Sung Kwon Cho

A Review of PMMA Bone Cement and Intra-Cardiac Embolism

Percutaneous vertebroplasty procedure is of major importance, given the significantly increasing aging population and the higher number of orthopedic procedures related to vertebral compression fractures. Vertebroplasty is a complex technique involving the injection of polymethylmethacrylate (PMMA) into the compressed vertebral body for mechanical stabilization of the fracture. Our understanding and ability to modify these mechanisms through alterations in cement material is rapidly evolving. However, the rate of cardiac complications secondary to PMMA injection and subsequent cement leakage has increased with time. The following review considers the main effects of PMMA bone cement on the heart, and the extent of influence of the materials on cardiac embolism. Clinically, cement leakage results in life-threatening cardiac injury. The convolution of this outcome through an appropriate balance of complex material properties is highlighted via clinical case reports.

A retrievable rescue stent graft and radiofrequency positioning for rapid control of noncompressible hemorrhage.

BACKGROUND Noncompressible hemorrhage of the torso remains a challenging surgical dilemma. Stent graft repair requires endovascular expertise, imaging, and inventory that are not available within the critical window of massive hemorrhage. We developed a retrievable stent graft for rapid hemorrhage. We further investigated a radiofrequency (RF) positioning approach as a possible alternative to the logistics of fluoroscopy. METHODS A retrievable stent graft was constructed with a novel “petal and stem” design from nitinol and covered with a sleeve of electrospun polyurethane. The stent graft was tested using an in vitro model of simulated hemorrhage. Next, the stent graft was examined in vivo using a porcine model of noncompressible hemorrhage. The stent was examined for hemorrhage control in a porcine model of either aortic or caval injury. An RF reader was assembled from an Arduino processor while RF tags were affixed to the ends of the stent graft. Detection accuracy of a handheld RF wand for an RF tag was quantified both in vitro and through tissue. RESULTS The retrievable RESCUEstent graft was deployed within minutes and rapidly controlled traumatic hemorrhage angiographically in both aortic injury (n = 3) and caval injury (n = 2). Stent grafts were easily recaptured in both models in under 15 seconds. The LED light of a handheld RF detector illuminated when positioned directly over an RF tag. The RF detection approach revealed positioning accuracy to within 1 cm of the intended target, despite tissue interference. CONCLUSION This study demonstrates the rapid deployment and retrieval of a RESCUE stent graft as well as the ability to tamponade injuries of the aorta and cava. In addition, this study demonstrates the feasibility of RF tags to guide stent placement through tissue. More rigorous models are needed to define the effectiveness of this approach in the setting of vascular injury and shock.

A novel compartmentalised stent graft to isolate the perfusion of the abdominal organs.

Abstract Donation after cardiac death has been adopted to address the critical shortage of donor organs for transplant. Recovery of these organs is hindered by low blood flow that leads to permanent organ injury. We propose a novel approach to isolate the perfusion of the abdominal organs from the systemic malperfusion of the dying donor. We reasoned that this design could improve blood flow to organs without open surgery, while respecting the ethical principle that cardiac stress not be increased during organ recovery. Conditions within the stent were analysed using a computational fluid dynamics (CFD) method and validated on two prototypes in vitro. The hydrodynamic pressure drop across the stent was measured as 0.14–0.22 mmHg, which is a negligible influence. Device placement studies were also conducted on swine model fluoroscopically. All these results demonstrated the feasibility of rapidly isolating the perfusion to abdominal organs using a compartmentalised stent graft design.

A novel low profile wireless flow sensor to monitor hemodynamic changes in cerebral aneurysm

A proof of concept of low-profile flow sensor has been designed, fabricated, and subsequently tested to demonstrate its feasibility for monitoring hemodynamic changes in cerebral aneurysm. The prototype sensor contains three layers, i.e., a thin polyurethane layer was sandwiched between two sputter-deposited thin film nitinol layers (6μm thick). A novel superhydrophilic surface treatment was used to create hemocompatible surface of thin nitinol electrode layers. A finite element model was conducted using ANSYS Workbench 15.0 Static Structural to optimize the dimensions of flow sensor. A computational fluid dynamics calculations were performed using ANSYS Workbench Fluent to assess the flow velocity patterns within the aneurysm sac. We built a test platform with a z-axis translation stage and an S-beam load cell to compare the capacitance changes of the sensors with different parameters during deformation. Both LCR meter and oscilloscope were used to measure the capacitance and the resonant frequency shifts, respectively. The experimental compression tests demonstrated the linear relationship between the capacitance and applied compression force and decreasing the length, width and increasing the thickness improved the sensor sensitivity. The experimentally measured resonant frequency dropped from 12.7MHz to 12.48MHz, indicating a 0.22MHz shift with 200g ( 2N) compression force while the theoretical resonant frequency shifted 0.35MHz with 50g ( 0.5N). Our recent results demonstrated a feasibility of the low-profile flow sensor for monitoring haemodynamics in cerebral aneurysm region, as well as the efficacy of the use of the surface treated thin film nitinol for the low-profile sensor materials.

On a path toward structures with reconfigurable circulatory systems

In order to provide structures with new and better characteristics, researchers often look to biological systems for inspiration. One trait that many biological system have that conventional structures do not is a circulatory system, which can be used for many purposes, one of which is the transport of structural material. This paper explores the benefits of transporting structural material for the purpose of changing the structures static and dynamic characteristics. Several scenarios are explored, including the transport of non-load-bearing mass (mass transport) to load-bearing mass (termed stiffness transport). It is argued that stiffness transport, while more complex than simply moving mass within a structure, affords the same features as mass transport, along with several unconventional and particularly useful abilities.