Biplane Imaging Versus Standard Transverse Single-Plane Imaging for Ultrasound-Guided Peripheral Intravenous Access: A Prospective Controlled Crossover Trial.

Obtaining peripheral IV access in critically ill patients is often challenging especially for novice providers. The availability of biplane imaging for ultrasound guided peripheral access has the potential to improve successful venous cannulation compared with standard plane imaging. DESIGN: Single-center quasi-randomized (alternate allocation) crossover trial. SETTING: Surgical ICU at the Massachusetts General Hospital. SUBJECTS: Twenty surgical ICU nurses with no prior experience using ultrasound for peripheral IV were enrolled. INTERVENTIONS: All participants viewed instructional videos on single-plane and biplane imaging for peripheral IV insertion. The participants were then quasi-randomly assigned to use either single-plane or biplane imaging for peripheral IV insertion using a phantom model. The time to catheter completion, successful lumen cannulation, and attempts in which the needle was observed to go through the back wall of the vessel were recorded for each of the three attempts. The following day the participants repeated the peripheral IV insertion with the alternate imaging modality. MEASUREMENTS AND MAIN RESULTS: Biplane imaging compared with single-plane imaging was associated with a significantly greater overall success rate (78.3% ± 22.4% vs 41.7% ± 26%; p < 0.001), higher first-pass success rate (80% ± 41% vs 45% ± 51%; p = 0.015), faster cannulation times (27.8 ± 14.8 vs 36.6 ± 15.8 s; p = 0.003), and reduced frequency of backwall perforations (0.4 ± 0.7 vs 1.5 ± 0.8; p < 0.001). CONCLUSIONS: This proof-of-principle study demonstrates that the biplane ultrasound imaging approach for vessel cannulation resulted in an overall faster, more successful, and safer peripheral IV access than the standard single-plane transverse approach when performed by novice ultrasound users.

Biplane Imaging Using Portable Ultrasound Devices for Vascular Access.

The use of ultrasound guidance for the placement of difficult IVs, arterial lines, and central venous access has become the standard of care. While imaging quality has improved over the last two decades, the lack of affordability, availability, and training have been major limitations in its routine clinical use. We detail the first reported use of biplane imaging using a portable ultrasound probe for difficult vascular access to increase first past success, efficiency, safety, and sterility during the coronavirus disease 2019 (COVID-19) pandemic.

Study of Xplane imaging in quantifying the maximal volume of the left and right atria and evaluating atrial function in fetuses with abnormal heart morphology / 中华超声影像学杂志

Objective To explore the feasibility of real-time three-dimensional ultrasound Xplane imaging in quantifying left and right atrial diastolic maximal volume (LAVmax,RAVmax) and evaluating cardiac diastolic function in fetuses with cardiac disease in second and later trimesters.Methods One hundred and forty-four fetuses with abnormal heart morphology at 16-34 weeks of gestational age were included and divided into 3 groups according to the influence of pathological changes on atrial volume:group A with symmetrical left and right atrial volume,group B with decreased left atrial volume and increased right atrial volume and group C with increased left atrial volume and decreased right atrial volume,and the fetus were also divided into 2 groups according to the law of fetal development:the middle pregnancy group (16-27+6 weeks) and the late pregnancy group (28-34+6 weeks).Using the "Xplane" mode of volume probe,the maximal atrial volume was calculated automatically by tracing method and three-path line method.The correlation between the two methods in quantitative LAVmax was validated by paired sample t test and Pearson correlation analysis.The correlation between LAVmax,RAVmax and gestational age were analyzed by curve fitting.The volumes of bilateral chambers and the average weekly growth rates of E peak,A peak and E/A value of mitral and tricuspid orifices were calculated and compared.Results There was no significant statistical difference between the maximal volume of the left atrium obtained by the tracing method and the three-diameter line method (P ＞0.05),and there was high correlation between the two methods in the comparison of the maximal volume of the left atrium (r =0.90,0.88,0.85;all P ＜0.01).The data of group A,B and C showed that LAVmax and RAVmax could increase with the increase of gestational weeks in a certain period of abnormal state,and had a good correlation with them(LAVmax:r =0.78,0.74,0.78,all P ＜0.005;RAVmax:r =0.79,0.77,0.78,all P ＜0.005).The average weekly growth rate of RAVmax showed an advantage in group A,B and C.Especially in group C with reduced right atrium,the growth rate of right atrium was 8.15 ％,which was higher than that of group B with decreased left atrium by 5.06％.The weekly growth rates of E peak and E/A in tricuspid orifice were also higher than those in mitral orifice.The E peak and E/A values of tricuspid orifice in group C were 4.05％ and 0.60％,respectively,higher than those in group B,which were 2.58％ and 0.02％.Peak A showed an increase in growth rate in group B and group C with decreased atria,peak A values in group B and group C increased by 4.01 ％ and 2.19％,respectively.Conclusions The right ventricular dominance of fetal heart can still be reflected in certain stages of disease,and the atrial active systolic may play a regulatory role in the filling of cardiac blood flow.Real-time three-dimensional ultrasound Xplane imaging could be used to quantify the atrial volume of fetuses with abnormal heart morphology in second and later trimesters and to preliminary assess atrial function combined with the changes of atrioventricular valve orifice hemodynamics.Real-time three-dimensional ultrasound Xplane imaging technology has obvious advantages of simple,safe,non-invasive,simultaneous and high repeatability in measuring fetal atrial volume.

Study of Xplane imaging in quantifying the maximal volume of the left and right atria and evaluating atrial function in fetuses with abnormal heart morphology / 中华超声影像学杂志

Objective@#To explore the feasibility of real-time three-dimensional ultrasound Xplane imaging in quantifying left and right atrial diastolic maximal volume (LAVmax, RAVmax) and evaluating cardiac diastolic function in fetuses with cardiac disease in second and later trimesters.@*Methods@#One hundred and forty-four fetuses with abnormal heart morphology at 16-34 weeks of gestational age were included and divided into 3 groups according to the influence of pathological changes on atrial volume: group A with symmetrical left and right atrial volume, group B with decreased left atrial volume and increased right atrial volume and group C with increased left atrial volume and decreased right atrial volume, and the fetus were also divided into 2 groups according to the law of fetal development: the middle pregnancy group (16-27+ 6 weeks) and the late pregnancy group (28-34+ 6 weeks). Using the " Xplane" mode of volume probe, the maximal atrial volume was calculated automatically by tracing method and three-path line method. The correlation between the two methods in quantitative LAVmax was validated by paired sample t test and Pearson correlation analysis. The correlation between LAVmax, RAVmax and gestational age were analyzed by curve fitting. The volumes of bilateral chambers and the average weekly growth rates of E peak, A peak and E/A value of mitral and tricuspid orifices were calculated and compared.@*Results@#There was no significant statistical difference between the maximal volume of the left atrium obtained by the tracing method and the three-diameter line method (P>0.05), and there was high correlation between the two methods in the comparison of the maximal volume of the left atrium (r=0.90, 0.88, 0.85; all P<0.01). The data of group A, B and C showed that LAVmax and RAVmax could increase with the increase of gestational weeks in a certain period of abnormal state, and had a good correlation with them(LAVmax: r=0.78, 0.74, 0.78, all P<0.005; RAVmax: r=0.79, 0.77, 0.78, all P<0.005). The average weekly growth rate of RAVmax showed an advantage in group A, B and C. Especially in group C with reduced right atrium, the growth rate of right atrium was 8.15%, which was higher than that of group B with decreased left atrium by 5.06%. The weekly growth rates of E peak and E/A in tricuspid orifice were also higher than those in mitral orifice. The E peak and E/A values of tricuspid orifice in group C were 4.05% and 0.60%, respectively, higher than those in group B, which were 2.58% and 0.02%. Peak A showed an increase in growth rate in group B and group C with decreased atria, peak A values in group B and group C increased by 4.01% and 2.19%, respectively.@*Conclusions@#The right ventricular dominance of fetal heart can still be reflected in certain stages of disease, and the atrial active systolic may play a regulatory role in the filling of cardiac blood flow. Real-time three-dimensional ultrasound Xplane imaging could be used to quantify the atrial volume of fetuses with abnormal heart morphology in second and later trimesters and to preliminary assess atrial function combined with the changes of atrioventricular valve orifice hemodynamics. Real-time three-dimensional ultrasound Xplane imaging technology has obvious advantages of simple, safe, non-invasive, simultaneous and high repeatability in measuring fetal atrial volume.

Z-scores for fetal atrial volume using real-time three-dimensional echocardiographic Xplane imaging in normal fetuses / 中华超声影像学杂志

Objective To establish Z-scores reference ranges for fetal atrial volume in normal fetuses for accurate assessment of fetal cardiac structure and function . Methods Two hundred ninty-three normal fetuses with gestational ages between 18 to 38 weeks were investigated .Biparietal diameter (BPD) , femur length (FL) and gestational age (GA) were measured .Left atrial volume (LAV) and right atrial volume ( RAV ) were obtained using echocardiographic Xplane imaging . Subsequently , the optimal regression equation was established with BPD ,FL and GA as the independent variable and LAV and RAV as the dependent variable ,and then Z-scores of LAV and RAV were calculated . Results The linear regression equation of LAV and FL was Y＝0 .056×FL －1 .791 ( r ＝0 .952) ;the linear regression equation of RAV and FL was Y＝0 .057×FL －1 .833 ( r ＝0 .942) ;the linear regression equation of LAV and BPD was Y＝0 .046×BPD－2 .289 ( r ＝0 .910) ;the linear regression equation of RAV and BPD was Y＝0 .047×BPD－2 .348 ( r ＝0 .903) ;the linear regression equation of LAV and GA was Y ＝ 0 .122 × GA －2 .403 ( r ＝0 .952) ;the linear regression equation of RAV and GA was Y ＝0 .125×GA －2 .456 ( r ＝0 .942) . There was significant heteroscedasticity of standard deviation ( SD ) with increasing independent variables ,then weighted regression of absolute residuals was used in order to minimize the effect of heteroscedasticity ,and the linear regression equation was established . The linear regression equation of LAV-SD and FL was Y＝0 .005×FL －0 .119 ( r ＝0 .272) ;the linear regression equation of RAV-SD and FL was Y＝0 .005×FL －0 .104 ( r ＝0 .240) ;the linear regression equation of LAV-SD and BPD was Y＝ 0 .00375×BPD －0 .125 ( r＝0 .210) ;the linear regression equation of RAV-SD and BPD was Y＝0 .00375×BPD －0 .10875 ( r ＝0 .192) ;the linear regression equation of LAV-SD and GA is Y＝0 .0125×GA －0 .21125 ( r ＝0 .346) ;the linear regression equation of RAV-SD and GA was Y＝0 .0125×GA －0 .20875 ( r ＝0 .308) . According to these equations ,the Z-score calculation formula for LAV was ( measured LAV-predicted LAV from BPD , FL and GA)/SD of predicted LAV ; Z-score calculation formula for RAV was ( measured RAV －predicted RAV from BPD ,FL and GA)/SD of predicted RAV . Conclusions Fetal Z-scores references for the LAV and RAV can be established using common fetal biometrical parameters ( including FL ,BPD and GA utilizing statistical methods based on a large sample size) . This enhances accurate assessment of growth and development of fetal cardiac structures ,and provides novel insights for the determination of fetal atrial volume in fetuses with congenital heart disease .

3D Xplane Echocardiographic Technique for Validation of Mitral Leaflet Separation to Assess Severity of Mitral Stenosis.

BACKGROUND: Determining the severity of mitral stenosis (MS) is important for both prognostic and therapeutic implications. Mitral valve area (MVA) calculation techniques have more limitations. Mitral leaflet separation (MLS) is a precise and operator friendly alternative to planimetry. In contrast to previous researchers, we have used a novel 3D Xplane technique to validate MLS for assessing the severity of MS. 3D Xplane is superior for validation of MLS due to simultaneous real time acquisition of MLS in parasternal long-axis view and corresponding MVA by planimetry in parsternal short-axis view. METHODS: It was a prospective observational single center study. A total of 174 patients with MS were evaluated for MVA estimation by various echocardiographic modalities. Maximum leaflet separation and corresponding planimetered MVA were measured using novel 3D Xplane technique. RESULTS: With 3D Xplane technique, there was strong positive correlation between planimetered MVA and MLS (R = 0.925, P < 0.001), irrespective of coexisting MR (R = 0.886, P < 0.001) or AF (R = 0.912, P < 0.001). Receiver operating characteristic curves of MLS demonstrated AUC for mild and severe MS to be 0.966 and 0.995, respectively. MLS less than 8.62 mm predicted severe MS with 95.5% sensitivity and 94.7% specificity and MLS more than 12.23 mm predicted mild MS with 93.2% sensitivity and 91.4% specificity. CONCLUSION: In our study, a strong correlation between planimetered MVA and MLS was found using 3D Xplane technique. 3D Xplane thus validates and standardizes MLS by excluding errors due to temporal and spatial variations which are important limitations of 2D echocardiography.

Transthoracic two-dimensional xPlane and three-dimensional echocardiographic analysis of the site of mitral valve prolapse.

This study sought to assess the value of two-dimensional (2D) transthoracic echocardiography (TTE), 2D xPlane imaging and three-dimensional (3D) TTE for the definition of the site and the extent of mitral valve (MV) prolapse. Fifty patients underwent transthoracic 2D, 2D xPlane and 3D echocardiography. With 2D xPlane a segmental analysis of the MV was performed, by making a lateral sweep across the MV coaptation line as seen in the parasternal short-axis view. Inter-observer agreement for specific scallop prolapse was for 2D xPlane excellent (97%, kappa = 0.94) and for 3D TTE moderate (85%, kappa = 0.67). The respective sensitivities of standard 2D TTE, 2D xPlane, and 3D TTE for the identification of the precise posterior scallop prolapse were for P1 92, 85, and 92%, for P2 96, 96, and 82%, and for P3 86, 81, and 71%. In total, 5 (8%) prolapsing MV scallops were missed by 2D TTE, 7 (12%) by 2D xPlane, and 12 (20%) by 3D TTE. The sensitivity of 3D TTE was significantly lower than standard 2D imaging (80% versus 93%, P < 0.05). The extent of P2 prolapse was under or overestimated in 5 patients with 2D xPlane and in 9 patients with 3D TTE. 2D xPlane imaging is an accurate, easy to use (compared to 3D TTE) and easy to interpret (compared to 2D and 3D TTE) imaging modality to study the site and the extent of MV prolapse.