who fulfilled theinclusion criteria (Fig 1). The baselinecharacteristics of the included studiesare presented in Table 1. Studies variedin terms of the gestational age of theparticipants (23–36 weeks); site of TcBmeasurement (forehead: 16 studies;sternum: 10 studies; abdomen: 3 stud-ies); TcB device used (BiliCheck: 9studies; JM-103: 7 studies; JM-102: 4studies; other devices: 4 studies);method used for serum bilirubin mea-surement (direct spectrophotometry:14 studies; Diazo method: 7 studies;high-performance liquid chromatogra-phy: 1 study); and agreement statisticused for comparison (correlation co-efficient: 21 studies; Bland-Altman dif-ference plots: 13 studies [with 12studies reporting results by bothmethods]).
Results for risk of bias assessments onthe included studies are provided inTable 2. Using the QUADAS-2 tool, themajority of the included studies wereassessed as low risk for bias with
respect to patient selection, index test,reference standard, and flow and tim-ing. Most studies conducted the TcBand TSB estimations within a short in-terval of time (within #30 minutes: 17studies [77%]; within 1 hour: 21 studies[95%]). For applicability, 3 studies22,30,38
were assessed as high risk for appli-cability concerns as an index test be-cause the TcB devices used in thosestudies are no longer used in clinicalpractice.
Meta-analysis of CorrelationCoefficients
Twenty-one studies9,20–24,26–40 providedresults for correlation coefficients, andthe pooled estimates according to thesite of measurement were as follows:forehead9,20–23,28,29,31,32,34–40 (16 stud-ies): 0.83 (95% confidence interval [CI]:0.80–0.86); sternum24,26,27,30,33–38 (10studies): 0.83 (95% CI: 0.76–0.87); andabdomen30,35,36 (3 studies): 0.83 (95%CI: 0.72–0.90) (Fig 2). There were nosubgroup differences with respect to
TABLE 2 Risk of Bias Assessments of the Included Studies
Author (Year) Risk of Bias Applicability Concerns
PatientSelection
IndexTest
ReferenceStandard
Flow andTiming
PatientSelection
IndexTest
ReferenceStandard
Badiee et al21 (2012) ✓ ✓ ✓ ✓ ✓ ✓ ✓
Ahmed et al20 (2010) ✓ ? ✓ ✓ ✓ ✓ ✓
Siu et al34 (2010) ? ? ✓ ? ✓ ✓ ✓
Stillova et al36 (2009) ✓ ? ? ✓ ✓ ✓ ✓
Schmidt et al33 (2009) ✓ ? ? ✓ ✓ ✓ ✓
Karen et al26 (2009) ✓ ? ✓ ✓ ✓ ✓ ✓
Namba and Kitajima29 (2007) ✓ ✓ ✓ ✓ ✓ ✓ ✓
Stillova et al35 (2007) ✓ ? ✓ ✓ ✓ ✓ ✓
De Luca et al23 (2007) ✓ ✓ ✓ ✓ ✓ ✓ ✓
Sanpavat and Nuchprayoon32
(2007)✓ ? ✓ ✓ ✓ ✓ ✓
Jangaard et al25 (2006) ✓ ✓ ✓ ✓ ✓ ✓ ✓
Nanjundaswamy et al31 (2005) ✓ ✓ ✓ ✓ ✓ ✓ ✓
Willems et al39 (2004) ✓ ? ✓ ✓ ✓ ✓ ✓
Szabo et al37 (2004) ✓ ? ✓ ✓ ✓ ? ✓
Karolyi et al27 (2004) ✓ ? ✓ ✓ ✓ ? ✓
Yasuda et al40 (2003) ✓ ✓ ✓ ✓ ✓ ? ✓
Knüpfer et al28 (2001) ✓ ? ✓ ✓ ✓ ✓ ✓
Bhutani et al9 (2000) ✓ ? ✓ ✓ ✓ ✓ ✓
Donzelli and Pratesi24 (2000) ? ✓ ✓ ✓ ✓ ? ✓
Bhardwaj et al22 (1989) ? ✓ ✓ ✓ ✓ X ✓
Tan and Mylvaganam38 (1988) ✓ ? ✓ ✓ ✓ X ✓
Palmer et al30 (1982) ✓ ✓ ✓ ✓ ✓ X ✓
✓, low risk; X, high risk; ?, unclear risk.
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site of TcB measurement. There wassignificant heterogeneity noted in thepooled estimates from the foreheadand sternum sites. In predefined sen-sitivity analysis, when data for a singlemeasurement per enrolled subjectwere used for analysis, the pooledestimates were no more heteroge-neous (forehead site: 0.83 [95% CI:0.79–0.85], I2 = 16%; sternum site: 0.87[95% CI: 0.81–0.90], I2 = 42%) (Fig 3).
Figure 4 shows the meta-analysisresults of correlation coefficients forthe 2 most widely used devices in cur-rent clinical practice. For the BiliCheckdevice, 8 studies9,20,21,23,28,31,37,39 pro-vided data for correlation coefficients(all measured at the forehead site ex-cept for 1 study, which also provided
data for the sternum site),37 and thepooled estimate was 0.83 (95% CI: 0.77–0.88) for measurement at the foreheadcompared with 0.77 (95% CI: 0.68–0.84)at the sternum. For the JM-103 device, 7studies provided data for correlationcoefficients, and the pooled estimatefor measurement at the forehead sitewas 0.85 (6 studies29,32,34–36,40 [95% CI:0.80–0.89]) and for the sternum site, itwas 0.87 (4 studies33–36 [95% CI: 0.82–0.91]).
Figure 5 shows pooled estimates from5 studies20,21,33,36,39 that provided sep-arate data for infants ,32 weeks’gestation. The results show a trendtoward a slightly better correlationcoefficient (r = 0.89 [95% CI: 0.82–0.93])than overall estimates in the preterm
population with no significant het-erogeneity noted. Two of these stud-ies provided separate data forsubjects #28 weeks’ gestation andreported correlation coefficients of0.92 (Schmidt et al33) and 0.94 (Ahmedet al20).
Bland-Altman (TcB – TSBDifferences) Plot Analysis
Thirteen studies20,21,23,25,26,32–37,39,40
provided results as an analysis of theBland-Altman difference plots. Thestudies were published between theyears 2003 and 2012, and the majorityused either JM-103 (6 studies) or Bili-Check (6 studies) devices except forthe study by Karen et al,26 whichused Bilimed. In addition, 2 studies
FIGURE 2Pooled estimates of correlation coefficients according to the site of TcB measurement.
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FIGURE 3Pooled estimates of correlation coefficients from the studies reporting data for a single reading/subject.
FIGURE 4Pooled estimates of correlation coefficients for the BiliCheck and JM-103 devices.
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evaluated the JM-102 device along withthe BiliCheck and JM-103.37,40 The re-sults of TcB – TSB differences, alongwith their SDs for individual studies,are listed in Table 3.Table 4 shows pooled data for the biasestimates and precision according tothe study characteristics. The biasestimates were negligible at both the
forehead and the sternum sites, witha comparable precision noted acrossboth sites (pooled estimate of SD atforehead: 29.46 mmol/L; pooled esti-mate of SD at sternum: 26.06 mmol/L).In terms of devices used, the 2 com-monly used TcB devices showed com-parable bias; however, the JM-103 wasnoted to be more precise compared
with the BiliCheck (pooled estimate ofSD: 24.3 and 31.98mmol/L, respectively).
DISCUSSION
We identified a large number of studiesevaluating the diagnostic accuracy ofvarious TcB devices in a pretermpopulation. The results of this reviewfound that TcB measurements corre-late reasonably well with the serumbilirubin estimation in prematureinfants, particularly for the 2 widelyused TcB devices in practice (ie, Bili-Check and JM-103). The accuracy ofthese 2 devices was similar for themeasurement at the forehead site;however, JM103 exhibited better cor-relation with TSB for measurement atthe sternum (P = .02). The analysis ofabsolute TcB – TSB difference plotsrevealed minimal bias in measure-ments, irrespective of the site and thedevice used, although the JM103 de-vice showed a slightly better precisioncompared with the BiliCheck device.When the data from subjects born at#32 weeks’ gestation were analyzedseparately, the results were compa-rable to the diagnostic accuracy in theoverall preterm population.
To the best of our knowledge, this is thefirst systematic review looking at the
FIGURE 5Pooled estimates of correlation coefficients for studies reporting data for infants ,32 weeks’ gestation.
TABLE 3 Results of Bland-Altman Difference Plots for the Studies Providing Those Data
Study TcB Device Measurements/No. of Subjects
Biasa
(mmol/L)Precision(SD)
Site of measurement: foreheadBadiee et al21 2012 BiliCheck 63/63 7.4 25.7Ahmed et al20 2010 BiliCheck 183/57 28.08 31.26Siu et al34 2010 JM-103 110/30 9.3 27.1Stillova et al36 2009 JM-103 32/32 5.1 6.8Stillova et al35 2007 JM-103 44/44 222.4 4.2De Luca et al23 2007 BiliCheck 340/340 218.1 34.2Sanpavat and Nuchprayoon32 2007 JM-103 249/196 5.1 25.7Jangaard et al25 2006 BiliCheck 65/33 23.8 33.57Willems et al39 2004 BiliCheck 93/24 24.92 27.15Szabo et al37 2004 BiliCheck 107/69 28 33Yasuda et al40 2003 JM-103 75/24 7.48 27.2Yasuda et al40 2003 JM-102 75/24 17.1 35.2
Site of measurement: sternumSiu et al34 2010 JM-103 110/30 20.1 27.6Stillova et al36 2009 JM-103 32/32 12 6.8Schmidt et al33 (24–28 wk) 2009 JM-103 39/30 218.7 32.3Schmidt et al33 (29–31 wk) 2009 JM-103 43/29 213.6 22.1Schmidt et al33 (32–34 wk) 2009 JM-103 49/31 217 27.2Karen et al26 (28–33 wk) 2009 Bilimed 21/13 28 38Karen et al26 (34–36 wk) 2009 Bilimed 47/38 16 45.5Stillova et al35 2007 JM-103 44/44 1.7 5.4Szabo et al37 2004 BiliCheck 107/69 10 31Szabo et al37 2004 JM-102 107/69 56 28
a TcB – TSB difference.
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diagnostic accuracy of TcB devices ina preterm population. We presentpooled data for bias and precisionestimates along withthe more com-monly usedmeasure of the correlationcoefficient, as the latter typicallydescribes the strength of a relationbetween 2 variables rather than agree-ment between them.17 Thus, the clinicalutility of correlation coefficient data islimited because they intuitively do notprovide information regarding expecteddifferences between the measurementsconducted on a given patient by 2 sep-arate tests.
The pooled estimates of bias noted herearecomparable to theaccuracyof thesedevices in a term population,41–44 inwhom the use of these devices hasbeen shown to result in a marked de-crease in blood sampling for assess-ment of neonatal jaundice.45,46 However,there is a lower threshold for the initi-ation of phototherapy for preterminfants, with certain guidelines pro-viding specific cutoffs for each gesta-tional week according to the postnatalage.47 Thus, the information from thissystematic review should be incor-porated in clinical practice, taking intoconsideration the thresholds for pho-totherapy in preterm infants. In ouropinion, based on the data presentedhere, a TcB reading$50 mmol/L belowthe phototherapy threshold foran infant
could be considered safe for not ini-tiating phototherapy in an otherwisewell preterm, without the need for TSBestimation from the laboratory. Simi-larly, a TcB reading above the photo-therapy threshold may be sufficientgrounds to initiate phototherapywithout the invasive test in most sit-uations. The latter recommendation ismade despite knowing that some ofthese infants may be classified as be-low the phototherapy threshold basedon TSB results because those infantsare still likely to be reasonably close tothe threshold.
Our review is not without limitations.First, we were unable to include a fewstudies that enrolled preterm infantsalong with the term infants. Thesestudies did not provide comparisondata for preterm populations sepa-rately in their publication and uponcontacting the principal author of thestudy. The majority of these excludedstudies enrolled near-term infants inwhom the accuracy of TcB devices isnot debated. Second, the estimatesprovided for the very preterm pop-ulation are based on limited data. Al-though several studies enrolledsubjects #32 weeks’ and #28 weeks’gestation, only a few studies providedcomparison data separately for thesesubpopulations. However, it is reas-suring that the estimates for these
subpopulations were comparable tothe overall estimates in the pretermpopulation. Third, several of the in-cluded studies also provided results ofthe relationship between TcB and TSBas a linear equation with slope andintercept. We did not pool results ofthese data because it would be difficultto interpret such information in clinicalpractice. Fourth, we did not includestudies that provided data for infantsunder phototherapy or postphototherapy.Thus, the results of our review cannotbe applied to those situations. Fifth,we did not apply a formal test tocheck for publication bias; however,the funnel plot of the included studiesdid not reveal any obvious asymmetrysuggestive of missing studies withpoor correlation coefficients. Lastly,several of the studies included in themeta-analysis provided multiple read-ings from each patient enrolled, leadingto the statistical risks of dependency ofdata. We separately compiled studiesthat provided results for 1 data point foreach subject for our sensitivity analysis(Fig 3). The results were similar to theoverall results with no significant het-erogeneity noted.
CONCLUSIONS
The results of this systematic reviewfound that the currently available TcBdevices, particularly JM-103 and Bili-Check, measure TSB values in pretermpopulations with reasonable accuracy,including in infants ,32 weeks’ ges-tational age. The performance of thesedevices in preterm populations issimilar to those in term and near-terminfants. Incorporating the use of TcBdevices in clinical practice, as per oursuggestions outlined here, could helpreduce the need for blood sampling forthe management of neonatal jaundicein preterm infants. The results of thisreview do not apply to preterm infantsundergoing phototherapy or post-phototherapy.
TABLE 4 Pooled Estimates of Bias and Precision for Studies Reporting Data as Bland-AltmanDifference Plots
Variable No. ofStudies
No. ofMeasurements
No. ofSubjects
Biasa
(mmol/L)Precision(SD)
According to site ofmeasurementb
Forehead 11 1361 912 20.06 29.46Sternum 5 424 265 3.8 26.06
According to device usedJM-103 6 827 522 3.14 24.30Bilicheck 6 958 655 1.10 31.98
,32-wk GAdata
4 303 170 1.57 26.86
GA, gestational age.a TcB – TSB difference.b Analysis restricted to data from JM-103 and BiliCheck devices.
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GENES AND OBESITY: A friend of mine has wrestled with being overweight foryears. She is very careful about her diet, exercises maniacally, and limits heralcohol consumption. Despite these efforts, her BMI has always been . 30. Herweight does not seem to be related to lack of self-control and is not easily un-derstood. My friend’s weight problems may be due to her genes.As reported in The New York Times (July 19, 2013), researchers have known fora long time that some aspects of weight gain are hereditary. Twins raised aparttend to have the same weight, while adopted children tend to have the body massof the biologic parents, not their adopted parents. Evidence has accumulated overtime to suggest that dozens of genes may be involved in increasing appetite, andnew research suggests that at least one gene is associated not only with appetitebut with a change in mammalian metabolic rate.The investigators developed knockoutmice deficient in brain- and body-expressed“melanocortin receptor accessory protein 2” (MRAP2). When allowed to eat asmuch food as desired, the MRAP2 deficient mice were voracious and quicklybecame extremely obese. When MRAP2 deficient mice were fed the same numberof calories as normalmice however, only theMRAP2 deficientmice became obese.The MRAP2 mice had to be fed 10% to 15% fewer calories in order to demonstratethe same weight gain as their normal siblings. How MRAP2 controls weight gainis not entirely understood, but researchers suspect that MRAP2 regulates“melanocortin 4 receptor” (Mc4r), a protein previously implicated in mammalianobesity. Without MRAP2 production, appropriate appetite and energy metabolismregulated by Mc4r is impaired. Interestingly, four children in a registry of 500severely obese children were found to have alterations in the MRAP2 gene whilenone of the healthy controls in the same study did.While still very preliminary, researchers are now looking for alterations in theMRAP2 gene that could lead to partial expression and hence, explain some of thevariance in weight gain among people consuming the same number of calories.While it will not helpmy friend loseweight, I think shewill appreciate learning thatobesity is not always about loss of self-control.
Noted by WVR, MD
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Reliability of Transcutaneous Bilirubin Devices in Preterm Infants: A Systematic
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