Your search keyword '"Dean, Ethan W"' showing total 4 results

1. Clinical outcomes related to glenosphere overhang in reverse shoulder arthroplasty using a lateralized humeral design.

Author

Dean, Ethan W., Dean, Natalie E., Wright, Thomas W., Hao, Kevin A., Schoch, Bradley S., Farmer, Kevin W., Struk, Aimee M., and King, Joseph J.

Abstract

Previous studies have demonstrated that decreased impingement-free range of motion (ROM) can adversely influence clinical outcomes following reverse shoulder arthroplasty (RSA). Inferior placement of the glenosphere is thought to minimize impingement and its associated sequelae. This study evaluated the relationship between inferior overhang of the glenosphere and clinical outcomes in patients undergoing primary RSA using a lateralized humeral implant design. By use of a prospectively collected shoulder arthroplasty database, all primary RSAs performed at our institution between 2007 and 2015 with a single implant design (lateralized humerus and medialized glenoid) and minimum 2-year follow-up were evaluated. Glenosphere overhang in relation to the inferior rim of the glenoid was measured in millimeters on postoperative Grashey radiographs of the shoulder and categorized into tertiles (low, <7.1 mm; medium, 7.1 to 9.9 mm; and high, >9.9 mm). Clinical outcomes of interest comprised the changes between preoperative and postoperative values in the following ROM and outcome score measures: active forward elevation (aFE), active external rotation, American Shoulder and Elbow Surgeons score, Constant-Murley score, Shoulder Pain and Disability Index score, and Simple Shoulder Test score. Random-effects linear models were used to assess univariate and multivariable associations between overhang tertile and change in patient outcomes. Differences in outcomes were further compared using the minimal clinically important difference (MCID). The study identified 284 shoulders in 265 patients. The median follow-up period was 36 months (range, 24-108 months). The median glenosphere inferior overhang was 8.4 mm, with an interquartile range of 6.3-10.6 mm. Plots demonstrated nonlinear relationships between overhang and outcome scores and between overhang and ROM. Patients with high overhang experienced a significantly greater improvement in aFE compared with patients with low overhang (P =.019), which exceeded the MCID. No other differences in ROM and outcome scores between overhang groups exceeded the MCID. For other outcome scores and ROM measurements, there was no significant relationship with glenosphere overhang. Increased overhang was associated with a significantly lower incidence of scapular notching (P =.005). Patients undergoing RSA using a lateralized humerus design with greater inferior overhang of the glenosphere demonstrated a significantly greater improvement in aFE and lower rate of notching compared with those with low overhang. No ideal glenosphere overhang range was identified to maximize function in this study. [ABSTRACT FROM AUTHOR]

Published

2022

2. Preoperative shoulder strength is associated with postoperative primary anatomic total shoulder arthroplasty outcomes and improvement.

Author

Hao, Kevin A., Wright, Thomas W., Dean, Ethan W., Struk, Aimee M., and King, Joseph J.

Abstract

Although numerous preoperative factors that influence postoperative outcomes after anatomic total shoulder arthroplasty (aTSA) have been identified, preoperative shoulder strength has not been studied. The purpose of this study was to determine whether preoperative shoulder strength is predictive of postoperative outcomes and improvement after primary aTSA. We conducted a retrospective review of prospectively collected data from 160 shoulders with minimum 2-year follow-up after primary aTSA. Preoperative external rotation (ER) strength, supraspinatus strength, and abduction strength score were analyzed to determine their correlation with postoperative outcomes and improvement in shoulder strength, range of motion (ROM), and outcome scores. Multiple linear regression models were subsequently used to adjust for covariates and determine the preoperative measures of shoulder strength that most influenced postoperative outcomes and improvement. Preoperative ER strength, supraspinatus strength, and abduction strength score were each moderately correlated with their respective postoperative values and improvement (P <.001 for all). A decrease in ER strength, supraspinatus strength, and abduction strength score postoperatively was identified for preoperative strength values > 8.2 kg, > 6.6 kg, and > 4.5 kg, respectively. In contrast, no upper limit of preoperative shoulder strength led to a decrease in ROM or outcome scores postoperatively. On multivariate analysis, the baseline abduction strength score was a statistically significant predictor of postoperative values and improvement for all 3 measures of shoulder strength, raw and normalized Constant scores, and improvement in active abduction and active elevation. Preoperative shoulder strength is moderately associated with postoperative outcomes and improvements in shoulder strength, ROM, and outcome scores after primary aTSA. It is important to note that we identified preoperative strength values that led to a decrease in strength postoperatively but not ROM or outcome scores. The results of our study demonstrate that abduction strength may be a useful indicator of patient outcomes after aTSA. Our findings will provide surgeons with useful prognostic insight to aid in guiding patient expectations. [ABSTRACT FROM AUTHOR]

Published

2022

3. Differential outcomes of venous and arterial tissue engineered vascular grafts highlight the importance of coupling long-term implantation studies with computational modeling.

Author

Best, Cameron A., Szafron, Jason M., Rocco, Kevin A., Zbinden, Jacob, Dean, Ethan W., Maxfield, Mark W., Kurobe, Hirotsugu, Tara, Shuhei, Bagi, Paul S., Udelsman, Brooks V., Khosravi, Ramak, Yi, Tai, Shinoka, Toshiharu, Humphrey, Jay D., and Breuer, Christopher K.

Subjects

VASCULAR grafts, TISSUE engineering, ARTERIAL grafts, TISSUE scaffolds, VASCULAR remodeling, EXTRACELLULAR matrix

Abstract

Electrospinning is commonly used to generate polymeric scaffolds for tissue engineering. Using this approach, we developed a small-diameter tissue engineered vascular graft (TEVG) composed of poly-ε-caprolactone-co- l -lactic acid (PCLA) fibers and longitudinally assessed its performance within both the venous and arterial circulations of immunodeficient (SCID/bg) mice. Based on in vitro analysis demonstrating complete loss of graft strength by 12 weeks, we evaluated neovessel formation in vivo over 6-, 12- and 24-week periods. Mid-term observations indicated physiologic graft function, characterized by 100% patency and luminal matching with adjoining native vessel in both the venous and arterial circulations. An active and robust remodeling process was characterized by a confluent endothelial cell monolayer, macrophage infiltrate, and extracellular matrix deposition and remodeling. Long-term follow-up of venous TEVGs at 24 weeks revealed viable neovessel formation beyond graft degradation when implanted in this high flow, low-pressure environment. Arterial TEVGs experienced catastrophic graft failure due to aneurysmal dilatation and rupture after 14 weeks. Scaffold parameters such as porosity, fiber diameter, and degradation rate informed a previously described computational model of vascular growth and remodeling, and simulations predicted the gross differential performance of the venous and arterial TEVGs over the 24-week time course. Taken together, these results highlight the requirement for in vivo implantation studies to extend past the critical time period of polymer degradation, the importance of differential neotissue deposition relative to the mechanical (pressure) environment, and further support the utility of predictive modeling in the design, use, and evaluation of TEVGs in vivo. Herein, we apply a biodegradable electrospun vascular graft to the arterial and venous circulations of the mouse and follow recipients beyond the point of polymer degradation. While venous implants formed viable neovessels, arterial grafts experienced catastrophic rupture due to aneurysmal dilation. We then inform a previously developed computational model of tissue engineered vascular graft growth and remodeling with parameters specific to the electrospun scaffolds utilized in this study. Remarkably, model simulations predict the differential performance of the venous and arterial constructs over 24 weeks. We conclude that computational simulations should inform the rational selection of scaffold parameters to fabricate tissue engineered vascular grafts that must be followed in vivo over time courses extending beyond polymer degradation. [ABSTRACT FROM AUTHOR]

Published

2019

4. Characterization of evolving biomechanical properties of tissue engineered vascular grafts in the arterial circulation.

Author

Udelsman, Brooks V., Khosravi, Ramak, Miller, Kristin S., Dean, Ethan W., Bersi, Matthew R., Rocco, Kevin, Tai Yi, Humphrey, Jay D., and Breuer, Christopher K.

Subjects

*BIOMECHANICS, *TISSUE engineering, *VASCULAR grafts, *BLOOD circulation, *COLLAGEN

Abstract

We used a murine model to assess the evolving biomechanical properties of tissue engineered vascular grafts (TEVGs) implanted in the arterial circulation. The initial polymeric tubular scaffold was fabricated from poly(lactic acid)(PLA) and coated with a 50:50 copolymer of poly(caprolactone) and poly(lactic acid)(P[PC/LA]). Following seeding with syngeneic bone marrow derived mononuclear cells, TEVGs (n=50) were implanted as aortic interposition grafts in wild-type mice and monitored serially using ultrasound. A custom biaxial mechanical testing device was used to quantify the in vitro circumferential and axial mechanical properties of grafts explanted at 3 or 7 months. At both times, TEVGs were much stiffer than native tissue in both directions. Repeated mechanical testing of some TEVGs treated with elastase or collagenase suggested that elastin did not contribute significantly to the overall stiffness whereas collagen did contribute. Traditional histology and immunostaining revealed smooth muscle cell layers, significant collagen deposition, and increasing elastin production in addition to considerable scaffold at both 3 and 7 months, which likely dominated the high stiffness seen in mechanical testing. These results suggest that PLA has inadequate in vivo degradation, which impairs cell-mediated development of vascular neotissue having properties closer to native arteries. Assessing contributions of individual components, such as elastin and collagen, to the developing neovessel is needed to guide computational modeling that may help to optimize the design of the TEVG. [ABSTRACT FROM AUTHOR]

Published

2014