This proposal aims to secure training grant stipends and associated support for students during their first two years in the UCSF/UCB Joint Graduate Group in Bioengineering (JBBG). Over the past 25 years, the JBBG has awarded Ph.D.s in Bioengineering to 221 students, with 86 of these receiving stipends from this NIH Training Grant Award. Such stipends are the backbone for the unique JGGB structure, which requires that students have financial support during their first two years. These initial two years of preparation include intensive course work in engineering and the biomedical sciences, as well as three laboratory rotations, are essential to the students in selecting appropriate dissertation research topics. In later year the students receive financial support through their research mentor. The JGGB bridges two University of California campuses that possess complementary strengths: UCSF is a leading Health Sciences institution and UC Berkeley's Engineering School is a national leader in the physical sciences. The breadth and depth of the training environment offered to students is of an order larger than a single department could provide. Over 170 faculty based in 25 departments participate in the JGGB. Their laboratories include an array of state-of-the art facilities. An academic and intellectual environment fosters seamless interaction between physical and life sciences and that trains students to solve complex biological problems with an emphasis on translational research is in high demand. The JGGB has an established record of such integration, and the breadth of opportunity for collaboration is one of the reasons that the program is structured to have students spend two years concentrating on a variety of laboratory rotations and course work prior to committing to their dissertation project. With the recent expansion of Bioengineering research and educational programs at UCSF and UCB, the capacity for training graduate students has increased and the size of the student body has grown from 148 to 173. This training grant is a critical component of the support package that students are offered, and it has therefore become increasingly important for ensuring that they flourish in the present competitive environment. Because qualified applicants far exceed the number of students that can be admitted into the JGGB, we are requesting an increase in the number of slots during the next funding cycle from the current recommended level of 17 to 25 students. The unique ability for bioengineers to integrate principles from diverse fields and thereby span the gap between advances in basic science and clinical utilization places individuals trained in this field at a critical point in advancing a translational research agenda that has been recently highlighted by new organizations within the NIH.
The health and life sciences are in the midst of a profound revolution due to new technology and quantitative approaches developed in the disciplines of chemistry, biology, physics and engineering. These advances, along with the aging of the population and the focus on health issues will increase the demand for better medical devices, techniques, and therapeutic modalities. The JGGB is making a significant contribution to meeting these societal needs by training the next generation of bioengineers.
|Muthusubramaniam, Lalitha; Zaitseva, Tatiana; Paukshto, Michael et al. (2014) Effect of collagen nanotopography on keloid fibroblast proliferation and matrix synthesis: implications for dermal wound healing. Tissue Eng Part A 20:2728-36|
|Wade, Jennifer S; Desai, Tejal A (2014) Planar microdevices enhance transport of large molecular weight molecules across retinal pigment epithelial cells. Biomed Microdevices 16:629-38|
|Schweicher, Julien; Desai, Tejal A (2014) Facile Synthesis of Robust Free-Standing TiO2 Nanotubular Membranes for Biofiltration Applications. J Appl Electrochem 44:411-418|
|Cheng, Kevin K; Berven, Sigurd H; Hu, Serena S et al. (2014) Intervertebral discs from spinal nondeformity and deformity patients have different mechanical and matrix properties. Spine J 14:522-30|
|Uricchio, Lawrence H; Hernandez, Ryan D (2014) Robust forward simulations of recurrent hitchhiking. Genetics 197:221-36|
|Kam, Kimberly R; Desai, Tejal A (2013) Nano- and microfabrication for overcoming drug delivery challenges. J Mater Chem B Mater Biol Med 1:1878-1884|
|Muthusubramaniam, Lalitha; Peng, Lily; Zaitseva, Tatiana et al. (2012) Collagen fibril diameter and alignment promote the quiescent keratocyte phenotype. J Biomed Mater Res A 100:613-21|
|Keller, E L; Gandhi, N J; Vijay Sekaran, S (2000) Activity in deep intermediate layer collicular neurons during interrupted saccades. Exp Brain Res 130:227-37|
|Gandhi, N J; Keller, E L (1999) Comparison of saccades perturbed by stimulation of the rostral superior colliculus, the caudal superior colliculus, and the omnipause neuron region. J Neurophysiol 82:3236-53|
|Gandhi, N J; Keller, E L (1999) Activity of the brain stem omnipause neurons during saccades perturbed by stimulation of the primate superior colliculus. J Neurophysiol 82:3254-67|
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