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Risk Stratification in the Prevention of PC-AKI

Beoordeeld: 01-12-2024

Uitgangsvraag

Hoe dienen kinderen die verhoogd risico lopen op post-contrast acuut nierletsel (PC-AKI) te worden geïdentificeerd?

Aanbeveling

Bepaal niet routinematig de nierfunctie bij gezonde kinderen die niet tot een risicopopulatie behoren.

 

Bepaal de nierfunctie (eGFR met behulp van de gemodificeerde Schwartz formule) voorafgaand aan het onderzoek met intraveneuze jodiumhoudende contrastmiddelen:

 

Bij kinderen met bekende nierziekte of nierfunctie stoornis

EN

Bij kinderen die tot een veronderstelde hoog risico groep voor PC-AKI behoren:

  • Doorgemaakte nierziekte,
  • Voorgeschiedenis van AKI,
  • Congenital anomalies of the kidney and urinary tract (CAKUT),
  • Voorgeschiedenis van Prematuriteit < 32 weken,
  • Trisomie 21,
  • Gebruik van nefrotoxische en renale perfusie beïnvloedende medicatie (ACEi, ARB (angiotensine receptor blokker), NSAIDs),
  • Hypovolemie / bedreigde circulatie (bijvoorbeeld sepsis/ shock),
  • Diabetes mellitus.

Wees in deze verhoogd risico populatie alert op nierfunctieproblemen en bepaal de nierfunctie (eGFR). Bij een stabiele kliniek is een bepaling tot 3 maanden voor het beeldvormend onderzoek geldig.

 

Afspraken na beeldvorming

Bereken de eGFR met behulp van de modified Schwarz formule: lengte (cm) x 36.5 / serum kreatinine (micromol/L) binnen 2 tot 7 dagen na intravasculaire jodiumhoudende CM-toediening bij elke patiënt met eGFR < 30 voor het onderzoek.

 

Indien er PC-AKI wordt gediagnostiseerd (volgens Kidney Disease Improving Global Outcomes criteria), vervolg de patiënt tot normalisatie van serum creatinine naar baseline en consulteer een kindernefroloog.

 

Gemodificeerde Schwartz formule: lengte (cm) x 36.5 / serum creatinine (micromol/L).

In kinderen met een lage spiermassa (bijvoorbeeld eetstoornis of cerebrale parese) kan de uitkomst van de formule incorrect zijn en dient overlegd te worden met een kinderarts/nefroloog.

Overwegingen

Pros and cons of the intervention and quality of the evidence

The guideline development group conducted a systematic review of the increased risk for developing PC-AKI or complications related to PC-AKI after contrast exposure in children with prematurity, trisomy 21, diabetes mellitus, congenital anomalies of the kidney and urinary tract (CAKUT), renovascular medication or nephrotoxic medication. One article (Cantais, 2016) examined risk factors for developing PC-AKI. However, the evidence was of too low quality (very low GRADE) to draw a conclusion. No articles describing complications of PC-AKI met the inclusion criteria. Therefore, no conclusions could be drawn about the effects of these risk factors on the development of PC-AKI and complications related to PC-AKI (hospitalization, dialysis). A knowledge gap exists on this topic.

 

Multiple studies did not meet the inclusion criteria. Most of these studies were excluded based on wrong design, comparing contrast exposure to non-contrast exposure, where our PICO is aimed at identifying risk factors in contrast exposed groups only. These studies report low incidences of PC-AKI. McDonald (2018) published a cohort study on postcontrast acute kidney injury in pediatric patients, reporting a low rate of contrast associated AKI (3,3%) with no observed difference between contrast and noncontrast groups following propensity score analysis in a small sample with low rates of PC-AKI. Gilligan (2020) published similar results (PC-AKI 2.4%) in a cohort study in hospitalized children using propensity score analysis with no noticeable difference between exposed and non-exposed children in a small sample with low rates of PC-AKI.

Calle-Toro (2022) published a retrospective cohort study in children undergoing CT scans with or without contrast media. They reported a PC-AKI incidence of 1.4% after contrast exposure, showing a difference in risk between contrast exposed and non-contrast exposed groups only in children with an eGFR < 60 prior to imaging.

 

The quality of the evidence from the systematic literature search is too low to draw a conclusion, the recommendations in this national guideline are based mainly on the guideline for PC-AKI risk stratification and stratification tools in adults (NVVR, 2017) when applicable. The low reported PC-AKI incidence in children in combination with the low prevalence of kidney disease in children however requires a different approach then mentioned in the guideline for adults. Based on expert opinion we describe the main differences below.

 

The vast majority of children that are scheduled for IV contrast-enhanced studies have no medical history, (past) use of nephrotoxic medication, or hypovolemia. This patient group can safely be scheduled for imaging without renal function testing and/or prehydration strategies.

 

The minority of children that are scheduled for studies with IV contrast media with known renal disease (including Congenital Anomalies of the Kidney and Urinary Tract or CAKUT) OR a medical history associated with an elevated risk of renal disease, including prematurity and use of renovascular or nephrotoxic medication, should have renal function tests performed (eGFR calculated using serum creatinine (in micromol/L) and patients height (in cm). Also euvolemia / adequate circulation should be guaranteed prior to imaging. In case of impaired renal function, prehydration strategies should be performed. An eGFR based on a serum creatinine sample within the last 3 months before imaging is considered valid, when the child is well appearing, in a stable condition and with no recent changes in his/her medical condition and medication. This is based on common practice in the absence of relevant articles/studies on this topic, in line with similar recommendations in, for example, the ESUR guidelines on contrast agents.

 

Patient (and their caretakers) values and preferences

Patients, parents/caretakers, and health care professionals like to make decisions based on the best available evidence. A similar case should get equal advice/treatment.

This guideline defines a patient group with an increased risk of PC-AKI. Patients at increased risk and their caretakers should be informed about the options available to them and together with their physician decide on risk reducing measures and alternative imaging modalities. The exact options will depend on many different factors such as type of examination and reason for performing a scan.

This guideline helps in identifying a population with an elevated risk, thereby reducing the chance of unnecessary tests and interventions.

 

Costs

Cases of PC-AKI are associated with additional healthcare costs both in the short and long term. Currently physicians are likely to be very careful in children and thus order additional diagnostic tests and interventions. The recommendations in this guideline can prevent unnecessary diagnostic tests and interventions, while simultaneously preventing unnecessary incidents of PC-AKI.

 

Acceptability, feasibility and implementation

The guideline development group does not anticipate any acceptance issues. The recommendations in the current guideline address longstanding uncertainty about the need for diagnostic testing and interventions. Therefore, it will contribute to a more unified and equal approach in children.

 

Rationale of the recommendation: weighing arguments for and against the interventions

We present a simple and uniform strategy to identify children at increased risk of developing PC-AKI. Children with known kidney disease are at risk and require renal function monitoring in the form of serum creatinine up to three months after contrast administration. We also identify an increased risk population where kidney problems may arise, and serum creatinine should be measured to determine renal function. This strategy should enable us to limit testing to a well-defined subgroup of patients, preventing unnecessary testing and costs. Since there are limited studies in children, the strategy is based mainly on evidence in adult populations as described in the guideline for PC-AKI risk stratification and stratification tools in adults (NVVR, 2017), supplemented by expert opinion to incorporate important difference in children. For instance, the lower prevalence of kidney disease led to no further action for children with no medical history, (past) use of nephrotoxic medication or hypovolemia. Based on the adult guideline we recommend testing for renal impairment prior to imaging. Based on expert opinion we limit this testing to a well-defined population at risk for renal impairment.

Onderbouwing

Intravascular iodine-based contrast media could lead to PC-AKI in certain cases, especially when renal function is already impaired. At the moment there is no routine screening for impaired renal function in children exposed to intravenous contrast media as part of diagnostic or therapeutic imaging (for instance by measurement of serum creatinine or determination of Glomerular Filtration Rate or eGFR).

There are certain risk factors that may indicate renal dysfunction that worsens after administration of intravenous contrast media. These risk factors include children with Down syndrome (trisomy 21), diabetes mellitus, prematurity or congenital anomalies of the kidney and urinary tract (CAKUT) as well as the use of renovascular or nephrotoxic medication. It is unclear whether screening for impaired renal function is necessary in children at increased risk of renal dysfunction. 

Very low GRADE

The evidence is very uncertain about the identification of risk factors for PC-AKI in children (<18 years of age) undergoing radiological examinations with intravascular iodine-based contrast media.

Source: Cantais, 2016

 

 

 

- GRADE

No evidence was found regarding risk factors for complications of PC-AKI in children (<18 years of age) undergoing radiological examinations with intravascular iodine-based contrast media.

Description of studies

Cantais (2016) published a retrospective chart review study of contrast-induced acute kidney injury (CI-AKI) incidence, risk factors and impact in paediatric patients (<16 years). CI-AKI is a specific term used to describe a sudden deterioration in kidney function that is caused by the administration of an iodine-based contrast medium; therefore, it is a subgroup of PC-AKI (see the chapter PC-AKI: Definities, terminologie en klinisch verloop in the guideline Veilig gebruik van contrastmiddelen (NVVR, 2017)). The authors defined AKI, in accordance with the KDIGO classification system, as a serum creatinine (SCr) increase of ≥26.4 micromol/L within 48 h or of ≥150 % from baseline presumed to have occurred within the prior 7 days or as oliguria (urine output of <0.5 ml/kg/h for ≥6 h). Baseline renal function was based on the baseline Cr and estimated glomerular filtration rate at the time of contrast media injection; any degree of AKI within 48 h was considered contrast-associated nephropathy. 346 paediatric patients received an iodine-based contrast media injection as part of a CT scan between January 2005 and September 2014. 233 patients had renal function assessment before and following contrast media injection and were included in the analysis. Median patient age was 5.9 years with an CI-AKI incidence of 10.3% (95%CI: 6.4 to 14.2%). There were few patients with comorbidities that could be potential risk factors, including thirteen patients with prematurity, eight with pre-existing chronic kidney disease, two with a history of glomerular disease without renal dysfunction and no patient with diabetes. The authors did report extracting information about trisomy 21 or congenital anomalies of the kidney Guideline Safe Use of Contrast Media part 4 Guideline for Authorisation phase June 2024 27 and urinary tract (CAKUT) from the charts. Vasopressor medication was used in 14 of 233 patients (6%). Nephrotoxic medication use (non-steroidal anti-inflammatory drugs (NSAIDs), aminoglycosides, starches or iodine-based contrast media within 72h) was more common, occurring in 83 of 233 patients (36%). To identify risk factors for CI-AKI conditional forward logistic regression analyses were performed. The model included clinically relevant variables and variables yielding a P value of ≤0.20 in a bivariate analysis, the latter being maintained in the final model. Authors tested for co-linearity and interactions as well as assessing goodness of fit of the logistic regression with the Hosmer-Lemeshow test.

 

Results

PC-AKI

In Cantais (2016), 24 of 233 included patients (10.3 %; 95%CI 6.4 to 14.2%) developed CI-AKI. Nine of these 24 (38 %) had no previous history of chronic kidney disease, concomitant use of nephrotoxic agents or hypovolemia. Conditional forward logistic regression analysis found no factors independently associated with CI-AKI (Table 1).

 

Table 1. Odds ratio (OR) and 95% confidence interval (95%CI) from forward conditional logistic regression analysis of factors associated with CI- AKI (Cantais 2016).

 

OR

95%CI

Hypovolemia or shock at contrast-media infusion

1.98

0.78 to 5.05

Underlying chronic kidney disease

3.16

0.53 to 18.6

Cumulative number of nephrotoxic agents

 

 

  None

Reference group

 

  1

0.93

0.32 to 2.68

  ≥2

3.63

0.86 to 15.40

 

Complications of PC-AKI

No studies describing complications of PC-AKI were included in the analysis of the literature.

 

Level of evidence of the literature

PC-AKI

The level of evidence regarding the outcome measure PC-AKI started as GRADE low due to the observational nature of the included study (Cantais, 2016), and was downgraded by one level to very low due to the small number of included patients (imprecision).

 

Complications of PC-AKI

The level of evidence could not be determined as no studies describing complications of PC-AKI were included in the analysis of the literature.

A systematic review of the literature was performed to answer the following question: Do prematurity, trisomy 21, diabetes, CAKUT, renovascular medication, or nephrotoxic medication increase the risk of developing PC-AKI in children receiving intravenous contrast media?

 

P(atients): Children (<18 years) receiving intravascular iodine-based contrast media.
I(ntervention): Risk factors: prematurity, trisomy 21, diabetes, congenital anomalies of the kidney and urinary tract (CAKUT), renovascular medication, nephrotoxic medication.
C(ontrol): Absence of these risk factors.
O(utcome): 

Post-contrast acute kidney injury (PC-AKI), complications of PC-AKI (hospitalization, start of dialysis).

 

Relevant outcome measures

The guideline development group considered PC-AKI and complications of PC-AKI as critical outcome measures for decision making.

 

A priori, the guideline development group did not define the outcome measures listed above but used the definitions used in the studies. The guideline development group defined PC-AKI as described in the chapter PC-AKI: Definities, terminologie en klinisch verloop in the guideline Safe Use of Contrast Media, part 1 (NVVR, 2017). If authors used other definitions such as CA-AKI (contrast associated) or CI-AKI (contrast induced). We used their terminology for the description of the study, but for the purposes of the guideline standardized to PC-AKI.

 

The guideline development group defined the following as a minimal clinically (patient) important difference:

• Post-contrast acute kidney injury (PC-AKI): relative risk <0.91 or >1.10. Guideline Safe Use of Contrast Media part 4 Guideline for Authorisation phase June 2024 26

• Complications of PC-AKI (hospitalization, start of dialysis): relative risk <0.91 or >1.10.

 

Search and select (Methods)

The databases Medline (via OVID) and Embase (via Embase.com) were searched with relevant search terms from 1990 until 27-03-2023. The detailed search strategy is depicted under the tab Methods. The systematic literature search resulted in 210 hits.

 

Studies were selected based on the following criteria:

• Systematic review, randomized controlled trial or observational research comparing risk factors to absence of risk factors for the risk of PC-AKI in children receiving intravascular iodine-based contrast.

• Children (<18 years) who underwent radiological examination using intravascular iodine-based contrast media (including radiological examination during percutaneous angiography).

• Potential risk factors related either to patient characteristics and/or treatment characteristics and/or iodine-based contrast medium characteristics were studied in how they influenced the risk of PC-AKI.

• Risk factors were corrected for confounders in multivariable models.

• At least one of the outcome measures was described: PC-AKI, complications of PCAKI (hospitalization, start of dialysis, mortality).

 

Eight studies were initially selected based on title and abstract screening. After reading the full text, 7 studies were excluded (see the table with reasons for exclusion under the tab Methods), and 1 study was included.

 

Results

One study by Cantais (2016) was included in the analysis of the literature. Important study characteristics and results are summarized in the evidence tables. The assessment of the risk of bias is summarized in the risk of bias tables.

  1. Cantais, A. and Hammouda, Z. and Mory, O. and Patural, H. and Stephan, J. L. and Gulyaeva, L. and Darmon, M. Incidence of contrast-induced acute kidney injury in a pediatric setting: a cohort study. Pediatric Nephrology. 2016; 31 (8) :1355-1362.
  2. McDonald, J. S. and McDonald, R. J. and Tran, C. L. and Kolbe, A. B. and Williamson, E. E. and Kallmes, D. F. Postcontrast Acute Kidney Injury in Pediatric Patients: A Cohort Study. American Journal of Kidney Diseases. 2018; 72 (6) :811-818
  3. Gilligan, L. A. and Davenport, M. S. and Trout, A. T. and Su, W. and Zhang, B. and Goldstein, S. L. and Dillman, J. R. Risk of Acute Kidney Injury following Contrast-enhanced CT in Hospitalized Pediatric Patients: A propensity score analysis. Radiology. 2020; 294 (2) :548-556
  4. Calle-Toro, J. and Viteri, B. and Ballester, L. and García-Perdomo, H. A. and White, A. and Pradhan, M. and Otero, H. J. Risk of Acute Kidney Injury Following Contrast-enhanced CT in a Cohort of 10?407 Children and Adolescents. Radiology. 2022; :210816
  5. NVvR, 2017. Richtlijn Veilig gebruik van contrastmiddelen - Module Risicostratificatie en stratificatietools. Beoordeeld: 01-11-2017. 

Evidence table for intervention studies (randomized controlled trials and non-randomized observational studies [cohort studies, case-control studies])

 

Research question: Do prematurity, trisomy 21, diabetes, CAKUT, renovascular medication and nephrotoxic medication increase the risk of developing PC-AKI in children receiving contrast?

 

Study reference

Study characteristics

Patient characteristics 2

Intervention (I)

Comparison / control (C) 3

 

Follow-up

Outcome measures and effect size 4

Comments

Cantais, 2016

Type of study: retrospective chart review study

 

Setting and country: hospital France

 

Funding and conflicts of interest: Study was supported by a grant from the French Intensive Care Society. No conflicts of interest were reported by the authors.

Inclusion criteria: children (< 16 years) receiving iodine-based contrast media injection as part of a CT scan between January 2005 and September 2014.

 

Exclusion criteria:

Missing renal function assessment before or following contrast media injection.

 

N total at baseline:

233

 

Important prognostic factors2:

Age (interquartile range):

I: 8.3 (1.2-13.2)

C: 6.1 (2.1-14.3)

 

Sex:

I: % M 19 (79.1%)

C: % M 123 (58.9%)

 

Groups comparable at baseline?

No retrospective study without matching on patient characteristics.

 

Describe intervention (treatment/procedure/test):

 

To identify risk factors for contrast-induced acute kidney injury (CI-AKI) and unfavourable outcome, conditional forward logistic regression analyses were performed. The model included clinically relevant variables and variables yielding a P value of ≤0.20 in bivariate analysis, the latter being maintained in the final model. Variables under consideration were:

-age

-gender

-comorbidities (prematurity, chronic heart failure, chronic kidney disease, history of glomerulopathy),

- baseline renal function (cGFR, creatinine),

- exposure to nephrotoxic agents (non-steroidal anti-inflammatory drugs (NSAIDs), aminoglycosides, starches or iodine-based contrast media within 72h)

- Unit of hospitalization (medical ward, surgical ward, intensive care unit (ICU), emergency department)

- CT scan indication (surgical assessment, cancer, malformation, epilepsy, thromboembolism)

- Hemodynamic status and need for organ support (nonsevere sepsis, severe sepsis, hemmorrhage, miscellaneous hypovolemia, need for mechanical ventilation, vasopressors)

 

 

 

Describe control (treatment/procedure/test):

 

Absence of the variables described in the intervention column.

 

Length of follow-up:

Unclear, outcome reported at day 30. So at least 30 days.

 

Loss-to-follow-up or incomplete outcome data:

Not applicable, retrospective chart review where only participants with sufficient information to calculate the outcome of interest were included. Authors excluded participants missing renal function assessment before or following contrast media injection (113 patients, 12 (10.6%) with an unfavourable outcome).

 

 

Outcome measures and effect size:

 

For both outcomes conditional forward logistic regression analyses were performed with clinically relevant variables and variables yielding a P value of ≤0.20 in bivariate analysis.

 

PC-AKI

AKI was defined as a serum creatinine (SCr) increase of ≥26.4 μmol/L within 48 h or of ≥150 % from baseline presumed to have occurred within the prior 7 days or as oliguria (urine output of <0.5 ml/kg/h for ≥6 h).

 

The final model included three factors:

Hypovolemia or shock at contrast- media infusion OR=1.98 (95%CI 0.78-5.05)

Underlying chronic kidney disease OR=3.16 (95%CI 0.53-18.6)

Cumulative number of nephrotoxic agents with no use as reference. For one nephrotoxic agent OR= 0.93 (95%CI 0.32-2.68). For ≥2 OR= 3.63 (95%CI 0.86-15.40).

 

Complications PC-AKI

Authors assessed whether patients had an unfavourable outcome at day 30 (rehospitalization within 30 days, ICU admission within 30 days or mortality).

In the CI-AKI -group 11 out of 24 patients (45.8%) and in the no CI-AKI-group 41 out of 209 patients (19.7%) had an unfavourable outcome within 30 days. After adjustment for confounders, unfavourable outcome was associated with severe sepsis or septic shock at the time of CT scan (OR 3.5; 95%CI 1.5 to 7.8), younger age (OR per year 0.89; 95%CI 0.84 to 0.95), and contrast-associated nephropathy (OR 3.6; 95%CI 1.4 to 9.5).

The authors did not identify independent risk factors of CI-AKI. CI-AKI is associated with poorer outcome, including a higher rehospitalization rate. Identification of risk factors and prognostic impact was a secondary objective for this study.

 

The authors mention several study limitations:

1.  The population was heterogeneous, which may have limited the precision of the results and the ability to detect risk factors (a secondary outcome).

2. The Definition used is highly sensitive which may explain the high incidence of CI-AKI.

3. The retrospective design precluded adequate assessment of adherence to preventive measures or of the influence of these measures in preventing CI-AKI.

4. Unable to assess AKI duration, as several patients had unrecognized AKI and were discharged before renal dysfunction recovery.

5. High exclusion rate due to the absence of renal assessment following contrast media injection. One third of children exposed to contrast media had no renal function assessment or follow-up.

 

Risk of bias table for interventions studies (cohort studies based on risk of bias tool by the CLARITY Group at McMaster University)

Author, year

Selection of participants

 

Was selection of exposed and non-exposed cohorts drawn from the same population?

 

 

 

 

 

 

 

 

Exposure

 

 

Can we be confident in the assessment of exposure?

 

 

 

 

 

 

 

 

 

Outcome of interest

 

Can we be confident that the outcome of interest was not present at start of study?

 

 

 

 

 

 

 

Confounding-assessment

 

Can we be confident in the assessment of confounding factors? 

 

Confounding-analysis

 

Did the study match exposed and unexposed for all variables that are associated with the outcome of interest or did the statistical analysis adjust for these confounding variables?

 

Assessment of outcome

 

Can we be confident in the assessment of outcome?

 

 

 

 

 

 

 

 

 

Follow up

 

 

Was the follow up of cohorts adequate? In particular, was outcome data complete or imputed?

 

 

 

 

 

 

 

 

 

 

Co-interventions

 

Were co-interventions similar between groups?

 

 

 

 

 

 

 

 

 

 

Overall Risk of bias

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Definitely yes, probably yes, probably no, definitely no

Low, Some concerns, High

Cantais, 2016

Definitely yes

 

Reason: Participants were selected from an electronic hospital registry.

Probably yes

 

Reason: based on (retrospective) chart extraction.

Definitely yes

 

Reason: participants without baseline measurements for renal function were excluded.

Probably no

 

Reason: unclear how the authors determined which information to extract from charts and thus which confounders were considered.

Probably no

 

Reason: although stated that analyses were adjusted for confounding, it is unclear which variables were taken into account in the multivariate analysis.

Probably no

 

Reason: the retrospective study design had a high dropout rate related to the absence of renal assessment following contrast media injection. One third of children exposed to contrast media had no renal function assessment or follow-up. It is not known how these excluded patients might have influenced the CI-AKI incidence in the studied population.

Definitely no

 

Reason: Follow up was too short for the outcome complication PC-AKI to occur (some patients had unrecognized AKI and were discharged before renal dysfunction recovery).

For PC-AKI, it was enough.

No information

High (PC-AKI)

High (Complications PC-AKI)

 

Table of excluded studies

Reference

Reason for exclusion

Calle-Toro, J. and Viteri, B. and Ballester, L. and García-Perdomo, H. A. and White, A. and Pradhan, M. and Otero, H. J. Risk of Acute Kidney Injury Following Contrast-enhanced CT in a Cohort of 10 407 Children and Adolescents. Radiology. 2022; :210816

wrong design (comparing contrast exposure to non-contrast exposure, PICO about risk factors in contrast exposed group)

Gilligan, L. A. and Davenport, M. S. and Trout, A. T. and Su, W. and Zhang, B. and Goldstein, S. L. and Dillman, J. R. Risk of Acute Kidney Injury following Contrast-enhanced CT in Hospitalized Pediatric Patients: A propensity score analysis. Radiology. 2020; 294 (2) :548-556

wrong design (comparing contrast exposure to non-contrast exposure, PICO about risk factors in contrast exposed group)

McDonald, J. S. and McDonald, R. J. and Tran, C. L. and Kolbe, A. B. and Williamson, E. E. and Kallmes, D. F. Postcontrast Acute Kidney Injury in Pediatric Patients: A Cohort Study. American Journal of Kidney Diseases. 2018; 72 (6) :811-818

wrong design (comparing contrast exposure to non-contrast exposure, PICO about risk factors in contrast exposed group)

Niboshi, A. and Nishida, M. and Itoi, T. and Shiraishi, I. and Hamaoka, K. Renal function and cardiac angiography. Indian Journal of Pediatrics. 2006; 73 (1) :49-53

wrong design (description renal function, not about risk factors)

Young J, Dahale D, Demmel K, O'Brien M, Geller J, Courter J, Haslam DB, Danziger-Isakov L, Goldstein SL. Reducing acute kidney injury in pediatric oncology patients: An improvement project targeting nephrotoxic medications. Pediatr Blood Cancer. 2020 Aug;67(8):e28396. doi: 10.1002/pbc.28396. Epub 2020 Jun 3. PMID: 32495508.

wrong exposure (nephrotoxic medication with contrast as one of the medications, not nephrotoxic medication as a risk factor when exposed to contrast)

He, F. and Zhang, J. and Lu, Z. Q. and Gao, Q. L. and Sha, D. J. and Pei, L. G. and Fan, G. F. Risk factors and outcomes of acute kidney injury after intracoronary stent implantation. World Journal of Emergency Medicine. 2012; 3 (3) :197-201

wrong population (adults)

Buyan, N. and Arab, M. and Hasanoglu, E. and Gokcora, N. and Ercan, S. The effects of contrast media on renal function in children: comparison of ionic and non-ionic agents. Turkish Journal of Pediatrics. 1995; 37 (4) :305-13

wrong intervention (different risk factors); wrong outcome (measures GFR and urine markers, but not PC-AKI); wrong design (outcomes in high risk group not reported because of insufficient numbers)

 

Autorisatiedatum en geldigheid

Laatst beoordeeld  : 01-12-2024

Laatst geautoriseerd  : 01-12-2024

Geplande herbeoordeling  : 01-12-2027

Validity

The Radiological Society of the Netherlands (NVvR) will determine if this guideline (per module) is still valid and applicable around 2029. If necessary, the scientific societies will form a new guideline group to revise the guideline. The validity of a guideline can be shorter than 5 years, if new scientific or healthcare structure developments arise, asking for a revision of the guideline. The Radiological Society of the Netherlands is the owner of this guideline and therefore primarily responsible for the actuality of the guideline. Other scientific societies that have participated in the guideline development share the responsibility to inform the primarily responsible scientific society about relevant developments in their field.

Initiatief en autorisatie

Initiatief:
  • Nederlandse Vereniging voor Radiologie
Geautoriseerd door:
  • Nederlandse Vereniging voor Anesthesiologie
  • Nederlandse Vereniging voor Heelkunde
  • Nederlandse Vereniging voor Kindergeneeskunde
  • Nederlandse Vereniging voor Radiologie
  • Stichting Kind en Ziekenhuis

Algemene gegevens

General Information

The Kennisinstituut van de Federatie Medisch Specialisten assisted the guideline development group. The guideline was financed by Stichting Kwaliteitsgelden Medisch Specialisten (SKMS) which is a quality fund for medical specialists in The Netherlands.

Samenstelling werkgroep

A multidisciplinary guideline development group (GDG) was formed for the development of the guideline in 2022. The GDG consisted of representatives from all relevant medical specialization fields which were using intravascular contrast administration in their field.

 

All GDG members have been officially delegated for participation in the GDG by their scientific societies. The GDG has developed a guideline in the period from June 2022 until July 2024. The GDG is responsible for the complete text of this guideline.

 

Guideline development group

  • de Graaf N. (Nanko), chair guideline development group, radiologist, Erasmus Medical Center, Rotterdam
  • Den Dekker M.A.M. (Martijn), radiologist, Ziekenhuis ZorgSaam
  • Emons J.A.M. (Joyce), paediatric allergist, Sophia Children’s Hospital, Erasmus Medical Center, Rotterdam
  • Geenen R.W.F. (Remy), radiologist, Noordwest Ziekenhuisgroep, Alkmaar
  • Jöbsis, J.J. (Jasper), paediatrician and nephrologist, Onze Lieve Vrouwe Gasthuis, Amsterdam
  • Liebrand C.A. (Chantal), anaesthesiologist, Erasmus Medical Centre, Rotterdam
  • Sloots C.E.J. (Pim), surgeon, Erasmus Medical Centre, Rotterdam
  • Zwaveling-Soonawala N. (Nitash), paediatrician -endocrinologist, Amsterdam University Medical Center, Amsterdam.

Advisory group

  • Doganer E.C. (Esen), Kind & Ziekenhuis, Patient representative
  • Riedijk M.A. (Maaike), paediatrician and intensive care physician, Emma Hospital, Amsterdam University Medical Centre
  • Van der Molen A.J. (Aart), radiologist, Leiden University Medical Centre, Leiden

Methodological support

•          Houtepen L.C. (Lotte), advisor, Knowledge Institute of the Federation Medical Specialists

•          Mostovaya I.M. (Irina), senior advisor, Knowledge Institute of the Federation Medical Specialists

Belangenverklaringen

Conflicts of interest

The GDG members have provided written statements about (financially supported) relations with commercial companies, organisations or institutions that were related to the subject matter of the guideline. Furthermore, inquiries have been made regarding personal financial interests, interests due to personal relationships, interests related to reputation management, interest is related to externally financed research and interests related to knowledge valorisation. The statements on conflict of interest can be requested from the administrative office of Kennisinstituut van de Federatie Medisch Specialisten (secretariaat@kennisinstituut.nl) and were summarised below.

 

Last name

Function

Other positions

Personal financial interests

Personal relations

Reputation management

Externally financed research

Knowledge valorisation

Other interests

Signed

Actions

De Graaf

Radiologist, Erasmus Medical Centre Rotterdam,

Board member of the Technology section, Netherlands. Far. for Radiology (unpaid)

Board member Ned. Comm. Radiation dosimetry (NCS) (unpaid)

None

None

None

None

None

None

July 14th, 2022

 

No restrictions.

Geenen RWF

Radiologist, Noordwest ziekenhuisgroep/medisch specialisten Noordwest

Member of contrast media safety committee, European Society of Urogenital Radiology (no payment)

None

None

None

None

None

None

September 2nd, 2022

No restrictions

Emons

Pediatrician-allergologist, Erasmus MC-Sophia, paid

Editorial board NTvAAKI, unpaid

NVvAKI communications committee, unpaid

None

None

None

Epitope study, cutaneous immunotherapy for peanut, DBV

BAT cow's milk study, NWO

Itulizax study, tree pollen immunotherapy, ALK

None

None

July 7th, 2022

 

No restrictions, research has no link with hypersensitivity reactions after administration of contrast agents in children.

Jöbsis

Pediatrician, pediatric nephrologist

None

None

None

None

None

None

None

July 2nd, 2022

No restrictions

Sloots

Pediatric surgeon Erasmus MC Sophia Children's Hospital

None

None

None

None

None

None

None

August, 15th, 2022

 

No restrictions

Liebrand

Anaesthesiologist Sophia Children's Hospital/Erasmus MC

Pediatrician St. Antonius Hospital, Kleve

Notarzt Kreis Kleve

None

None

None

None

None

None

December, 20th, 2022

 

No restrictions

Zwaveling-Soonawala

Pediatrician-endocrinologist, Emma Children's Hospital, Amsterdam UMC

None

None

None

None

None

None

None

June, 13th, 2023

 

No restrictions

Advisory group

Molen AJ, van der

Radiologist LUMC

Member of contrast media safety committee, European Society of Urogenital Radiology (no payment).

Member, Gadolinium Research and Education Committee, European Society of Magnetic Resonance in Medicine, and Biology (no payment).

None

None

None

None

None

Received speaker fees from Guerbet, 2019-2022

June, 5th, 2023

 

No restrictions (given the role as a sounding board group member, no active contribution to texts and the mandate for decisions rests with the guideline development group, no further restrictions have been formulated for the ancillary activities at the gadopiclenol expert group)

Riedijk

Pediatrician

Amsterdam UMC - Emma Children's Hospital

Board member SICK: unpaid.

PICE board member: unpaid.

None

None

None

None

None

None

December, 6th, 2022

 

No restrictions

Doganer

Junior project manager/policy officer at the Child and Hospital Foundation

None

None

None

None

None

None

None

July, 25th, 2023

 

No restrictions

Inbreng patiëntenperspectief

Input of patient’s perspective

The guideline does not address a specific child patient group, but a diverse set of diagnoses. Therefore, it was decided to invite a broad spectrum of patient organisations for the stakeholder consultation, and invite the patient organisation Kind & Ziekenhuis (translated as Child and Hospital Foundation) in the Advisory group. The stakeholder consultation was performed at the beginning of the process for feedbacking on the framework of subjects and clinical questions addressed in the guideline, and during the commentary phase to provide feedback on the concept guideline. The list of organisations which were invited for the stakeholder consultation can be requested from the Kennisinstituut van de Federatie Medisch Specialisten (secretariaat@kennisinstituut.nl). In addition, patient information on safe use of contrast media in children was developed for Thuisarts.nl, a platform to inform patients about health and disease.

Implementatie

Implementation

During different phases of the guideline development, implementation and practical enforceability of the guideline were considered. The factors that could facilitate or hinder the introduction of the guideline in clinical practice have been explicitly considered. The implementation plan can be found in the ‘Appendices to modules’. Furthermore, quality indicators were developed to enhance the implementation of the guideline. The indicators can also be found in the ‘Appendices to modules’.

Werkwijze

Methodology

AGREE

This guideline has been developed conforming to the requirements of the report of Guidelines for Medical Specialists 2.0 by the advisory committee of the Quality Counsel (www.kwaliteitskoepel.nl). This report is based on the AGREE II instrument (Appraisal of Guidelines for Research & Evaluation II) (www.agreetrust.org), a broadly accepted instrument in the international community and based on the national quality standards for guidelines: “Guidelines for guidelines” (www.zorginstituutnederland.nl).

 

Identification of subject matter

During the initial phase of the guideline development, the GDG identified the relevant subject matter for the guideline. The framework is consisted of both new matters, which were not yet addressed in Part 1, 2 and 3 of the guideline, and an update of matters that were subject to modification (for example in case of new published literature). Furthermore, a stakeholder consultation was performed, whre input on the framework was requested.

 

Clinical questions and outcomes

The outcome of the stakeholder consultation was discussed with the GDG, after which definitive clinical questions were formulated. Subsequently, the GDG formulated relevant outcome measures (both beneficial and harmful effects). The GDG rated the outcome measures as critical, important and of limited importance (GRADE method). Furthermore, where applicable, the GDG defined relevant clinical differences.

 

Search and select

For clinical questions, specific search strategies were formulated, and scientific articles published in several electronic databases were searched. First, the studies that potentially had the highest quality of research were reviewed. The GDG selected literature in pairs (independently of each other) based on the title and abstract. A second selection was performed by the methodological advisor based on full text. The databases used, selection criteria and number of included articles can be found in the modules, the search strategy can be found in the appendix.

 

Quality assessment of individual studies

Individual studies were systematically assessed, based on methodological quality criteria that were determined prior to the search. For systematic reviews, a combination of the AMSTAR checklist and PRISMA checklist was used. For RCTs the Cochrane risk of bias tool and suggestions by the CLARITY Group at McMaster University were used, and for cohort studies/observational studies the risk of bias tool by the CLARITY Group at McMaster University was used. The risk of bias tables can be found in the separate document “Appendices to modules”.

 

Summary of literature

The relevant research findings of all selected articles were shown in evidence tables. The evidence tables can be found in the separate document “Appendices to modules”. The most important findings in literature were described in literature summaries. When there were enough similarities between studies, the study data were pooled.

 

Grading quality of evidence and strength of recommendations

The strength of the conclusions of the included studies was determined using the GRADE-method. GRADE stands for Grading Recommendations Assessment, Development and Evaluation (see http://www.gradeworkinggroup.org) (Atkins, 2004). GRADE defines four levels for the quality of scientific evidence: high, moderate, low, or very low. These levels provide information about the certainty level of the literature conclusions (http://www.guidelinedevelopment.org/handbook).

The evidence was summarized in the literature analysis, followed by one or more conclusions, drawn from the body of evidence. The level of evidence for the conclusions can be found above the conclusions. Aspects such as expertise of GDG members, local expertise, patient preferences, costs, availability of facilities and organisation of healthcare are important to consider when formulating a recommendation. These aspects are discussed in the paragraph “Justifications”. The recommendations provide an answer to the clinical question or help to increase awareness and were based on the available scientific evidence and the most relevant “Justifications”.

 

Appendices

Internal (meant for use by scientific society or its members) quality indicators were developed during the conception of the guideline and can be found in the separate document “Appendices to modules”. In most cases, indicators were not applicable. For most questions, additional scientific research on the subject is warranted. Therefore, the GDG formulated knowledge gaps to aid in future research, which can be found in the separate document “Appendices to modules”.

 

Commentary and authorisation phase

The concept guideline was subjected to commentaries by the involved scientific societies. The list of parties that participated in the commentary phase can be requested from the Kennisinstituut van de Federatie Medisch Specialisten (secretariaat@kennisinstituut.nl).
The commentaries were collected and discussed with the GDG. The feedback was used to improve the guideline; afterwards the guideline was made definitive by the GDG. The final version of the guideline was offered to the involved scientific societies for authorization and was authorized.

 

Literature

Brouwers MC, Kho ME, Browman GP, et al. AGREE Next Steps Consortium. AGREE II: advancing guideline development, reporting and evaluation in health care. CMAJ. 2010; 182(18): E839-E842.

 

Medisch Specialistische Richtlijnen 2.0. Adviescommissie Richtlijnen van de Raad Kwaliteit, 2012. Available at: [URL].

 

Schünemann H, Brożek J, Guyatt G, et al. GRADE handbook for grading quality of evidence and strength of recommendations. Updated October 2013. The GRADE Working Group, 2013. Available at: [URL].

 

Schünemann HJ, Oxman AD, Brozek J, et al. Grading quality of evidence and strength of recommendations for diagnostic tests and strategies. BMJ. 2008;336(7653):1106-1110. Erratum published in: BMJ 2008;336(7654).

 

Ontwikkeling van Medisch Specialistische Richtlijnen: stappenplan. Kennisinstituut van Medisch Specialisten, 2020.

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