Use of ultrasound-measured internal jugular vein collapsibility index to determine static intracardiac pressures in patients with presumed pulmonary hypertension

Background Bedside ultrasound helps to estimate volume status in critically ill patients and has traditionally relied on diameter, respiratory variation, and collapsibility of the inferior vena cava (IVC) to reflect fluid status. We evaluated collapsibility of the internal jugular vein (IJ) with ultrasound and correlated it with concomitant right heart catheterization (RHC) measurements in patients with presumed pulmonary hypertension. Methods and results We studied 71 patients undergoing RHC for evaluation of pulmonary hypertension. Using two-dimensional ultrasound (Sonosite, Washington, USA), we measured the diameter of the IJ at rest, during respiratory variation, and during manual compression. Collapsibility index during respiration (respiratory CI) and during manual compression (compression CI) was calculated. We correlated mean right atrial pressure (mRAP) and pulmonary artery occlusion pressure (PAOP) defined by RHC measurements with respiratory and compression CI. A secondary goal was examining correlations between CI calculations and B-type natriuretic peptide (BNP) levels. Baseline characteristics demonstrated female predominance (n = 51; 71.8%), mean age 59.5 years, and BMI 27.3. There were significant correlations between decrease in compression CI and increase in both mRAP (Spearman: − 0.43; p value = 0.0002) and PAOP (Spearman: − 0.35; p value = 0.0027). In contrast, there was no significant correlation between respiratory CI and either mRAP (Spearman: − 0.14; p value = 0.35) or PAOP (Spearman:− 0.12; p value = 0.31). We also observed significant negative correlation between compression CI and BNP (Spearman: − 0.31; p value = 0.01) but not between respiratory CI and BNP (Spearman: − 0.12; p value = 0.35). Conclusion Increasing use of ultrasound has led to innovative techniques for estimating volume status. While prior ultrasound studies have used clinical parameters to estimate fluid status, our study used RHC measurements and demonstrated that compression CI potentially reflects directly measured mRAP and PAOP.


Background
Currently, precise determination of cardiac filling pressures and biventricular volume status requires invasive monitoring with a pulmonary artery catheter. Ultrasonography of the inferior vena cava (IVC) can non-invasively estimate the mean right atrial pressure (mRAP), but it can be misleading and limited, especially among critically ill patients or if visualization of the IVC is suboptimal [1,2]. Despite these limitations, bedside ultrasound has become a versatile modality for assessing volume status in critically ill patients using measurements such as diameter, variation with respiration, and overall collapsibility of the IVC [3][4][5][6][7][8][9]. Recently, ultrasound characterization of the internal jugular vein (IJ), specifically diameter and cross-sectional area, has been shown to correlate with and Open Access *Correspondence: Raj.parikh@bmc.org 5 Boston University Medical Center, 72 East Concord Street, R304, Boston, MA 02118, USA Full list of author information is available at the end of the article predict central venous pressure (CVP) [10][11][12][13][14][15]. Furthermore, these IJ measurements are comparable and at times superior to IVC measurements [16]. However, no studies have correlated IJ ultrasonography with invasively measured hemodynamics. The aim of the current study was to correlate measurements of the IJ by bedside ultrasound with measurements obtained during concomitant right heart catheterization (RHC).

Study design and patient selection
We conducted a prospective study of 71 consecutive patients undergoing RHC as part of routine evaluation for pulmonary hypertension (PH) at Boston University Medical Center, Boston, MA, USA. The study was approved by the Institutional Review Board of Boston University Medical Center and the requirement for informed consent was waived.

Data extraction: ultrasound measurements
Clinical and laboratory data were collected for all patients before and during the procedure. Collected data from the electronic medical record included past medical history and laboratory tests. Procedural data included ultrasound measurements and RHC measurements ( Fig. 1).
RHC was performed in a fluoroscopy-equipped catheterization laboratory with patients positioned at the level of their respiratory comfort; 62 (87.3%) participants were supine for the entirety of the procedure. Using a bedside two-dimensional ultrasound (Sonosite, Washington, USA), the diameter of the IJ at rest, during respiratory variation (inspiration and expiration), and during manual compression (measured at 2 cm of depth from the skin) was measured. All ultrasound measurements were completed prior to the RHC. Trained Pulmonary/Critical Care physicians with certification to complete central venous and pulmonary artery catheterizations performed the ultrasound measurements and the subsequent RHC.
IJ measurements were recorded with the linear transducer probe. The IJ was visualized by placing the ultrasound transducer perpendicular to the skin in the transverse plane at a level just above the clavicle. The IJ was identified by compression as well as by color Doppler imaging and Pulse Wave Doppler. Sufficient ultrasound gel was used to prevent direct skin contact with the transducer, helping to limit the amount of pressure applied and avoid significant influence of external compression on the IJ diameter at rest [7]. Measurements were obtained by an M-mode scan on the ultrasound device. The maximum anterior-posterior diameter of the IJ was measured at rest followed by variations during the respiratory cycle, where the patient was asked to take a deep breath in, breathe out, and then hold their breath at the end of expiration for one second. Subsequently, minimal pressure (measured via ruler at 2 cm of depth from the superficial skin) via the transducer was applied on the IJ to induce extrinsic manual compression (Fig. 2). The antero-posterior diameter of the IJ was then re-measured. Accuracy of the measurements was based on agreement between the operator and the supervising physician (HWF for all patients). The collapsibility index of respiratory variation (respiratory CI) and the collapsibility index of manual extrinsic compression (compression CI) were computed using the following calculation: (maximum diameter − minimum diameter)/maximum diameter.

Patients undergoing RHC for routine PH evaluation
Ultrasound assessment of IJ Cannulation of IJ with introducer cordis PA catheter inserted, RHC measurements obtained

Study outcomes
The primary outcome of the study was the correlation between respiratory CI, compression CI, and volume status defined by the RHC measurements. Additionally, we evaluated the correlation between respiratory CI, compression CI, and B-type natriuretic peptide (BNP) levels, measured pre-procedurally.

Statistical analysis
Summary statistics are reported on all variables including n (%) for categorical and mean ± standard deviation for continuous measures. Spearman correlations were used to quantify the linear relationship between continuous measures. All analyses were performed using SAS v9.4 with p < 0.05 considered statistically significant.

Discussion
The increasing use of ultrasound to estimate CVP and fluid responsiveness in acutely and/or chronically ill patients has led to several innovative techniques. While prior ultrasound studies have used clinical parameters to estimate volume status, the current study used concomitant RHC measurements, the gold standard in volume assessment. This study demonstrated that compression CI, a simple ultrasound technique requiring minimal operator experience, accurately reflects directly measured mRAP and PAOP in patients with presumed pulmonary hypertension.

Compression CI
Assessing the ultrasound-measured compressibility of a vein and using it as a non-invasive marker for fluid status could provide yet another component to critical care ultrasound techniques. Volume status is a central component to manage both critically ill patients in an intensive care unit and chronically ill patients, such as those with underlying renal or cardiac disease [18,19]. Moreover, the accuracy in estimating volume status is essential to improve patient care and therapeutic approaches. Based on the current observations, compression CI of the IJ, a simple, non-invasive technique that only requires basic ultrasound skills, could be used as a surrogate for CVP.

IJ vs IVC
Use of the compression CI of the IJ provides a novel approach to non-invasive fluid status assessment; however, is it better or easier than use of the IVC as the target venous structure? IVC collapsibility is a well-documented measurement in critical care ultrasound and volume assessment, although evidence for its accuracy is controversial; moreover, in many situations, the IVC is poorly visualized [1,2,16]. Additionally, formal echocardiography uses the IVC diameter and collapsibility with sniff to generate an estimated, yet imprecise, assessment of the mRAP [3]. Nevertheless, the IVC has historically been used as the target venous structure; in particular, size of the IVC and its dynamic change during respiration is used to estimate mRAP [3][4][5][6][7][8][9]. The current study suggests that use of the IJ may be an accurate and reliable estimation of mRAP during ultrasonography. Although we did not compare IJ and IVC measurements in the current study, the strong correlation observed between IJ diameter at rest and mRAP suggests the need for future studies comparing both ultrasound methods.

Limitations
The current study has several limitations. 1) The operators were not blinded to the ultrasound and RHC assessments, which could have influenced the results. 2) The cohort included patients with known or suspected pulmonary vascular disease; none were critically ill patients in an intensive care unit. Unfortunately, given the paucity of pulmonary artery catheters inserted in intensive care units currently, it would be very difficult to perform a similar study in such patients. Likewise, we did not assess fluid responsiveness in these patients. 3) We only   [20]. In the current study, we used an extrinsic compression of 2 cm at the level of the patient's skin. Despite the outlined technique, user error in estimating 2 cm and an inability to directly measure the degree of compression could result in variability. Additionally, variability with patient's body habitus could also affect the ability to provide adequate compression. Although a standardized process of applying compression has yet to be described in the literature, in this study, one individual supervised all the procedures and measurements to assure a standard protocol among the operators. Further studies that apply the use of a pressure manometer could mitigate this variability; such a pressure manometer has been utilized in other ultrasound-based investigations [21]. In a similar manner, standardizing the maneuver used to obtain the respiratory CI was a challenge as well [22]. Ultrasound measurements of the IJ, specifically compression CI, correlate with invasively measured biventricular hemodynamics in this non-critically ill population of patients with presumed pulmonary hypertension. Thus, compression CI may be a useful tool in the non-invasive estimation of intravascular volume status. Further studies of the compression CI of the IJ, as well as direct comparison to IVC, are warranted.