Figures
Abstract
Background
Intracavitary electrocardiogram (IC ECG) guidance emerges as a new technique for peripherally inserted central catheters (PICCs) placement and demonstrates many potential advantages in recent observational studies.
Aims
To determine whether IC ECG-guided PICCs provide more accurate positioning of catheter tips compared to conventional anatomical landmarks in patients with cancer undergoing chemotherapy.
Methods
In this multicenter, open-label, randomized controlled study (ClinicalTrials.gov number, NCT02409589), a total of 1,007 adult patients were assigned to receive either IC ECG guidance (n = 500) or anatomical landmark guidance (n = 507) for PICC positioning. The confirmative catheter tip positioning x-ray data were centrally interpreted by independent radiologists. All reported analyses in the overall population were performed on an intention-to-treat basis. Analyses of pre-specified subgroups and a selected large subpopulation were conducted to explore consistency and accuracy.
Results
In the IC ECG-guided group, the first-attempt success rate was 89.2% (95% confidence interval [CI], 86.5% to 91.9%), which was significantly higher than 77.4% (95% CI, 73.7% to 81.0%) in the anatomical landmark group (P < 0.0001). This trend of superiority of IC ECG guidance was consistently noted in almost all prespecified patient subgroups and two selected large subpopulations, even when using optimal target rates for measurement. In contrast, the superiority nearly disappeared when PICCs were used via the left instead of right arms (interaction P-value = 0.021). No catheter-related adverse events were reported during the PICC intra-procedures in either group.
Conclusions
Our findings indicated that the IC ECG-guided method had a more favorable positioning accuracy versus traditional anatomical landmarks for PICC placement in adult patients with cancer undergoing chemotherapy. Furthermore, there were no significant safety concerns reported for catheterization using the two techniques.
Citation: Yuan L, Li R, Meng A, Feng Y, Wu X, Yang Y, et al. (2017) Superior success rate of intracavitary electrocardiogram guidance for peripherally inserted central catheter placement in patients with cancer: A randomized open-label controlled multicenter study. PLoS ONE 12(3): e0171630. https://doi.org/10.1371/journal.pone.0171630
Editor: Iratxe Puebla, Public Library of Science, FRANCE
Received: October 13, 2015; Accepted: January 25, 2017; Published: March 9, 2017
Copyright: © 2017 Yuan et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by Drum Tower Hospital-based Science and Research Fund (No: 2015-001). This study was funded by Key Project of Medical Science and Technology Development, Nanjing Health Bureau (No: ZKX15017). The funding sources had no role in the study design, data collection, analysis, preparation of the manuscript, or decision to publish. The corresponding author had full access to all the data in the study and had the final responsibility for the decision to submit for publication.
Competing interests: We declare that the new IC ECG guidance system used in the study had been offered a National Utility Model Patent (No.: ZL-2014-2-0436176.7, authors: Ling Yuan, Rongmei Li, Chen Xiangyu) previously. However, this does not alter our adherence to PLOS ONE policies on sharing data and materials. Moreover, we declare that no part of this paper has been published or submitted elsewhere. No conflict of interest exists in the submission of this manuscript.
Introduction
Chemotherapy as a routine treatment option for patients with cancer is usually administrated intravenously using a peripherally inserted central catheter (PICC) [1–5]. Since catheters placed outside of the cavo-atrial junction (CAJ) are potentially associated with higher risk of thrombosis and infection [1–3], it is essential that the catheter tip is in an ideal position when PICCs used for chemotherapy are left in place for several weeks or months [6, 7]. Most recommendations from the USA [8–10] propose that the tip should be placed in the lower third of the superior vena cava (SVC), while European guidelines [11, 12] often regard the upper part of the atrium as acceptable. Specifically, Pittiruti et al. [13, 14] agreed that for chemotherapy, the tip should preferably be placed in the lower third of the SVC. Chinese nursing practice standards require that the catheter tip be placed in the SVC [15]. Since there is no method for assessing tip positioning that can exclude misplacement with absolute certainty [16], any new method with high accuracy at first-attempt insertion warrants research.
The conventional anatomical landmark method exploits the estimated length from the puncture site to the junction of the SVC/right atrium (SVC-RA) to guide tip placement. This method is associated with relatively lower financial costs and acceptable performance, and has become the first choice for patients with poor economic status and good vascular access in China [5]. Nevertheless, additional post-procedural chest X-rays (exposure of patients to radiation and extra cost) are required later to confirm central line placement. Following on from this simple technique, there is a growing body of evidence from around the world regarding the use of intracavitary electrocardiography (IC ECG) to guide PICC placement. The current findings indicate that this alterative technique could be as accurate as radiological methods as well as safe, while providing real-time monitoring and less need for X-ray confirmation [1, 13]. In a recent prospective, non-controlled Italian study, Rossetti et al. reported that IC ECG was up to 95.8% as effective as X-ray [14]. However, there is a lack of randomized controlled studies comparing these two methods properly. Therefore, the current study tested the hypothesis of whether IC ECG-guided technique is more accurate than landmark technique for PICC placement in patients with cancer undergoing chemotherapy. We investigated how well the two techniques perform among patient subgroups. This study provides substantial initial Chinese patient data with which to improve PICC technique for local use.
Materials and methods
Study design
This was a multicenter, open-label, randomized controlled (EGG) study of IC ECG guidance versus anatomical landmark guidance in patients undergoing chemotherapy for different cancers (NCT02409589; study protocol [S1 and S2 Files] and Consolidated Standards of Reporting Trials (CONSORT) checklist available in S3 File). There was a 1-week delay in making public the online registry of this study because our study team had to develop the information used for the registry in English. The authors confirm that all ongoing and related trials for this IC ECG intervention are registered. Eligible patients enrolled by sites obtained a unique patient number and were randomly assigned to undergo IC ECG guidance or anatomical landmark guidance for PICC insertion in a 1:1 ratio. A stratified block randomization with randomly varying block sizes of 2 and 4 was performed, and stratification by site was used. Random assignment was performed by a statistician from Shanghai Knowlands MedPharm Consulting Co., Ltd and implemented via random envelopes assigned to each site. Sequences were concealed from patients and clinical staff until assignment. The study protocol was centrally approved by the independent Medical Ethics Committee (IEC) of Drum Tower Hospital, Medical School of Nanjing University on March 10, 2015.
Patients
The study was conducted at eight centers in China. Eligible inpatients or outpatients were aged 18 to 80 years, had malignant tumors that required the periodical infusion of chemotherapy drugs via three-valve PICCs, and had normal P-waves according to surface ECG recordings prior to PICC insertion. Patients also had to provide signed informed consent prior to enrollment in the study.
Patients with the following conditions were excluded: heart diseases such as valvular heart disease, atrial fibrillation, supraventricular tachycardia, pulmonary heart disease, or the presence of a pacemaker and past history of cardiac surgery that may affect P-waves, or the inability to lie in the prostrate or semi-supine position.
PICC methods
Eligible patients underwent traditional anatomical landmark or IC ECG-guided technique for PICC insertion. We used Rountree’s method [17] to measure catheter insertion length. A single-lumen PICC kit (Groshong NXT ClearVue, 4 F) manufactured by Bard Access Systems, Inc. (Utah, USA) and a C100 specialized cardiovascular monitor from Shenzhen Comen Medical Instruments Co., Ltd. were used during catheterization. In the landmark group, if we suspected that the catheter had been inserted outside the SVC, an ultrasound examination of the subclavian vein, internal jugular vein and external jugular vein was performed to detect and adjust any malposition of the catheter.
In the IC ECG group, we used a column of saline contained in the catheter as an intracavitary (endovascular) electrode [13]. IC ECG was performed to guide the positioning of the PICC tip while using an intravenous gravity drip of normal saline to form the column [18]. The new IC ECG guidance system used in the study had been offered a National Utility Model Patent (No.: ZL-2014-2-0436176.7) previously. The same puncture procedure was applied. In accordance with our pilot study, after puncture was performed, the catheter was advanced gently with sequential monitoring of ECG P-wave shape and amplitude by a bedside ECG monitor as follows: (1) when the catheter tip was located outside of the SVC or was just entering the SVC, no obvious change in P-wave occurred relative to surface ECG; (2) when continuing to slowly advance the catheter along the SVC, the P-wave would enlarge gradually; (3) when the catheter tip reached the atrium, the following changes in P-wave were observed: the low-frequency wave shifted to high frequency and the shape changed from obtuse to very sharp with either the PR segment moving down or negative P-wave starting to appear (amplitude ≥ 1 mm). The catheter was immediately pulled back slowly until the P-wave returned to a low-frequency obtuse shape with no negative wave, which then indicated that the catheter tip was located in the lower third of the SVC or at the CAJ (S1 Fig). Therefore, no ultrasound examinations were required to adjust PICC placement in this group.
Efficacy evaluation
The primary analysis was an intention-to-treat (ITT) assessment of first-attempt success rates with IC ECG guidance compared with anatomical landmark guidance for PICC insertion. The first-attempt success rate as a primary efficacy endpoint was defined as the proportion of patients whose catheter tip was in the SVC or at the CAJ during the first attempt of PICC insertion as confirmed by chest X-ray. If the catheter tip was in the lower third of the SVC or at the CAJ, the placement was regarded as optimal. Furthermore, the proportion of patients whose catheter tip resided in the RA space at the first attempt was also summarized. In the study, we utilized the reported methodology and radiologic criteria [19] for the post-procedural review of the tip position. When the PICC tip was positioned in the right atrium, the distance between the cavo–atrial junction and the tip was determined. Then the right atrium is divided into three equal segments of upper 1/3, middle 1/3 and lower 1/3. The confirmative X-ray data in the study were interpreted separately by two independent radiologists. If inconsistent findings were noted, a third radiologist would further check the X-ray recordings and make a decision, and the majority decision was taken as the final result. In total, the third radiologist checked 43 X-ray recordings until the determination of primary endpoint. All of the independent radiologists are always blinded to treatment assignment. In addition to demographic and medical condition data, physical and laboratory examinations were performed prior to the start of and/or during PICC insertion.
Statistical analysis
All randomly assigned patients were included as an ITT population in the primary analysis. No missing data were imputed and the as-observed rule was implemented. The primary efficacy parameters of first-attempt success rates were compared using a Pearson’s chi-squared test with a two-sided 5% significance level; 95% confidence intervals (CIs) of the success rate and rate difference were provided to indicate precision. The CIs used normal approximation or the Clopper-Pearson’s exact method. Interactions between planned covariates and PICC techniques were evaluated using a logistic model. The P-values for interaction were reported. The prespecified stratifications were based on the following covariates: gender, age group, body mass index (BMI) classification, cancer duration since diagnosis, current cancer metastasis status, prior chemotherapy, prior chest radiotherapy, smoking status, current activity level, prior CVCs, prior PICC insertion, arm side of PICC, and body posture during PICC insertion. Additional analyses of selected subpopulations were performed. BMI classification was derived using Chinese criteria [20]. Lesser activity was defined as an amount less than that of daily living (activities performed for self-care such as feeding, bathing, dressing, grooming, etc.) and higher activity as more than that required for daily living (ability to work normally, perform physical exercise, etc.) [21].
Assuming a first-attempt success rate of 88% for the anatomical landmark method as reported in previous studies [22–24], a sample size of 135 patients per group was assumed to have 90% power to detect a 10% increase in rate at a 2-sided Type I error rate of 5%. With an estimated 10% dropout rate during the study, 300 patients were randomized. Given the intention and feasibility to perform subgroup analyses and exploratory analysis on common PICCs-related complications as well, the sample size was enlarged to 1,000 randomized patients (500 per group). Two-sided p-values of less than 0.05 were considered statistically significant. No multiplicity adjustment was considered for the subgroup analyses. All statistical analyses were performed using SAS software, version 9.2 (SAS Institute, NC, USA) and R, version 3.1.2 [25].
Results
Patient characteristics
Between late March and July 2015, a total of 1,007 patients were randomly assigned to receive either IC ECG guidance (n = 500) or anatomical landmark guidance (n = 507) for PICC positioning (ITT population; Fig 1). Four patients (IC ECG: n = 1; landmark: n = 3) refused to undergo X-ray confirmation for catheter tip positioning. No other protocol deviations occurred during the entire procedural period, although four patients were aged over 80.
IC ECG: Intracavitary Electrocardiograph, ITT: Intention-To-Treat, PICCs: Peripherally Inserted Central Catheters.
Patient demographic and baseline disease characteristic data were well matched between the two study groups (Table 1 and S1 Table).
PICC insertion characteristics and safety
The PICC operating characteristics were comparable between the two techniques (S2 Table). Most PICCs were inserted via the right arm (77%), using the basilic vein (89%), and in the supine body posture (86%). For safety, intra-procedural heart rhythm, heart rate and blood oxygen levels were monitored in the IC ECG group, but no significant changes since the start of PICC insertion were noted (data not shown). No catheter-related adverse events or complications were reported during the PICC manipulation in either group.
Accuracy of PICC tip positioning
During the PICC procedure, ultrasound examinations indicted that in 29 (5.8%) patients who underwent placement using the anatomical landmark technique, the PICC tip failed to reach the SVC area on the first attempt. Of them, eight patients experienced aberrant placement ≥ 3 times. Conversely, In the IC ECG guided group, tip misplacement was totally avoided due to real-time monitoring of changes in P-waves.
In our study, the first-attempt success rate in the IC ECG-guided group was up to 89.2% (95% CI, 86.5% to 91.9%), significantly higher than 77.4% (95% CI, 73.7% to 81.0%) in the anatomical landmark group (P < 0.0001, Table 2). A slightly less obvious superiority was observed with respect to optimal target rate or right atrium rate (Table 2). This trend of higher accuracy when using IC ECG guidance was consistently found in almost all of the prespecified patient subgroups (Table 3) and two selected large subpopulations (S3 and S4 Tables). However, the superiority of IC ECG guidance nearly disappeared when PICCs were inserted via the left arm, while it remained when the right side was used (interaction P-value = 0.021, Table 3).
Discussion
To our knowledge, this EGG study is the first randomized controlled study to compare IC ECG and landmark techniques for PICC placement in adult patients with cancer. Our study demonstrates that PICCs inserted using IC ECG technique are positioned relatively better. The comparative advantage was observed in almost all prespecified patient subgroups undergoing chemotherapy. This method may provide a possibility to avoid catheter tip placement outside of the SVC.
In the last 20 years, PICCs have come to play an important role in intravenous therapy and treatment because of a few key advantages over traditionally placed CVCs [1, 26]. Currently, several methods are available for the positioning of PICC catheter tips [1, 5, 13, 27]. Of them, the most frequently used techniques are traditional anatomical landmark guidance, followed by IC ECG guidance [5, 27]. The latter technique, which uses ECG to guide CVC placement, emerged in 1949 [28], and a number of non-randomized studies have recently been published regarding its performance and safety. These studies all agree that ECG technique performs well for the positioning of PICCs [1, 13]. Unfortunately, there are very few head-to-head studies comparing these techniques. In a very recent small comparative study by Baldinelli et al. [27] (n = 90 PICCs), the authors reported significant benefits from ECG guidance versus landmark guidance, but recognized non-randomization as one of major limitations of the methodology [27]. At the time of designing the present study, this report was not yet published. Our study aimed to confirm the benefits of IC ECG technique for PICC placement.
The malpositioning of PICCs occurs rather frequently, but the exact rate can vary greatly. Trerotola et al. [29] reported in a review of medical records that 10% of tips in 1,654 PICC attempts were malpositioned. Fricke et al. [30] summarized 843 consecutively placed pediatric PICCs, of which 85.8% were associated with non-central PICC tip positioning initially. Minkovich et al. [31] reported an incidence of aberrant positioning or suboptimal positioning of 35% and 13%, respectively, using a database of 269 patients. Therefore, for robust estimation in adult patients with cancer, we tripled our study size from the initial calculation. Accordingly, advantages might be seen for IC ECG technique among larger subgroups. Our study showed that landmark guidance had a relatively low overall success rate (77.4%), which was consistent among nearly all subgroups. In a Cochrane review with 18 included studies (n = 1792) comparing ultrasound and landmark guidance via internal jugular vein cannulation for CVCs (direct puncture) [22], landmark guidance achieved an overall success rate of 88.7%, but with varying rates in individual studies. Our lower rate in the landmark guidance group might also result from the different veins cannulated [22] and different vascular statuses even in the same Chinese setting [5]. Similarly, a lower overall success rate of 89.2% occurred in the IC ECG group, which was due to a lower success rate (81.4%) in the patients with PICCs inserted from the left arms. This decrease in success on the left arm may be explained by a higher P-wave force, as this could confuse operators when trying to accurately secure the catheter tip at the desired location. When catheters were advanced into the SVC from the left side, the PICC tip tended to stay closer to the right wall of the SVC due to the stretching force introduced by the catheter. On this occasion a smaller angle of the PICC tip—resultant atrial depolarization vector developed and then a consequent higher P-wave force occurred.
Although this randomized study demonstrated an expected and consistent superiority of IC ECG technique, we must acknowledge that this study is open-labeled given the totally different techniques used. Nonetheless, in order to avoid introducing bias, the confirmative X-ray was centrally reviewed and the reviewers were blinded to the PICC technique used in each patient. Secondly, in view of the focus of the current report, we did not provide any data regarding cost, long-term efficacy, and safety. PICC-related complications will be a topic of research for us in the future. Like a similar report observed in another large multicenter study (1,444 patients) in European [32], our current analysis did not report any catheter-related adverse events or complications during the PICC manipulation in either group. Third, the use of IC ECG technique is subject to a standard P-wave identified on a surface ECG. For this reason, about 7% of cases of any disease might have to resort to other PICC placement methods [13]. The IC ECG catheter tip positioning technology usually relies on normal electrophysiology. Therefore, if those patients with structural heart diseases and similar conditions contraindicated for chemotherapy were identified and counted out, most cancer patients in need of chemotherapy would benefit from this PICC technique.
In conclusion, this randomized study demonstrated the superior efficacy in terms of first-attempt success rate of IC ECG technique for PICC placement guidance in adult patients with cancer undergoing chemotherapy. There were no significant safety concerns reported for catheterization using the two techniques. Moreover, it might be of clinical relevance that the significant beneficial difference observed almost completely disappeared in patients with PICCs inserted from the left arms.
Supporting information
S3 File. CONSORT 2010 Checklist.
CONSORT: CONsolidated Standards of Reporting Trials.
https://doi.org/10.1371/journal.pone.0171630.s003
(DOC)
S1 Fig.
Evolving ECG monitor photographs among the same individual patient: (A): surface; (B) SVC; (C) RA; (D) SVC-RA junction. ECG: electrocardiograph; RA: right atrium; SVC: superior vena cava.
https://doi.org/10.1371/journal.pone.0171630.s004
(TIF)
S1 Table. Comorbidities and medical history (N = 1,007).
https://doi.org/10.1371/journal.pone.0171630.s005
(DOCX)
S2 Table. Table PICC insertion characteristics (ITT, N = 1,007).
ITT: intent-to-treat; PICC: peripherally inserted central catheter.
https://doi.org/10.1371/journal.pone.0171630.s006
(DOCX)
S3 Table. Catheter tip placement at first attempt by ultra-sound or chest x-ray confirmation and corresponding rates of outcome measures in subgroup patients with major prior surgery (N = 551).
https://doi.org/10.1371/journal.pone.0171630.s007
(DOCX)
S4 Table. Catheter tip placement at first attempt by ultra-sound or chest x-ray confirmation and corresponding rates of outcome measures in subgroup patients with basilic vein used for PICCs (N = 892).
PICCs: peripherally inserted central catheters.
https://doi.org/10.1371/journal.pone.0171630.s008
(DOCX)
Acknowledgments
We all thank Sam Zhong (SZ) and Weikai Chen for their generous assistance with this study.
Author Contributions
- Conceptualization: LY.
- Data curation: LY RML AFM YLF XCW YQY PC ZZQ JQ CYC JW MYQ WWK WX.
- Formal analysis: LY.
- Funding acquisition: LY.
- Investigation: LY RML AFM YLF XCW YQY PC ZZQ JQ CYC JW MYQ WWK WX.
- Methodology: LY XC WX.
- Project administration: LY RML.
- Resources: LY.
- Software: LY.
- Supervision: LY.
- Validation: LY WWK WX.
- Visualization: LY RML WX.
- Writing – original draft: LY RML WX.
- Writing – review & editing: LY RML WX.
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