Biomedical Engineering and Bioengineering Commons^™

Mechanical Stimulation Increases Knee Meniscus Gene Rna-Level Expression In Adipose-Derived Stromal Cells, Elizabeth M. Meier, Bin Wu, Aamir Siddiqui, Donna G. Tepper, Michael T. Longaker, Mai T. Lam

Biomedical Engineering Faculty Research Publications

Background: Efforts have been made to engineer knee meniscus tissue for injury repair, yet most attempts have been unsuccessful. Creating a cell source that resembles the complex, heterogeneous phenotype of the meniscus cell remains difficult. Stem cell differentiation has been investigated, mainly using bone marrow mesenchymal cells and biochemical means for differentiation, resulting in no solution. Mechanical stimulation has been investigated to an extent with no conclusion. Here, we explore the potential for and effectiveness of mechanical stimulation to induce the meniscal phenotype in adipose-derived stromal cells.

Methods: Human adipose-derived stromal cells were chosen for their fibrogenic nature and conduciveness …

The Connectivity Domain: Analyzing Resting State Fmri Data Using Feature-Based Data-Driven And Model-Based Methods, Armin Iraji, Vince D. Calhoun, Natalie M. Wiseman, Esmaeil Davoodi-Bojd, Mohammad R. N. Avanaki, Zhifeng Kou

Biomedical Engineering Faculty Research Publications

Spontaneous fluctuations of resting state functional MRI (rsfMRI) have been widely used to understand the macro-connectome of the human brain. However, these fluctuations are not synchronized among subjects, which leads to limitations and makes utilization of first-level model-based methods challenging. Considering this limitation of rsfMRI data in the time domain, we propose to transfer the spatiotemporal information of the rsfMRI data to another domain, the connectivity domain, in which each value represents the same effect across subjects. Using a set of seed networks and a connectivity index to calculate the functional connectivity for each seed network, we transform data into …

A Glycosaminoglycan Based, Modular Tissue Scaffold System For Rapid Assembly Of Perfusable, High Cell Density, Engineered Tissues, Ramkumar Tiruvannamalai-Annamalai, David Randall Armant, Howard W. T Matthew

Biomedical Engineering Faculty Research Publications

The limited ability to vascularize and perfuse thick, cell-laden tissue constructs has hindered efforts to engineer complex tissues and organs, including liver, heart and kidney. The emerging field of modular tissue engineering aims to address this limitation by fabricating constructs from the bottom up, with the objective of recreating native tissue architecture and promoting extensive vascularization. In this paper, we report the elements of a simple yet efficient method for fabricating vascularized tissue constructs by fusing biodegradable microcapsules with tunable interior environments. Parenchymal cells of various types, (i.e. trophoblasts, vascular smooth muscle cells, hepatocytes) were suspended in glycosaminoglycan (GAG) solutions …

Towards A More Robust Lower Neck Compressive Injury Tolerance - An Approach Combining Multiple Test Methodologies, Daniel Toomey, King H. Yang, N Yoganadan, F A. Pintar, C A. Van Ee

Biomedical Engineering Faculty Research Publications

Objective.The compressive tolerance of the cervical spine has traditionally been reported in terms of axial force at failure. Previous studies suggest that axial compressive force at failure is particularly sensitive to the alignment of the cervical vertebra and the end conditions of the test methodology used. The present study was designed to develop a methodology to combine the data of previous experiments into a diverse dataset utilizing multiple test methods to allow for the evaluation of the robustness of current and proposed eccentricity based injury criteria.

Methods. Data was combined from two studies composed of dynamic experiments including whole …

Why Is Ca3 More Vulnerable Than Ca1 In Experimental Models Of Controlled Cortical Impact-Induced Brain Injury?, Haojie Mao, Benjamin S. Elkin, Vinay V. Genthikatti, Barclay Morrison Iii, King H. Yang

Biomedical Engineering Faculty Research Publications

One interesting finding of controlled cortical impact (CCI) experiments is that the CA3 region of the hippocampus, which is positioned further from the impact than the CA1 region, is reported as being more injured. The current literature has suggested a positive correlation between brain tissue stretch and neuronal cell loss. However, it is counterintuitive to assume that CA3 is stretched more during CCI injury. Recent mechanical studies of the brain have reported on a level of spatial heterogeneity not previously appreciated—the finding that CA1 was significantly stiffer than all other regions tested and that CA3 was one of the most …