Your search keyword '"Morsi YS"' showing total 28 results

1. The influence of non-Newtonian characteristics of blood on the patient-specific left ventricle

Author

Australian Biomedical Engineering Conference (2015 : Melbourne, Vic.), Doost, SN, Zhong, L, Su, B, and Morsi, YS

Published

2015

2. Population structure and phylogenetic relationships in Brassica rapa L. subspecies by using isozyme markers.

Author

Sammour RH, Karam MA, Morsi YS, and Ali RM

Subjects

Genetic Variation genetics, Isoenzymes genetics, Phylogeny, Plant Breeding, Brassica napus, Brassica rapa genetics

Abstract

The present study aimed to assess population structure and phylogenetic relationships of nine subspecies of Brassica rapa L. represented with thirty-five accessions cover a wide range of species distribution area using isozyme analysis in order to select more diverse accessions as supplementary resources that can be utilized for improvement of B. napus. Enzyme analysis resulted in detecting 14 putative polymorphic loci with 27 alleles. Mean allele frequency 0.04 (rare alleles) was observed in Cat4A and Cat4B in sub species Oleifera accession CR 2204/79 and in subspecies trilocularis accessions CR 2215/88 and CR 2244/88. The highest genetic diversity measures were observed in subspecies dichotoma, accession CR 1585/96 (the highest average of observed (H0) and expected heterozygosity (He), and number of alleles per locus (Ae)). These observations make this accession valuable genetic resource to be included in breeding programs for the improvement of oilseed B. napus. The average fixation index (F) is significantly higher than zero for the analysis accessions indicating a significant deficiency of heteozygosity. The divergence among subspecies indicated very great genetic differentiation (FST = 0.8972) which means that about 90% of genetic diversity is distributed among subspecies, while 10% of the diversity is distributed within subspecies. This coincides with low value of gene flow (Nm = 0.0287). B. rapa ssp. oleifera (turnip rape) and B. rapa ssp. trilocularis (sarson) were grouped under one cluster which coincides with the morphological classification.

Published

2021

3. Effect of elasticity on electrospun styrene-butadiene-styrene fibrous membrane cell culture behaviors.

Author

Awad NK, Wong CS, Zhou H, Niu H, Wang H, Morsi YS, and Lin T

Subjects

Cell Culture Techniques, Elasticity, Endothelial Cells, Butadienes toxicity, Styrene toxicity

Abstract

In this study, elastic styrene-butadiene-styrene (SBS), non-elastic SBS and their blends at different ratios were electrospun into fibrous membranes and their cell biocompatibility was evaluated. The as-spun fibers showed an average fiber diameter of 2 µm, and the fibrous membranes had pore size of 8 ± 0.01 µm. The blending ratios of the elastic with non-elastic SBSs showed little effect on fibrous structure, but affected the mechanical properties. All SBS membrane showed no cytotoxicity on endothelial cells (ECs). ECs attached and proliferated on all the SBS fibrous membrane scaffolds regardless of their elasticity. ECs maintained their polygonal shape on the scaffolds and they tended to orient along the fiber length. The SBS fibrous samples with elastic:non-elastic SBS weight ratios of 1:1 and 2:3 showed better cell viability than that of elastic and non-elastic SBS.

Published

2020

4. Electrospun Fibrous Scaffolds for Small-Diameter Blood Vessels: A Review.

Author

Awad NK, Niu H, Ali U, Morsi YS, and Lin T

Abstract

Small-diameter blood vessels (SDBVs) are still a challenging task to prepare due to the occurrence of thrombosis formation, intimal hyperplasia, and aneurysmal dilation. Electrospinning technique, as a promising tissue engineering approach, can fabricate polymer fibrous scaffolds that satisfy requirements on the construction of extracellular matrix (ECM) of native blood vessel and promote the adhesion, proliferation, and growth of cells. In this review, we summarize the polymers that are deployed for the fabrication of SDBVs and classify them into three categories, synthetic polymers, natural polymers, and hybrid polymers. Furthermore, the biomechanical properties and the biological activities of the electrospun SBVs including anti-thrombogenic ability and cell response are discussed. Polymer blends seem to be a strategic way to fabricate SDBVs because it combines both suitable biomechanical properties coming from synthetic polymers and favorable sites to cell attachment coming from natural polymers., Competing Interests: The authors declare no conflict of interest.

Published

2018

5. A review of TiO 2 NTs on Ti metal: Electrochemical synthesis, functionalization and potential use as bone implants.

Author

Awad NK, Edwards SL, and Morsi YS

Subjects

Electrochemical Techniques, Nanotubes, Osseointegration, Quality of Life, Surface Properties, Titanium, Prostheses and Implants

Abstract

Degenerative diseases of bone such as osteoarthritis and osteoporosis can lead to bone fractures and immobility, compromising quality of life. Titanium (Ti)-based implants have been intensively investigated for bone repair, with these implants, demonstrating improved outcomes compared to stainless steel and cobalt-chrome alloys, owing to superior mechanical properties and biocompatibility. However, osseointegration between the Ti-based implants and the surrounding bone tissue needs to be improved. Surface modification of Ti-based implants provides a solution for addressing this, with electrochemical anodization becoming a realistic approach for the fabrication of hierarchical structured for example nanotubes (NTs), implant surfaces. Using this technique, biocompatibility and osteogenesis of the implant may be improved, by providing an appropriate site for bone cell attachment. In this review, we discuss the anodization of Ti-based implants as an approach for creating titanium dioxide nanotubes (TiO 2 NTs) on the implant surface. We further discuss the various ways of functionalizing the NT surface, to reduce post-operative infection and improve implant biocompatibility and osseointegration., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

6. Two-dimensional intraventricular flow pattern visualization using the image-based computational fluid dynamics.

Author

Doost SN, Zhong L, Su B, and Morsi YS

Subjects

Aortic Valve physiology, Blood Flow Velocity physiology, Humans, Mitral Valve physiology, Models, Cardiovascular, Numerical Analysis, Computer-Assisted, Computer Simulation, Hemodynamics physiology, Hydrodynamics, Image Processing, Computer-Assisted, Ventricular Function physiology

Abstract

The image-based computational fluid dynamics (IB-CFD) technique, as the combination of medical images and the CFD method, is utilized in this research to analyze the left ventricle (LV) hemodynamics. The research primarily aims to propose a semi-automated technique utilizing some freely available and commercial software packages in order to simulate the LV hemodynamics using the IB-CFD technique. In this research, moreover, two different physiological time-resolved 2D models of a patient-specific LV with two different types of aortic and mitral valves, including the orifice-type valves and integrated with rigid leaflets, are adopted to visualize the process of developing intraventricular vortex formation and propagation. The blood flow pattern over the whole cardiac cycle of two models is also compared to investigate the effect of utilizing different valve types in the process of the intraventricular vortex formation. Numerical findings indicate that the model with integrated valves can predict more complex intraventricular flow that can match better the physiological flow pattern in comparison to the orifice-type model.

Published

2017

7. Heart blood flow simulation: a perspective review.

Author

Doost SN, Ghista D, Su B, Zhong L, and Morsi YS

Subjects

Heart Diseases physiopathology, Humans, Hydrodynamics, Patient-Specific Modeling, Coronary Circulation, Models, Cardiovascular

Abstract

Cardiovascular disease (CVD), the leading cause of death today, incorporates a wide range of cardiovascular system malfunctions that affect heart functionality. It is believed that the hemodynamic loads exerted on the cardiovascular system, the left ventricle (LV) in particular, are the leading cause of CVD initiation and propagation. Moreover, it is believed that the diagnosis and prognosis of CVD at an early stage could reduce its high mortality and morbidity rate. Therefore, a set of robust clinical cardiovascular assessment tools has been introduced to compute the cardiovascular hemodynamics in order to provide useful insights to physicians to recognize indicators leading to CVD and also to aid the diagnosis of CVD. Recently, a combination of computational fluid dynamics (CFD) and different medical imaging tools, image-based CFD (IB-CFD), has been widely employed for cardiovascular functional assessment by providing reliable hemodynamic parameters. Even though the capability of CFD to provide reliable flow dynamics in general fluid mechanics problems has been widely demonstrated for many years, up to now, the clinical implications of the IB-CFD patient-specific LVs have not been applicable due to its limitations and complications. In this paper, we review investigations conducted to numerically simulate patient-specific human LV over the past 15 years using IB-CFD methods. Firstly, we divide different studies according to the different LV types (physiological and different pathological conditions) that have been chosen to reconstruct the geometry, and then discuss their contributions, methodologies, limitations, and findings. In this regard, we have studied CFD simulations of intraventricular flows and related cardiology insights, for (i) Physiological patient-specific LV models, (ii) Pathological heart patient-specific models, including myocardial infarction, dilated cardiomyopathy, hypertrophic cardiomyopathy and hypoplastic left heart syndrome. Finally, we discuss the current stage of the IB-CFD LV simulations in order to mimic realistic hemodynamics of patient-specific LVs. We can conclude that heart flow simulation is on the right track for developing into a useful clinical tool for heart function assessment, by (i) incorporating most of heart structures' (such as heart valves) operations, and (ii) providing useful diagnostic indices based hemodynamic parameters, for routine adoption in clinical usage.

Published

2016

8. The numerical analysis of non-Newtonian blood flow in human patient-specific left ventricle.

Author

Doost SN, Zhong L, Su B, and Morsi YS

Subjects

Humans, Coronary Circulation, Heart Ventricles diagnostic imaging, Models, Theoretical

Abstract

Recently, various non-invasive tools such as the magnetic resonance image (MRI), ultrasound imaging (USI), computed tomography (CT), and the computational fluid dynamics (CFD) have been widely utilized to enhance our current understanding of the physiological parameters that affect the initiation and the progression of the cardiovascular diseases (CVDs) associated with heart failure (HF). In particular, the hemodynamics of left ventricle (LV) has attracted the attention of the researchers due to its significant role in the heart functionality. In this study, CFD owing its capability of predicting detailed flow field was adopted to model the blood flow in images-based patient-specific LV over cardiac cycle. In most published studies, the blood is modeled as Newtonian that is not entirely accurate as the blood viscosity varies with the shear rate in non-linear manner. In this paper, we studied the effect of Newtonian assumption on the degree of accuracy of intraventricular hemodynamics. In doing so, various non-Newtonian models and Newtonian model are used in the analysis of the intraventricular flow and the viscosity of the blood. Initially, we used the cardiac MRI images to reconstruct the time-resolved geometry of the patient-specific LV. After the unstructured mesh generation, the simulations were conducted in the CFD commercial solver FLUENT to analyze the intraventricular hemodynamic parameters. The findings indicate that the Newtonian assumption cannot adequately simulate the flow dynamic within the LV over the cardiac cycle, which can be attributed to the pulsatile and recirculation nature of the flow and the low blood shear rate., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published

2016

9. Bioengineering strategies for polymeric scaffold for tissue engineering an aortic heart valve: an update.

Author

Morsi YS

Subjects

Animals, Aortic Valve physiopathology, Heart Valve Diseases diagnosis, Heart Valve Diseases physiopathology, Heart Valve Prosthesis Implantation methods, Hemodynamics, Humans, Prosthesis Design, Aortic Valve transplantation, Bioprosthesis, Heart Valve Diseases surgery, Heart Valve Prosthesis, Heart Valve Prosthesis Implantation instrumentation, Polymers chemistry, Tissue Engineering methods, Tissue Scaffolds

Abstract

The occurrence of dysfunctional aortic valves is increasing every year, and current replacement heart valves, although having been shown to be clinically successful, are only short-term solutions and suffer from many agonizing long-term drawbacks. The tissue engineering of heart valves is recognized as one of the most promising answers for aortic valve disease therapy, but overcoming current shortcomings will require multidisciplinary efforts. The use of a polymeric scaffold to guide the growth of the tissue is the most common approach to generate a new tissue for an aortic heart valve. However, optimizing the design of the scaffold, in terms of biocompatibility, surface morphology for cell attachments and the correct rate of degradation is critical in creating a viable tissue-engineered aortic heart valve. This paper highlights the bioengineering strategies that need to be followed to construct a polymeric scaffold of sufficient mechanical integrity, with superior surface morphologies, that is capable of mimicking the valve dynamics in vivo. The current challenges and future directions of research for creating tissue-engineered aortic heart valves are also discussed.

Published

2014

10. Fluid structure interaction (FSI) simulation of the left ventricle (LV) during the early filling wave (E-wave), diastasis and atrial contraction wave (A-wave).

Author

Arefin MS and Morsi YS

Subjects

Algorithms, Computer Simulation, Hemodynamics physiology, Humans, Heart Ventricles anatomy & histology, Models, Cardiovascular, Ventricular Function physiology

Abstract

In this paper, the hemodynamic characteristics inside a physiologically correct three-dimensional LV model using fluid structure interaction scheme are examined under various heart beat conditions during early filling wave (E-wave), diastasis and atrial contraction wave (A-wave). The time dependent and incompressible viscous fluid, nonlinear viscous fluid and the stress tensor equations are coupled with the full Navier-Stoke's equations together with the Arbitrary Lagrangian-Eulerian and elasticity in the solid domain are used in the analysis. The results are discussed in terms of the variation in the intraventricular pressure, wall shear stress (WSS) and the fluid flow patterns inside the LV model. Moreover, changes in the magnitude of displacements on the LV are also observed during diastole period. The results obtained demonstrate that the magnitude of the intraventricle pressure is found higher in the basal region of the LV during the beginning of the E-wave and A-wave, whereas the Ip is found much higher in the apical region when the flow propagation is in peak E-wave, peak A-wave and diastasis. The magnitude of the pressure is found to be 5.4E2 Pa during the peak E-wave. Additionally, WSS elevates with the rise in the E-wave and A-wave but the magnitude decreases during the diastasis phase. During the peak E-wave, maximum WSS is found to be 5.7 Pa. Subsequent developments, merging and shifting of the vortices are observed throughout the filling wave. Formations of clockwise vortices are evident during the peak E-wave and at the onset of the A-wave, but counter clockwise vortices are found at the end of the diastasis and at the beginning of the A-wave. Moreover, the maximum magnitude of the structural displacement is seen in the ventricle apex with the value of 3.7E-5 m.

Published

2014

11. A parametric study on mathematical formulation and geometrical construction of a stentless aortic heart valve.

Author

Kouhi E and Morsi YS

Subjects

Feasibility Studies, Humans, Sinus of Valsalva anatomy & histology, Aortic Valve anatomy & histology, Heart Valve Prosthesis, Models, Cardiovascular

Abstract

This study presents a novel methodology for constructing an accurate geometrical model of a stentless aortic heart valve replacement (AVR). The main objective is to propose an optimized AVR model that can be used as an ideal scaffold for tissue engineering applications or a biocompatible prosthesis. Current techniques available for creating heart valve geometry, including leaflets, are very complicated and are not precise, due to the extensive use of various complicated parameters. This paper introduces an alternative design procedure that uses limited and effective numbers of controlling parameters to construct the whole valve including the sinus of valsalva. In doing so the hyperbolic curves for multithickness leaflets are used and a 3D elliptical formulation is incorporated for the surface geometry of the sinus of valsalva. Still, the feasibility and the precision of the mathematical method are established by performing standard deviation analysis on the constructed surfaces. The surface fitting residuals are found as low as error 0.2351 mm with standard deviation of 8.83e-5 over the commissural lines. Preliminary validation to the proposed AVR model performance is achieved by testing the generated AVR model under quasi static condition while obtaining the mesh independent setup. The numerical model showed a rapid response of the leaflets to the transvalvular pressure where adequate values of stress are measured over the commissural lines.

Published

2013

12. Numerical analysis of coronary artery bypass grafts: an over view.

Author

Owida AA, Do H, and Morsi YS

Subjects

Anastomosis, Surgical, Compliance, Humans, Coronary Artery Bypass

Abstract

Arterial bypass grafts tend to fail after some years due to the development of intimal thickening (restenosis). Non-uniform hemodynamics following a bypass operation contributes to restenosis and bypass failure can occur due to the focal development of anastomotic intimal hyperplasia. Additionally, surgical injury aggravated by compliance mismatch between the graft and artery has been suggested as an initiating factor for progress of wall thickening along the suture line Vascular grafts that are small in diameter tend to occlude rapidly. Computational fluid dynamics (CFD) methods have been effectively used to simulate the physical and geometrical parameters characterizing the hemodynamics of various arteries and bypass configurations. The effects of such changes on the pressure and flow characteristics as well as the wall shear stress during a cardiac cycle can be simulated. Recently, utilization of fluid and structure interactions have been used to determine fluid flow parameters and structure forces including stress and strains relationships under steady and transient conditions. In parallel to this, experimental diagnostics techniques such as Laser Doppler Anemometry, Particle Image Velocimetry, Doppler Guide wire and Magnetic Resonance Imaging have been used to provide essential information and to validate the numerical results. Moreover, clinical imaging techniques such as magnetic resonance or computed tomography have assisted considerably in gaining a detailed patient-specific picture of the blood flow and structure dynamics. This paper gives a review of recent numerical investigations of various configurations of coronary artery bypass grafts (CABG). In addition, the paper ends with a summary of the findings and the future directions., (Copyright © 2011 Elsevier Ireland Ltd. All rights reserved.)

Published

2012

13. Graft-artery junctions: design optimization and CAD development.

Author

Morsi YS, Owida AA, Do H, Arefin MS, and Wang X

Subjects

Animals, Humans, Hydrodynamics, Prosthesis Design, Arteries surgery, Biocompatible Materials chemistry, Blood Vessel Prosthesis, Computer-Aided Design

Abstract

Designing and manufacturing of vascular prosthesis for arterial bypass grafts is a very complex problem. The process involves the selection of suitable geometry, materials of appropriate characteristics, and manufacturing technique capable of constructing prosthesis in a cost-effective manner. In this chapter, all engineering aspects related to the design and optimization of an artificial graft are presented and discussed. These aspects include CAD design of the graft, in vitro hemodynamic analysis to ensure good mechanical integrity and functionality, and optimization of the manufacturing techniques. Brief discussion is also given on the endothelization and vascularization of the artificial vessels and the future directions of the development of synthetic vessels for human implementation.

Published

2012

14. Gentamicin-impregnated chitosan/nanohydroxyapatite/ethyl cellulose microspheres granules for chronic osteomyelitis therapy.

Author

Shi P, Zuo Y, Li X, Zou Q, Liu H, Zhang L, Li Y, and Morsi YS

Subjects

Animals, Cell Death drug effects, Cell Survival drug effects, Cellulose pharmacology, Chronic Disease, Fibroblasts cytology, Fibroblasts drug effects, Fibroblasts metabolism, Gentamicins pharmacology, Humans, Implants, Experimental, Nanostructures ultrastructure, Osteoblasts cytology, Osteoblasts drug effects, Osteoblasts metabolism, Osteomyelitis pathology, Rabbits, Radiography, Rats, Rats, Wistar, Staphylococcus aureus drug effects, Tibia diagnostic imaging, Tibia drug effects, Tibia microbiology, Tibia pathology, Cellulose analogs & derivatives, Chitosan pharmacology, Durapatite pharmacology, Gentamicins therapeutic use, Microspheres, Nanostructures chemistry, Osteomyelitis drug therapy

Abstract

In this article gentamicin (GM) impregnated microspheres were used to extend the drug release time for the treatment of chronic osteomyelitis. The granules were prepared in solution and consisted of nanohydroxyapatite (nHA), chitosan (CS) and GM loaded ethyl cellulose (EC) microspheres. A rabbit model with chronic osteomyelitis was made by using staphylococcus aureus and morrhuate sodium and special inspection methods were used to test the curative effects of the granules, such as microbiological investigations, tissue, and X-ray observations. The granules were provided with excellent drug release properties, 49 days in vitro and 45 days in vivo, moreover, they showed almost no cytotoxic for fibroblast and osteoblast. The findings indicated that the GM-impregnated CS/nHA/EC microspheres granules showed outstanding curative effect. Generally, it can be concluded that the granules containing GM impregnated microspheres may be used effectively in the treatment of the chronic osteomyelitis.

Published

2010

15. Microwave sterilization of bovine pericardium for heart valve applications.

Author

Patel SS, Owida AA, and Morsi YS

Subjects

Animals, Cattle, Escherichia coli isolation & purification, Materials Testing, Microscopy, Electron, Scanning, Microwaves, Staphylococcus aureus isolation & purification, Tensile Strength, Bioprosthesis microbiology, Heart Valve Prosthesis microbiology, Heart Valve Prosthesis Implantation methods, Sterilization methods

Abstract

It is widely recognised that the bioprosthetic valves widely used for heart valve replacements have some drawbacks, for example tearing and occurrence of infections, which can be attributed to the fixation and sterilization techniques currently available. These techniques adversely affect the physical properties, functionality, and lifespan of the leaflets. In the work discussed in this paper we examined a novel procedure of using high-frequency microwaves to fix and disinfect the pericardium, without causing any harmful affects. The test bacteria used were Escherichia coli and Staphylococcus aureus. The pericardium was exposed to microwaves at a frequency of 18 GHz for three consecutive replicates. The findings indicated that there was almost complete inactivation of the bacteria on the biomaterial without compromising the biocompatibility, which was studied using ovine fibroblasts. An effective fixation and sterilization procedure, that is quick and has no adverse effects is presented and discussed.

Published

2010

16. Improved properties of incorporated chitosan film with ethyl cellulose microspheres for controlled release.

Author

Shi P, Zuo Y, Zou Q, Shen J, Zhang L, Li Y, and Morsi YS

Subjects

Cell Survival drug effects, Cellulose chemistry, Ciprofloxacin chemistry, Delayed-Action Preparations, Drug Carriers chemistry, Drug Stability, Solvents chemistry, Cellulose analogs & derivatives, Chitosan chemistry, Ciprofloxacin administration & dosage, Microspheres

Abstract

In this article, to discover an innovative drug release system, ciprofloxacin hydrochloride-loaded blending films of chitosan (CS)/ethyl cellulose (EC) microspheres were prepared. Two steps were adopted in the film forming process. The first was formation of the drug-loaded EC microspheres in CS solution by solvent remove/solvent evaporation methods; then, the composite films were made by casting and solvent evaporation. The results were that the drug-loaded round EC microspheres dispersed asymmetrically in the CS films and largely improved the release time. Moreover, the drug-loaded blending film containing 0.5 g EC microspheres prepared at 90 degrees C showed highlighted extended release property. The drug was stable in the blending films, which expressed good cytocompatibility proved by MTT test. The film should be a promising carrier for controlled and extended drug release system in pharmaceutical applications.

Published

2009

17. Haemodynamic analysis of coronary artery bypass grafting in a non-linear deformable artery and Newtonian pulsatile blood flow.

Author

Kouhi E, Morsi YS, and Masood SH

Subjects

Blood Flow Velocity, Blood Pressure, Computer Simulation, Elastic Modulus, Humans, Nonlinear Dynamics, Shear Strength, Stress, Mechanical, Coronary Artery Bypass, Coronary Stenosis physiopathology, Coronary Stenosis surgery, Coronary Vessels physiopathology, Coronary Vessels surgery, Models, Cardiovascular, Pulsatile Flow

Abstract

A three-dimensional (3D) computational model of stenotic coronary artery bypass grafting (CABG) system with fluid-structure interaction (FSI) using realistic physiological conditions is introduced. Unsteady pulsatile blood flow is applied to the wall of non-linear deformable arteries over the systolic period. In the analysis, the arbitrarily Lagrangian-Eulerian (ALE) formulation is used to couple the fluid region and solid domain. The method couples the equations of the deformation of the artery wall and applies them as the fluid domain boundary condition. The flow distribution and haemodynamic forces are presented in terms of velocity profiles and temporal and spatial wall shear stresses (WSSs) at the distal area. Rapid changes in the flow fields are observed in the early stages of the cardiac cycle, which alters the location of the recirculation zone from the toe to the host bed and then to the heel. The migration of the recirculation zone, considering the effect of deformability of the artery wall, indicates the same trend as the rigid wall model according to the location of low and high WSSs. However, the WSSs in the critical areas such as toe, heel, and suture lines are found to have dramatic drops in magnitudes in comparison with those of the rigid wall model. This could initiate the promotion of intimal hyperplasia (IH) and may cause an early graft failure in CABG.

Published

2008

18. A reinforced sternal wiring technique for transverse thoracosternotomy closure in bilateral lung transplantation: from biomechanical test to clinical application.

Author

Oto T, Venkatachalam R, Morsi YS, Marasco S, Pick A, Rabinov M, and Rosenfeldt F

Subjects

Biomechanical Phenomena, Bone Wires, Female, Humans, In Vitro Techniques, Lung Transplantation instrumentation, Male, Middle Aged, Osteoporosis etiology, Osteoporosis prevention & control, Surgical Wound Dehiscence etiology, Surgical Wound Dehiscence prevention & control, Thoracostomy adverse effects, Thoracostomy instrumentation, Weight-Bearing, Lung Transplantation methods, Sternum surgery, Thoracostomy methods

Abstract

Objectives: A high incidence of failure of transverse thoracosternotomy closure, involving the loops of wire cutting through the sternum, remains a significant morbidity after bilateral lung transplantation. We postulated that placing peristernal wires inside the usual longitudinal wires could prevent the longitudinal wires from cutting through the sternum. The aims of this study were to investigate the biomechanical and clinical efficacy of the proposed reinforced sternal closure technique., Methods: In vitro, 24 artificial sternal models were wired with the reinforced or conventional wiring techniques and were tested either by means of longitudinal distraction or anterior-posterior shear (n = 6 per group). In vivo, the 6-month outcomes of 70 bilateral lung transplantations, including 27 reinforced and 43 conventional wiring techniques, were assessed., Results: Reinforced wiring was stronger than conventional wiring for both longitudinal distraction (yield load: 585 +/- 60 vs 334 +/- 21 N [P = .03]; maximum load: 807 +/- 60 vs 525 +/- 34 N [P = .03]; postyield stiffness: 91.0 +/- 22.0 vs 32.8 +/- 11.8 N/mm [P = .04]) and anterior-posterior shear (yield load: 405 +/- 9 vs 364 +/- 16 N [P = .03]; postyield stiffness: 47.4 +/- 6.1 vs 27.5 +/- 5.1 N/mm [P = .04]). In multivariate analysis, the use of the conventional wiring technique (odds ratio, 5.38; P = .04) and osteoporosis (odds ratio, 18.31; P = .0005) were significant risk factors associated with sternal dehiscence. In the patients with osteoporosis (n = 25), the incidence of sternal dehiscence in the reinforced wiring group (4/16 [25%]) was significantly lower than that in the conventional wiring group (7/9 [78%], P = .02)., Conclusion: Osteoporosis is a significant risk factor for sternal dehiscence after bilateral lung transplantation. The new reinforced sternal wiring technique provides biomechanically superior fixation of the sternum and clinically reduces the incidence of sternal dehiscence in high-risk osteoporotic patients undergoing bilateral lung transplantation.

Published

2007

19. Development of a novel pulsatile bioreactor for tissue culture.

Author

Morsi YS, Yang WW, Owida A, and Wong CS

Subjects

Equipment Design, Perfusion, Pressure, Bioreactors, Pulsatile Flow, Tissue Culture Techniques

Abstract

The construction of tissue-engineered parts such as heart valves and arteries requires more than just the seeding of cells onto a biocompatible/biodegradable polymeric scaffold. It is essential that the functionality and mechanical integrity of the cell-seeded scaffold be investigated in vitro prior to in vivo implantation. The correct hemodynamic conditioning would lead to the development of tissues with enhanced mechanical strength and cell viability. Therefore, a bioreactor that can simulate physiological conditions would play an important role in the preparation of tissue-engineered constructs. In this article, we present and discuss the design concepts and criteria, as well as the development, of a multifunctional bioreactor for tissue culture in vitro. The system developed is compact and easily housed in an incubator to maintain sterility of the construct. Moreover, the proposed bioreactor, in addition to mimicking in vivo conditions, is highly flexible, allowing different types of constructs to be exposed to various physiological flow conditions. Initial verification of the hemodynamic parameters using Laser doppler anemometry indicated that the bioreactor performed well and produced the correct physiological conditions.

Published

2007

20. Transient fluid-structure coupling for simulation of a trileaflet heart valve using weak coupling.

Author

Morsi YS, Yang WW, Wong CS, and Das S

Subjects

Biomechanical Phenomena, Hemorheology, Models, Cardiovascular, Heart Valve Prosthesis, Prosthesis Design

Abstract

In this article, a three-dimensional transient numerical approach coupled with fluid-structure interaction for the modeling of an aortic trileaflet heart valve at the initial opening stage is presented. An arbitrary Lagrangian-Eulerian kinematical description together with an appropriate fluid grid was used for the coupling strategy with the structural domain. The fluid dynamics and the structure aspects of the problem were analyzed for various Reynolds numbers and times. The fluid flow predictions indicated that at the initial leaflet opening stage a circulation zone was formed immediately downstream of the leaflet tip and propagated outward as time increased. Moreover, the maximum wall shear stress in the vertical direction of the leaflet was found to be located near the bottom of the leaflet, and its value decreased sharply toward the tip. In the horizontal cross section of the leaflet, the maximum wall shear stresses were found to be located near the sides of the leaflet.

Published

2007

21. Polyethyleneterephthalate provides superior retention of endothelial cells during shear stress compared to polytetrafluoroethylene and pericardium.

Author

Wong CS, Sgarioto M, Owida AA, Yang W, Rosenfeldt FL, and Morsi YS

Subjects

Animals, Cells, Cultured, Endothelium, Vascular cytology, Sheep, Stress, Mechanical, Vascular Patency, Blood Vessel Prosthesis standards, Cell Adhesion, Endothelial Cells cytology, Pericardium cytology, Polyethylene Terephthalates therapeutic use, Polytetrafluoroethylene therapeutic use

Abstract

Background: Polyethyleneterephthalate (PET) and polytetrafluoroethylene (PTFE) are polymers successfully used as large diameter arterial grafts for peripheral vascular surgery. However, these prosthetic grafts are rarely used for coronary bypass surgery because of their low patency rates. Endothelialisation of the lumenal surface of these materials may improve their patency. This study aimed to compare the endothelialisation of PET, PTFE and pericardium by examining their seeding efficiency over time and the effect of various shear stresses on retention of endothelial cells., Methods: Ovine endothelial cells at 4x10(5)cells/cm(2) were seeded onto PET, PTFE and pericardium, and cultured for 1-168 hours. Cell coverage was determined via en face immunocytochemistry and cell retention was quantified after being subjected to shear stresses ranging from 0.018 to 0.037N/m(2) for 15, 30 and 60 minutes., Results: Endothelial cells adhered to all of the materials one hour post-seeding. PET exhibited better cell retention rate, ranging from 66.9+/-5.6% at 0.018N/m(2) for 15min to 44.7+/-1.9% at 0.037N/m(2) for 60 minutes, when compared to PTFE and pericardium (p<0.0001, three-way ANOVA)., Conclusion: PET shows superior retention of endothelial cells during shear stress compare to PTFE and pericardium.

Published

2006

22. The effect of angle on wall shear stresses in a LIMA to LAD anastomosis: numerical modelling of pulsatile flow.

Author

Freshwater IJ, Morsi YS, and Lai T

Subjects

Blood Flow Velocity physiology, Blood Pressure physiology, Computer Simulation, Coronary Artery Bypass methods, Humans, Shear Strength, Anastomosis, Surgical methods, Coronary Vessels physiopathology, Coronary Vessels surgery, Mammary Arteries physiopathology, Mammary Arteries surgery, Models, Cardiovascular, Pulsatile Flow physiology

Abstract

The purpose of this study was to examine the effect of anastomotic angle on the flow patterns and wall shear distributions at the distal anastomosis of a left interior mammary artery (LIMA) graft to the left anterior descending artery (LDA). It is now well recognized that abnormal wall shear stress distributions along the anastomotic bed, around the toe, and around the heel can contribute to the focal development of intimal hyperplasia. However, the exact nature of the interaction between the dominant pulsing flow and the anastomotic angle on wall shear stresses has not been fully investigated numerically. In this study a commercial CFD package was used for three-dimensional flow analysis where the pulsatile waveforms and flowrates used as the boundary conditions are representative of an anastomosed left internal mammary artery and a stenosed left anterior descending coronary artery (intermediate, <70 per cent diameter narrowing). The flow patterns and distributions of time-averaged wall shear stress (TAWSS) and the oscillatory shear index (OSI) for three anastomotic angles of 20, 40, and 60 degrees were evaluated and compared with other published data. The findings indicated that transient, highly disturbed flow patterns occurred in localized regions of the proximal and distal native segments and in the anastomotic domain including recirculation zones, moving points of stagnation, and oscillating wall shear stresses mainly on the bed, at the toe, and at the heel. Moreover, higher anastomotic angles resulted in more extreme variations in TAWSS and OSI values, particularly around the toe and along the bed. In addition, the effect of anastomotic angle on OSI values at the heel followed the same pattern whereas the TAWSS values along the graft at the heel showed a significant increase at the lowest anastomotic angle of 20 degrees.

Published

2006

23. Tissue engineering a functional aortic heart valve: an appraisal.

Author

Morsi YS and Birchall I

Abstract

Valvular heart disease is an important cause of morbidity and mortality, and currently available substitutes for failing hearts have serious limitations. A new promising alternative that may overcome these shortcomings is provided by the relatively new field of tissue engineering (TE). TE techniques involve the growth of autologous cells on a 3D matrix that can be a biodegradable polymer scaffold, or an acellular tissue matrix. These approaches provide the potential to create living matrix valve structures with an ability to grow, repair and remodel within the recipient. This article provides an appraisal of artificial heart valves and an overview of developments in TE that includes the current limitations and challenges for creating a fully functional valve. Biomaterials and stem cell technologies are now providing the potential for new avenues of research and if combined with advances in the rapid prototyping of biomaterials, the engineering of personalized, fully functional, and autologous tissue valve replacements, may become a clinical alternative.

Published

2005

24. Artificial aortic valves: an overview.

Author

Morsi YS, Birchall IE, and Rosenfeldt FL

Subjects

Animals, Biocompatible Materials, Humans, Polymers, Postoperative Complications, Prosthesis Design, Thromboembolism etiology, Tissue Engineering methods, Aortic Valve surgery, Heart Valve Prosthesis

Abstract

This review discusses strategies that may address some of the limitations associated with replacing diseased or dysfunctional aortic valves with mechanical or tissue valves. These limitations range from structural failure and thromboembolic complications associated with mechanical valves to a limited durability and calcification with tissue valves. In pediatric patients there is an issue with the inability of substitutes to grow with the recipient. The emerging science of tissue engineering potentially provides an attractive alternative by creating viable tissue structures based on a resorbable scaffold. Morphometrically precise, biodegradable polymer scaffolds may be fabricated from data obtained from scans of natural valves by rapid prototyping technologies such as fused deposition modelling. The scaffold provides a mechanical profile until seeded cells produce their own extra cellular matrix. The microstructure of the forming tissue may be aligned into predetermined spatial orientations via fluid transduction in a bioreactor. Although there are many technical obstacles that must be overcome before tissue engineered heart valves are introduced into routine surgical practice these valves have the potential to overcome many of the shortcomings of current heart valve substitutes.

Published

2004

25. Effect of environmental fluctuations on the dynamic composition of engineered cartilage: a deterministic model in stochastic environment.

Author

Saha AK, Mazumdar JN, and Morsi YS

Subjects

Animals, Cartilage cytology, Cell Culture Techniques methods, Cell Division physiology, Cells, Cultured, Chondrocytes cytology, Computer Simulation, Extracellular Matrix ultrastructure, Humans, Models, Statistical, Stochastic Processes, Cartilage physiology, Chondrocytes physiology, Environment, Extracellular Matrix physiology, Extracellular Matrix Proteins metabolism, Models, Biological, Tissue Engineering methods

Abstract

Dynamics of extracellular matrix (ECM) deposition and scaffold degradation in cell-polymer constructs have been studied in a random fluctuating environment created due to the applications of growth factors into the in vitro generation of cartilaginous constructs. Existing models of cell-polymer constructs for the design of engineered cartilage have been discussed and then a new deterministic scheme in random environment proposed taking into account the effects of growth factors as the environmental variability in the form of Gaussian white noise. Steady-state probability distribution of each individual component of the ECM in its homeostasis is found explicitly. The computer-simulated results of the model have been discussed and then compared with the data from a variety of scaffold systems and culture conditions.

Published

2003

26. Flow characteristics past jellyfish and St. Vincent valves in the aortic position under physiological pulsatile flow conditions.

Author

Morsi YS and Sakhaeimanesh AA

Subjects

Blood Flow Velocity, Blood Pressure, Hemodynamics physiology, Hemorheology, In Vitro Techniques, Materials Testing, Stress, Mechanical, Systole, Aortic Valve, Heart Valve Prosthesis, Prosthesis Design, Pulsatile Flow physiology

Abstract

Thrombus formation and hemolysis have been linked to the dynamic flow characteristics of heart valve prostheses. To enhance our understanding of the flow characteristics past the aortic position of a Jellyfish (JF) valve in the left ventricle, in vitro laser Doppler anemometry (LDA) measurements were carried out under physiological pulsatile flow conditions. The hemodynamic performance of the JF valve was then compared with that of the St. Vincent (SV) valve. The comparison was given in terms of mean systolic pressure drop, back flow energy losses, flow velocity, and shear stresses at various locations downstream of both valves and at cardiac outputs of 3.5 L/min, 4.5 L/min, and 6.5 L/min respectively. The results indicated that both valves created disturbed flow fields with elevated levels of turbulent shear stress as well as higher levels of turbulence in the immediate vicinity of the valve and up to 1 diameter of the pipe (D) downstream of the valve. At a location further downstream, the JF valve showed better flow characteristics than the SV in terms of velocity profiles and turbulent shear stresses. The closure volume of the SV valve was found to be 2.5 times higher than that of the JF valve. Moreover, the total back flow losses and mean systolic pressure drop also were found to be higher in the SV than the JF valve.

Published

2000

27. Hydrodynamic evaluation of three artificial aortic valve chambers.

Author

Morsi YS, Sakhaeimanesh A, and Clayton BR

Subjects

Blood Flow Velocity, Blood Pressure, Evaluation Studies as Topic, Hemorheology, Humans, Laser-Doppler Flowmetry, Materials Testing, Pressure, Regional Blood Flow, Rheology, Sinus of Valsalva, Stress, Mechanical, Surface Properties, Systole, Aortic Valve, Heart Valve Prosthesis, Prosthesis Design

Abstract

The effect of chamber geometry on the characteristics of turbulent steady flow through a newly designed artificial heart valve, "the jellyfish valve," has been investigated for flow rates matching those of peak systole. Laser Doppler Anemometry (LDA) was employed to determine the velocity and shear stress distributions at various locations downstream of the jellyfish valve. Three geometrically different aortic valve chambers have been investigated: namely, a chamber with sinuses of Valsalva, an ellipsoidal chamber, and a cylindrical chamber. The results of this investigation indicated that the aorta with sinuses of Valsalva model had the highest turbulent shear stresses whereas the ellipsoidal model gave the highest-pressure drops. However, for the various flow rates examined, including the systole peak value of 26 L/min, it appears that the ellipsoidal model displays better hydrodynamic characteristics in terms of shear stress and uniformity of axial velocity distributions downstream of the jellyfish valve.

Published

2000

28. Analysis of regurgitation, mean systolic pressure drop and energy losses for two artificial aortic valves.

Author

Sakhaeimanesh AA and Morsi YS

Subjects

Blood Flow Velocity, Blood Pressure, Cardiac Output, Humans, In Vitro Techniques, Models, Cardiovascular, Models, Structural, Pulsatile Flow, Systole, Aortic Valve physiopathology, Aortic Valve Insufficiency physiopathology, Heart Valve Prosthesis, Hemodynamics

Abstract

The work reported here is related to the hydrodynamic performance of a Jellyfish valve and St Vincent valve in terms of total energy losses, mean systolic pressure drop and regurgitation. The in vitro experimental investigation was conducted at cardiac outputs of 3.5, 4.5 and 6.51 min-1 across the two valves and under pulsatile flow condition. It was found that the closure volume of the St Vincent valve was about 2.5 times higher than that of the Jellyfish valve. The total back flow losses on the other hand were found to be in the range of 36.5 to 107.1 and 85.5 to 192.5 mJ for the Jellyfish valve and St Vincent valve respectively. Moreover, the mean systolic pressure drop of the St Vincent valve was found to be higher than that of the Jellyfish valve. However, for all the operating conditions tested here, the Jellyfish valve showed superior hydrodynamic performance in terms of backflow and mean systolic pressure as well as energy losses.

Published

1999