Shaphan R. Jernigan scite author profile

BackgroundLiver tumors are increasingly treated with radioembolization. Here, we present first evidence of catheter design effect on particle-fluid dynamics and downstream branch targeting during microsphere administrations.Materials and methods A total of 7 experiments were performed in a bench-top model of the hepatic arterial vasculature with recreated hemodynamics. Fluorescent microspheres and clinically used holmium microspheres were administered with a standard microcatheter (SMC) and an anti-reflux catheter (ARC) positioned at the same level along the longitudinal vessel axis. Catheter-related particle flow dynamics were analyzed by reviewing video recordings of UV-light illuminated fluorescent microsphere administrations. Downstream branch distribution was analyzed by quantification of collected microspheres in separate filters for two first-order branches. Mean deviation from a perfectly homogenous distribution (DHD) was used to compare the distribution homogeneity between catheter types.ResultsThe SMC administrations demonstrated a random off-centered catheter position (in 71 % of experiments), and a laminar particle flow pattern with an inhomogeneous downstream branch distribution, dependent on catheter position and injection force. The ARC administrations demonstrated a fixed centro-luminal catheter position, and a turbulent particle flow pattern with a more consistent and homogenous downstream branch distribution. Quantitative analyses confirmed a significantly more homogeneous distribution with the ARC; the mean DHD was 40.85 % (IQR 22.76 %) for the SMC and 15.54 % (IQR 6.46 %) for the ARC (p = 0.047).ConclusionCatheter type has a significant impact on microsphere administrations in an in-vitro hepatic arterial model. A within-patient randomized controlled trial has been initiated to investigate clinical catheter-related effects during radioembolization treatment.Electronic supplementary materialThe online version of this article (doi:10.1186/s13046-015-0188-8) contains supplementary material, which is available to authorized users.

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A laparoscopic knot-tying device for minimally invasive cardiac surgery☆

Jernigan¹,

Chanoit²,

Veeramani³

et al. 2010

European Journal of Cardio-Thoracic Surgery

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Objectives Intracorporeal suturing and knot tying can complicate, prolong or preclude minimally invasive surgical procedures, reducing their advantages over conventional approaches. An automated knot-tying device has been developed to speed suture fixation during minimally invasive cardiac surgery while retaining the desirable characteristics of conventional hand-tied surgeon's knots: holding strength and visual and haptic feedback. A rotating slotted disk (at the instrument's distal end) automates overhand throws, thereby eliminating the need to manually pass one suture end through a loop in the opposing end. Electronic actuation of this disk produces left or right overhand knots as desired by the operator. Methods To evaluate the effectiveness of this technology, 7 surgeons with varying laparoscopic experience tied knots within a simulated minimally invasive setting, using both the automated knot-tying tool and conventional laparoscopic tools. Suture types were 2-0 braided and 4-0 monofilament. Results Mean knot-tying times were 246 ±116 seconds and 102 ±46 seconds for conventional and automated methods, respectively, showing an average 56% reduction in time per surgeon (p=0.003, paired t-test). The peak holding strength of each knot (the force required to break the suture or loosen the knot) was measured using tensile testing equipment. These peak holding strengths were normalized by the ultimate tensile strength of each suture type (57.5 N and 22.1 N for 2-0 braided and 4-0 monofilament, respectively). Mean normalized holding strengths for all knots were 68.2% and 71.8% of ultimate tensile strength for conventional and automated methods, respectively (p= 0.914, paired t-test). Conclusions Experimental data reveal that the automated suturing device has great potential for advancing minimally invasive surgery: it significantly reduced knot-tying times while providing equivalent or greater holding strength than conventionally tied knots.

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Finite Element Modeling of the Left Atrium to Facilitate the Design of an Endoscopic Atrial Retractor

Jernigan

Buckner

Eischen

et al. 2007

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A finite element model of the left atrium, incorporating detailed anatomical features and realistic material characteristics, was built to investigate the interaction of heart tissue and surgical instruments. This model was used to facilitate the design of an endoscopically deployable atrial retractor for use in minimally invasive, robotically assisted (MIRA) mitral valve repair. The left atrial geometry was imported directly from MRI data of an explanted porcine heart, and material properties were derived from experimental testing of cardiac tissues. Model accuracy was verified by comparing simulated cardiac wall deflections to those measured by MRI. Finite element analysis was shown to be an effective tool for analyzing instrument/tissue interactions and for designing surgical instruments.

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Solid Tumor Embolotherapy in Hepatic Arteries with an Anti-reflux Catheter System

Jernigan

Kleinstreuer

et al. 2015

Ann Biomed Eng

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Unresectable hepatoma accounts for the majority of malignant liver tumor cases for which embolization therapy is considered a viable treatment option. However, the potential risk of aberrant particle deposition in non-target regions could cause severe side-effects, alongside diminished efficacy. A computational model has been developed to analyze the particle-hemodynamics before and after deployment of an FDA-approved anti-reflux catheter. The catheter features a retractable, porous cone-like tip designed to allow forward blood flow while preventing microsphere reflux. A patient-specific hepatic artery system, with different daughter branches connected to a liver tumor, was chosen as a representative test bed. In vitro as well as in vivo measurements were used to validate the computer simulation model. The model captures the effect of tip-deployment on blood perfusion and pressure drop in an interactive manner under physiologically realistic conditions. A relationship between the pressure drop and embolization level was established, which can be used to provide clinicians with real-time information on the best infusion-stop point. However, the results show that the present procedure for embolization of downstream vessels which feed a tumor is quite arbitrary. Nevertheless, a method to recycle aberrant particles captured by the deployed tip was proposed to minimize side-effects.

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