	Mission
	Economic Impact
	Staff

	Location
	Partners + Sponsors
	Press + Reports
	News + Events

	Overview

	Key Industry Intiatives
	• NY Infrastructure Developed
	• Companies Developed
	• SBIR

	NY Industry
	• Industry Profile
	• NY Industry Directory

	Overview of Initiatives
	Technology Development Pipeline

	CBT Assets
	• Resources + Facilities
	• Technologies Supported
	• SUNY Research Community

	Funding
	• ITD Award Program
	• Other Funding Opportunities

	Overview
	Seminar Series
	• Annual Life Sciences Career Development Conference

	Grad Level Programs
	• Fundamentals of the Bioscience Industry Program
	• BME Industrial Research Internship
	• Internship in Biotech + Patent Law
	• Career Development

	Undergrad Level Programs
	• Biotech Internship Program
	• Interdisciplinary Biomed Research Prog

	Outreach Programs
	• Biotechnology Teaching Laboratory

Creating positive economic impact
in New York State

home > about the center > staff > cv for c. rubin

Celebrating 25 Years of Leadership and Economic Growth


	2004 5-Year Report » High Res PDF \| Low Res PDF

Curriculum Vitae for Clinton T. Rubin

Research Focus
Education
Academic Appointments
Honors
Publications
Patents

Research Focus

The major research focus of my work is targeted towards understanding the cellular mechanisms responsible for the growth, healing, and homeostasis of bone. More specifically, I am interested in how biophysical stimuli (i.e., mechanical, electrical, temperature, magnetic, pressure) mediate these responses. The clinical significance of this work is applicable to the inhibition of osteopenia, the promotion of bony ingrowth into prostheses or skeletal defects, and the acceleration of fracture healing. These goals are approached via interdisciplinary studies at the biochemical, molecular, cellular, tissue, organ, computational (e.g., FEM) and clinical levels.

Education

Res. Fellow - Biomechanics, Brigham & Women's Hosp. Boston, MA, 1984-5
Res. Assoc. - Cell Biology, Tufts Univ., Boston, MA, 1983-4
Ph.D. - Anatomy, Univ. of Bristol, Bristol, U.K., 1983
B.A. - Physiology, Harvard Univ., Cambridge, MA, 1977

Academic Appointments

2000- Chair, Department of Biomedical Engineering
1997- Visiting Scientist, Brookhaven National Laboratory, Upton, NY
1997- Director, Center for Advanced Technology in Medical Biotechnology, New York State office of Science, Technology and Academic Research
1995- Director, Program in Biomedical Engineering, S.U.N.Y., Stony Brook.
1992- Professor of Orthopaedics, Anatomy, Molecular Biophysics & Mechanical Eng. S.U.N.Y., Stony Brook.
1987- Director, Musculo-Skeletal Research Laboratory, S.U.N.Y., Stony Brook.
1987-92 Associate Professor of Orthopaedics, Anatomy, & Mechanical Engineering, S.U.N.Y., Stony Brook.
1984-87 Assistant Professor of Anatomy & Cell Biol., Tufts Univ. School Med., Boston, Mass.

Dr. Rubin's research into non-invasive, non-pharmacological intervention to control osteoporosis was referenced in National Geographic's January 2001 article about surviving space travel. His studies show that the application of extremely low level strains to animals and humans will increase bone formation, and thus may represent the much sought after "anabolic" stimulus in bone.

Honors

2000 Giovanni Borelli Award, American Society of Biomechanics
1998- Board of Directors, New York Biotechnology Association
1997- The Whitaker Foundation, Fellowship Advisory Committee
1996 Fuller Albright Award, American Society of Bone and Mineral Research
1994 Founder, Exogen, Inc.
1993 John Charnley Award, The Hip Society, Amer. Acad. Orthop. Surgeons
1990 Kappa Delta Award for Outstanding Research, Bioelectric Repair and Growth Society.
1989-1994 Committee on Space Biology & Medicine, Space Studies Board, National Research Council
1987-1992 Presidential Young Investigator Award, National Science Foundation.
1986 European Society of Biomechanics Award for Excellence in Research.
1985 Kappa Delta Society Young Investigator Award, Amer. Acad. Orthop. Surgeons.

Publications

Judex, S., Donahue, L.R., Rubin, C.T. (2002) Genotypic predisposition to osteoporosis is paralleled by an enhanced sensitivity to signals anabolic to the skeleton. The FASEB Journa Express Article. 10.1096/fj.01-0913fje
Hadjiargyrou M, Lombardo F, Zhao S, Ahrens W, Joo J, Ahn H, White DW, Rubin CT. Transciptional profiling of bone regeneration: Insight into the molecular complexity of wound repair. J Biol Chem 2002.
Rubin C, Turner AS, Mallinckrodt C, Jerome C, McLeod K, Bain S. Mechanical strain, induced noninvasively in the high-frequency domain, is anabolic to cancellous bone, but not cortical bone. Bone 2002 Mar; 30(3):445-52.
Rubin C, Turner AS, Muller R, Mittra E, McLeod K, Lin W, Qin YX. Quantity and quality of trabecular bone in the femur are enhanced by a strongly anabolic, noninvasive mechanical intervention. J Bone Miner Res 2002 Feb; 17(2):349-57.
Rubin, C., Turner, S. Bain, S., Mallinckrodt, C. & McLeod, K. (2001) Extremely Low Level Mechanical Signals are Anabolic to Trabecular Bone. Nature 412:603-604.
Rubin C, Xu G, Judex S. The anabolic activity of bone tissue, suppressed by disuse, is normalized by brief exposure to extremely low-magnitude mechanical stimuli. FASEB J. 2001; 15(12):2225-9.
D. W. Sommerfeldt, C. T. Rubin. (2001) Biology of bone and how it orchestrates the form and function of the skeleton. Eur Spine J, DOI 10.1007/s005860100283
Rubin, C, Sommerfeldt, D, Judex, S & Qin, Y-X. (2001) Inhibition of Osteopenia by Low Magnitude, High Frequency Mechanical Stimuli. Drug Discovery Today 6:848-858.
Rubin, C., Bolander, M., Ryaby, J. & Hadjiargyrou, M. (2001) The use of low intensity ultrasound to accelerate the healing of fractures. J. Bone & Jt. Surg. 83:259-70.
Lin, W., Qin, Y.-X. & Rubin, C.T. (2001) Ultrasonic wave propagation in trabecular bone predicted by the stratified model. Annals of Biomed. Eng. 29(9):1-10.
Rubin, C., Alikhani, M. and Rubin, J. (2001) Comparative Skeletal Structure. In: Encyclopedia Life Sciences; Nature Press (in press).
Sommerfeldt DW, McLeod KJ, Rubin CT, Hadjiargyrou M. Differential phosphorylation of paxillin in response to surface-bound serum proteins during early osteoblast adhesion. Biochem Biophys Res Commun. 2001 Jul 13; 285(2):355-63.
Fritton, S.P., McLeod, K.J., Rubin, C.T. (2000) Quantifying the strain history of bone: spatial uniformity and self-similarity of low magnitude strains. J. Biomech. 33:317-326.
Hadjiargyrou, M., Ahrens, W. & Rubin, C. (2000) Expression and function of CYR-61 in the healing fracture. J. Bone & Min. Res 15:1014-1023
Rubin, C. and Rubin, J. (2000) Biomechanics of Bone. Primer for Metabolic Bone Diseases and Disorders of Mineral Metabolism. ed: M. Fauvus. Lippincott-Raven ch 5: p 39-42
Vander Molen, M.A., Donahue. H.J., Rubin, C.T. & McLeod, K.J. (2000) Gap junctions alter the kinetics of electric field induced differentiation in osteoblastic cells. Bone . 27(2):227-31
Rubin, J., Rubin, H., & Rubin, C. (1999) Constraints of experimental paradigms used to model the aging skeleton. The Aging Skeleton, eds: C.Rosen, J.Glowacki & J.Bilizekian. Acad. Press Ch.4; p27-36.
Rubin, C., Zhi, J., Xu, G., Cute, M., McLeod, K. and Hadjiargyrou, M. (1999) Expression of novel gene products upregulated by disuse is normalized by an osteogenic mechanical stimulus: NASA Space Biology Program; Biomedical Investigators' Workshop, Jan. 11-13, League City, Texas.
McLeod, K.J., Turner, A.S., Mallinckrodt, C.H. & Rubin, C.T. (1999) Frequency and duration optimization of dynamic loading protocols for the reversal of osteopenia. 45th Ann. Mtg. Orthop. Res. Soc.:24:571
Qin, Y.X., McLeod, K.J., Lin, W., Gray, J., Turner, A.S. & Rubin, C.T. (1999) Trabecular strength is enhanced by low magnitude and high frequency mechanical stimuli as determined by CT number, ultrasonic velocity and force-displacement measurements. 45th Ann. Mtg. Orthop. Res. Soc. 24:568.
Rubin, J. & Rubin, C. (1999) Genetic and Epigenetic Influences on Bone Strength. In: Osteoporosis: Genetics, Prevention and Treatment, eds: J. Adams & B. Lukert, Kluwer Publ., Newt., MA p.57-72 .
Rubin, J., Fan, X., Biskobing, D., Taylor, W. & Rubin, C. (1999) Osteoclast formation is attenuated in a dose-dependent and site-specific manner by physiologic levels of strain. J. Orth. Res, 17:639-645.
Huang, R., McLeod, K. & Rubin, C. (1999) Changes in the dynamics of muscle contraction as a function of age; A contributing factor to the etiology of osteoporosis? J. Gerontology 54:352-357.
Rubin, C., Recker, R., Cullen, D., Ryaby, J. & McLeod, K. (1998) Prevention of bone loss in a post-menopausal population by low-level biomechanical intervention. Amer. Sc. Bone Min Res: 23:1106
Rubin, C. Turner, S., Jerome, C. Strachan, M., Bain, S., & McLeod, K. (1998). Low magnitude, high frequency mechanical stimulation increases trabecular density of the proximal femur. Amer Soc.Bone Min Res: 23:1126
Qin, Y-X., Rubin, C. & McLeod, K. (1998) Nonlinear dependence of loading intensity and cycle number in the maintenance of bone mass and morphology. J. Orth. Res. 16:482-489.
Hadjiargyrou, M., Halsey, M., Ahrens, W., Rightmire, E., McLeod, K & Rubin, C. (1998) Cloning of a novel cDNA expressed during the early stages of fracture healing. Biochm & Biophys. Res. Com 249:879-884
Otter, M., Rubin, C., and McLeod, K. (1998) Stochastic modulation of cell shape by low-level mechanical loading. The Amer. J. Med. Sciences 316(3):176-183.
Demes, B., Stern, J., Larson, S. & Hausman, M, Rubin, C., (1998) Bone strain in the macaque ulna during locomotion. J. Phys. Anthrop 106:87-100
Hadjiargyrou, M., McLeod, K., Ryaby, J. & Rubin, C.(1998) Augmentation of Fracture Healing by Low Intensity Ultrasound.. Clin. Orth. Rel. Res. 355:216-229
Adams, D., Spirt, A., Brown, T., Fritton, S., Rubin, C. & Brand, R. (1997) Testing the "daily stress stimulus" hypothesis of bone remodeling. J. Biomech30:671-678.
Fritton, J., Rubin, C., Qin, Y.-X. & McLeod, K. (1997) Vibration in the skeleton. Part I: Development of a resonance-based whole body vibration device. J. Biomed Eng. 25:831-839.
Gross, T.S., Edwards, J.L., McLeod, K.J. & Rubin, C.T. (1997) Strain gradients correlate with sites of periosteal bone formation. J. Bone Min. Res. 12(6):982-988.
Rubin, C. T. & McLeod, K. (1996) Inhibition of osteopenia by biophysical intervention. In: Osteoporosis, Eds: R. Marcus, J. Kelsey & D. Feldman. Academic Press Ch. ch. 5, pp351-371.
Rubin, C., Sun, Y-Q, Hadjiargyrou, M. & McLeod, K. (1999) Increased expression of MMP-1 mRNA in osteocytes precedes bone resorption as stimulated by disuse: Evidence for the autoregulation of the bone's mechanical environment? J. Orth. Res.; 17: 354-361.
Rubin, C., Gross, T., Qin, Y., Fritton, S., Guilak, F. & McLeod, K.J. (1996) Differentiation of bone-tissue remodeling response to axial and torsional loading. J. Bone Jt. Surg. 78(10):1523-1533.
Qin, Y., McLeod, K., Guilak, F. and Rubin, C. (1996) Correlation of bony ingrowth with the distribution of stress and strain parameters surrounding a porous-coated implant. J. Orth. Res. 14:862-870.
Rubin, J., McLeod, K., Titus, L., Nanes, M., Catherwood, B. and Rubin, C. (1996) Formation of osteoclast-like cells is suppressed by low frequency, low intensity electric fields. J. Orth. Res. 14:7-15.
Ricos, V., Pedersen, D., Brown, T, Rubin, C., & Brand, R. (1996) Effects of anisotropy and material axis registration on computed stress and strain distributions in the turkey ulna. J. Biomec. 29:261-267.
Sun, Y-Q., McLeod, K. & Rubin, C. (1995) Mechanically induced periosteal bone formation is paralleled by the upregulation of collagen type one mRNA in osteocytes as measured by IS-RT-PCR. Calc. Tiss. Intl. 57:456-462.
Gross, T. and Rubin, C. (1995) Uniformity of resorptive bone loss induced by disuse. J. Orth. Res. 13(5):708-714.
Rubin, C.T., Gross, T.S., McLeod, K.J. & Bain, S.D. (1995) Morphologic stages in lamellar bone formation stimulated by a potent mechanical stimulus. J. Bone Min. Res. 10(3):488-495.
Rubin, C. & McLeod (1994) Promotion of bony ingrowth by frequency specific, low amplitude mechanical strains. John Charnley Award of The Hip Society. Clin. Orth. Rel. Res. 298:165-174

Patents

Method for inducing a current and voltage in living tissue for the prevention of bone loss. Patent #4,993,413
Mechanical loading protocol for the prevention of osteoporosis, acceleration of fracture healing, and the promotion of bony ingrowth. #5,103,808
Method for the promotion of growth, ingrowth and healing of bone tissue and the prevention of osteopenia by mechanical loading of the bone tissue. #5,191,880
Apparatus for the induction of high frequency strains into the axial skeleton to promote growth and repair. #5,273,028
Non-Invasive method and means for in-vivo bone-growth stimulation. #5,376,065
Method and system for therapeutically treating bone fractures and osteoporosis. #5,997,490
Method and system for therapeutically treating bone fractures and osteoporosis. #6,022,349
Chondrogenic and osteogenic genes to be used in the treatment of metabolic bone disease. Pending
Frequency scanning ultrasound as a non-invasive means to determine the physical properties of bone. Pending
Improvement of postural stability using low level, high frequency mechanical oscillations. Pending