Your search keyword '"Ortiz, Christine"' showing total 221 results

201. Geometry-dependent compressive responses in nanoimprinted submicron-structured shape memory polyurethane.

Author

Lee WL, Low HY, and Ortiz C

Abstract

High resolution surface textures, when rationally designed, provide an attractive surface engineering approach to enhance surface functionalities. Designing smart surfaces by coupling surface texture with shape memory polymers has garnered attention in achieving tunable mechanical properties. We investigate the structure-mechanical property relationships for programmable, shape-memorizing submicron-scale pillar arrays subjected to flat-punch compression. The geometrically-dependent deformation of structured surfaces with two different aspect ratios (250 nm-pillars 1 : 1 and 550 nm-pillars 2.4 : 1) were investigated, and their moduli were found to be lower than that of non-patterned surface. From finite element analysis, the pillar deformation is correlated to a mechanistic transition from a discrete, unidirectional compression of 250 nm-pillars to lateral constraints caused by interpillar contact in 550 nm-pillars. This lateral pillar-pillar contact in the 550 nm-pillars resulted in an increased and maximum strain-dependent modulus but lower elastic recovery and energy dissipation as compared with the 250 nm-pillars. Furthermore, the compressive responses of temporarily shaped pillars (programmed by stretching) were compared with the permanently shaped pillars. The extent of lateral constraints controlled by pillar shape and spacing in 550 nm-pillars was responsible for the modulus differences between the original and stretched patterns, whereas the modulus of 250 nm-pillars remained as a constant value with different levels of stretching. This study provides mechanistic insights into how the mechanical behavior can be modulated by designing the aspect ratio of shape memory pillar arrays and by programming the surface geometry, thus revealing the potential of developing ingenious designs of responsive surfaces sensitive to mechanical deformation.

Published

2017

202. Wide bandwidth nanomechanical assessment of murine cartilage reveals protection of aggrecan knock-in mice from joint-overuse.

Author

Azadi M, Nia HT, Gauci SJ, Ortiz C, Fosang AJ, and Grodzinsky AJ

Subjects

Aggrecans metabolism, Aging metabolism, Animals, Biomechanical Phenomena, Cattle, Endopeptidases metabolism, Femur metabolism, Humans, Mice, Microscopy, Atomic Force, Osteoarthritis metabolism, Permeability, Aggrecans genetics, Cartilage metabolism, Gene Knock-In Techniques, Mechanical Phenomena, Nanotechnology

Abstract

Aggrecan loss in human and animal cartilage precedes clinical symptoms of osteoarthritis, suggesting that aggrecan loss is an initiating step in cartilage pathology. Characterizing early stages of cartilage degeneration caused by aging and overuse is important in the search for therapeutics. In this study, atomic force microscopy (AFM)-based force-displacement micromechanics, AFM-based wide bandwidth nanomechanics (nanodynamic), and histologic assessments were used to study changes in distal femur cartilage of wildtype mice and mice in which the aggrecan interglobular domain was mutated to make the cartilage aggrecanase-resistant. Half the animals were subjected to voluntary running-wheel exercise of varying durations. Wildtype mice at three selected age groups were compared. While histological assessment was not sensitive enough to capture any statistically significant changes in these relatively young populations of mice, micromechanical assessment captured changes in the quasi-equilibrium structural-elastic behavior of the cartilage matrix. Additionally, nanodynamic assessment captured changes in the fluid-solid poroelastic behavior and the high frequency stiffness of the tissue, which proved to be the most sensitive assessment of changes in cartilage associated with aging and joint-overuse. In wildtype mice, aging caused softening of the cartilage tissue at the microscale and at the nanoscale. Softening with increased animal age was found at high loading rates (frequencies), suggesting an increase in hydraulic permeability, with implications for loss of function pertinent to running and impact-injury. Running caused substantial changes in fluid-solid interactions in aggrecanase-resistant mice, suggestive of tissue degradation. However, higher nanodynamic stiffness magnitude and lower hydraulic permeability was observed in running aggrecanase-resistant mice compared to running wildtype controls at the same age, thereby suggesting protection from joint-overuse., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

203. Multifunctionality of chiton biomineralized armor with an integrated visual system.

Author

Li L, Connors MJ, Kolle M, England GT, Speiser DI, Xiao X, Aizenberg J, and Ortiz C

Subjects

Animal Shells chemistry, Animals, Bioengineering, Crystallography, Biocompatible Materials chemistry, Calcium Carbonate chemistry, Lens, Crystalline chemistry, Polyplacophora chemistry, Polyplacophora physiology, Vision, Ocular

Abstract

Nature provides a multitude of examples of multifunctional structural materials in which trade-offs are imposed by conflicting functional requirements. One such example is the biomineralized armor of the chiton Acanthopleura granulata, which incorporates an integrated sensory system that includes hundreds of eyes with aragonite-based lenses. We use optical experiments to demonstrate that these microscopic lenses are able to form images. Light scattering by the polycrystalline lenses is minimized by the use of relatively large, crystallographically aligned grains. Multiscale mechanical testing reveals that as the size, complexity, and functionality of the integrated sensory elements increase, the local mechanical performance of the armor decreases. However, A. granulata has evolved several strategies to compensate for its mechanical vulnerabilities to form a multipurpose system with co-optimized optical and structural functions., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015

204. Biomechanical properties of murine meniscus surface via AFM-based nanoindentation.

Author

Li Q, Doyran B, Gamer LW, Lu XL, Qin L, Ortiz C, Grodzinsky AJ, Rosen V, and Han L

Subjects

Animals, Anisotropy, Biomechanical Phenomena, Cartilage, Articular pathology, Disease Models, Animal, Elastic Modulus, Male, Menisci, Tibial pathology, Mice, Mice, Inbred C57BL, Microscopy, Atomic Force methods, Microscopy, Electron, Scanning, Osteoarthritis, Knee pathology, Surface Properties, Viscosity, Cartilage, Articular physiopathology, Menisci, Tibial physiopathology

Abstract

This study aimed to quantify the biomechanical properties of murine meniscus surface. Atomic force microscopy (AFM)-based nanoindentation was performed on the central region, proximal side of menisci from 6- to 24-week old male C57BL/6 mice using microspherical tips (Rtip≈5µm) in PBS. A unique, linear correlation between indentation depth, D, and response force, F, was found on menisci from all age groups. This non-Hertzian behavior is likely due to the dominance of tensile resistance by the collagen fibril bundles on meniscus surface that are mostly aligned along the circumferential direction. The indentation resistance was calculated as both the effective modulus, Eind, via the isotropic Hertz model, and the effective stiffness, Sind = dF/dD. Values of Sind and Eind were found to depend on indentation rate, suggesting the existence of poro-viscoelasticity. These values do not significantly vary with anatomical sites, lateral versus medial compartments, or mouse age. In addition, Eind of meniscus surface (e.g., 6.1±0.8MPa for 12 weeks of age, mean±SEM, n=13) was found to be significantly higher than those of meniscus surfaces in other species, and of murine articular cartilage surface (1.4±0.1MPa, n=6). In summary, these results provided the first direct mechanical knowledge of murine knee meniscus tissues. We expect this understanding to serve as a mechanics-based benchmark for further probing the developmental biology and osteoarthritis symptoms of meniscus in various murine models., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

205. Biomechanics. Mechanistic origins of bombardier beetle (Brachinini) explosion-induced defensive spray pulsation.

Author

Arndt EM, Moore W, Lee WK, and Ortiz C

Subjects

Animals, Benzoquinones chemistry, Biological Evolution, Biomechanical Phenomena, Coleoptera anatomy & histology, Coleoptera chemistry, Exocrine Glands anatomy & histology, Exocrine Glands metabolism, Synchrotrons, Coleoptera physiology, Muscles physiology

Abstract

Bombardier beetles (Brachinini) use a rapid series of discrete explosions inside their pygidial gland reaction chambers to produce a hot, pulsed, quinone-based defensive spray. The mechanism of brachinines' spray pulsation was explored using anatomical studies and direct observation of explosions inside living beetles using synchrotron x-ray imaging. Quantification of the dynamics of vapor inside the reaction chamber indicates that spray pulsation is controlled by specialized, contiguous cuticular structures located at the junction between the reservoir (reactant) and reaction chambers. Kinematics models suggest passive mediation of spray pulsation by mechanical feedback from the explosion, causing displacement of these structures., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015

206. Aggrecan nanoscale solid-fluid interactions are a primary determinant of cartilage dynamic mechanical properties.

Author

Nia HT, Han L, Bozchalooi IS, Roughley P, Youcef-Toumi K, Grodzinsky AJ, and Ortiz C

Subjects

Adult, Aggrecans chemistry, Biomechanical Phenomena, Biomimetic Materials chemistry, Cartilage chemistry, Elasticity, Finite Element Analysis, Humans, Infant, Newborn, Microscopy, Atomic Force, Models, Molecular, Permeability, Porosity, Protein Conformation, Rheology, Static Electricity, Water chemistry, Aggrecans metabolism, Biomimetic Materials metabolism, Cartilage metabolism, Mechanical Phenomena, Nanotechnology

Abstract

Poroelastic interactions between interstitial fluid and the extracellular matrix of connective tissues are critical to biological and pathophysiological functions involving solute transport, energy dissipation, self-stiffening and lubrication. However, the molecular origins of poroelasticity at the nanoscale are largely unknown. Here, the broad-spectrum dynamic nanomechanical behavior of cartilage aggrecan monolayer is revealed for the first time, including the equilibrium and instantaneous moduli and the peak in the phase angle of the complex modulus. By performing a length scale study and comparing the experimental results to theoretical predictions, we confirm that the mechanism underlying the observed dynamic nanomechanics is due to solid-fluid interactions (poroelasticity) at the molecular scale. Utilizing finite element modeling, the molecular-scale hydraulic permeability of the aggrecan assembly was quantified (kaggrecan = (4.8 ± 2.8) × 10(-15) m(4)/N·s) and found to be similar to the nanoscale hydraulic permeability of intact normal cartilage tissue but much lower than that of early diseased tissue. The mechanisms underlying aggrecan poroelasticity were further investigated by altering electrostatic interactions between the molecule's constituent glycosaminoglycan chains: electrostatic interactions dominated steric interactions in governing molecular behavior. While the hydraulic permeability of aggrecan layers does not change across species and age, aggrecan from adult human cartilage is stiffer than the aggrecan from newborn human tissue.

Published

2015

207. High-bandwidth AFM-based rheology is a sensitive indicator of early cartilage aggrecan degradation relevant to mouse models of osteoarthritis.

Author

Nia HT, Gauci SJ, Azadi M, Hung HH, Frank E, Fosang AJ, Ortiz C, and Grodzinsky AJ

Subjects

Aggrecans metabolism, Animals, Biomechanical Phenomena, Disease Models, Animal, Extracellular Matrix metabolism, Femur, Mice, Mice, Inbred C3H, Permeability, Cartilage physiology, Glycosaminoglycans physiology, Microscopy, Atomic Force, Osteoarthritis, Rheology methods

Abstract

Murine models of osteoarthritis (OA) and post-traumatic OA have been widely used to study the development and progression of these diseases using genetically engineered mouse strains along with surgical or biochemical interventions. However, due to the small size and thickness of murine cartilage, the relationship between mechanical properties, molecular structure and cartilage composition has not been well studied. We adapted a recently developed AFM-based nano-rheology system to probe the dynamic nanomechanical properties of murine cartilage over a wide frequency range of 1 Hz to 10 kHz, and studied the role of glycosaminoglycan (GAG) on the dynamic modulus and poroelastic properties of murine femoral cartilage. We showed that poroelastic properties, highlighting fluid-solid interactions, are more sensitive indicators of loss of mechanical function compared to equilibrium properties in which fluid flow is negligible. These fluid-flow-dependent properties include the hydraulic permeability (an indicator of the resistance of matrix to fluid flow) and the high frequency modulus, obtained at high rates of loading relevant to jumping and impact injury in vivo. Utilizing a fibril-reinforced finite element model, we estimated the poroelastic properties of mouse cartilage over a wide range of loading rates for the first time, and show that the hydraulic permeability increased by a factor ~16 from knormal=7.80×10(-16)±1.3×10(-16) m(4)/N s to kGAG-depleted=1.26×10(-14)±6.73×10(-15) m(4)/N s after GAG depletion. The high-frequency modulus, which is related to fluid pressurization and the fibrillar network, decreased significantly after GAG depletion. In contrast, the equilibrium modulus, which is fluid-flow independent, did not show a statistically significant alteration following GAG depletion., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2015

208. Dynamic nanomechanics of individual bone marrow stromal cells and cell-matrix composites during chondrogenic differentiation.

Author

Lee B, Han L, Frank EH, Grodzinsky AJ, and Ortiz C

Subjects

Animals, Biomechanical Phenomena, Cattle, Cells, Cultured, Chondrocytes cytology, Extracellular Matrix physiology, Microscopy, Atomic Force, Tissue Engineering, Cartilage physiology, Cell Differentiation, Chondrocytes physiology, Chondrogenesis, Mesenchymal Stem Cells physiology

Abstract

Dynamic nanomechanical properties of bovine bone marrow stromal cells (BMSCs) and their newly synthesized cartilage-like matrices were studied at nanometer scale deformation amplitudes. The increase in their dynamic modulus, |E(*)| (e.g., 2.4±0.4 kPa at 1 Hz to 9.7±0.2 kPa at 316 Hz at day 21, mean±SEM), and phase angle, δ, (e.g., 15±2° at 1 Hz to 74±1° at 316 Hz at day 21) with increasing frequency were attributed to the fluid flow induced poroelasticity, governed by both the newly synthesized matrix and the intracellular structures. The absence of culture duration dependence suggested that chondrogenesis of BMSCs had not yet resulted in the formation of a well-organized matrix with a hierarchical structure similar to cartilage. BMSC-matrix composites demonstrated different poro-viscoelastic frequency-dependent mechanical behavior and energy dissipation compared to chondrocyte-matrix composites due to differences in matrix molecular constituents, structure and cell properties. This study provides important insights into the design of optimal protocols for tissue-engineered cartilage products using chondrocytes and BMSCs., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2015

209. Aggrecan: approaches to study biophysical and biomechanical properties.

Author

Nia HT, Ortiz C, and Grodzinsky A

Subjects

Adult, Aggrecans ultrastructure, Animals, Biomechanical Phenomena, Cattle, Compressive Strength, Horses, Humans, Infant, Newborn, Microscopy, Atomic Force, Models, Molecular, Nanoparticles chemistry, Rheology, Aggrecans chemistry, Biophysical Phenomena

Abstract

Aggrecan, the most abundant extracellular proteoglycan in cartilage (~35 % by dry weight), plays a key role in the biophysical and biomechanical properties of cartilage. Here, we review several approaches based on atomic force microscopy (AFM) to probe the physical, mechanical, and structural properties of aggrecan at the molecular level. These approaches probe the response of aggrecan over a wide time (frequency) scale, ranging from equilibrium to impact dynamic loading. Experimental and theoretical methods are described for the investigation of electrostatic and fluid-solid interactions that are key mechanisms underlying the biomechanical and physicochemical functions of aggrecan. Using AFM-based imaging and nanoindentation, ultrastructural features of aggrecan are related to its mechanical properties, based on aggrecans harvested from human vs. bovine, immature vs. mature, and healthy vs. osteoarthritic cartilage.

Published

2015

210. Mechanics of composite elasmoid fish scale assemblies and their bioinspired analogues.

Author

Browning A, Ortiz C, and Boyce MC

Subjects

Animals, Biomechanical Phenomena, Elasticity, Finite Element Analysis, Minerals, Predatory Behavior, Stress, Mechanical, Tooth, Biomimetic Materials, Fishes anatomy & histology, Mechanical Phenomena, Skin anatomy & histology, Skin chemistry

Abstract

Inspired by the overlapping scales found on teleost fish, a new composite architecture explores the mechanics of materials to accommodate both flexibility and protection. These biological structures consist of overlapping mineralized plates embedded in a compliant tissue to form a natural flexible armor which protects underlying soft tissue and vital organs. Here, the functional performance of such armors is investigated, in which the composition, spatial arrangement, and morphometry of the scales provide locally tailored functionality. Fabricated macroscale prototypes and finite element based micromechanical models are employed to measure mechanical response to blunt and penetrating indentation loading. Deformation mechanisms of scale bending, scale rotation, tissue shear, and tissue constraint were found to govern the ability of the composite to protect the underlying substrate. These deformation mechanisms, the resistance to deformation, and the resulting work of deformation can all be tailored by structural parameters including architectural arrangement (angle of the scales, degree of scale overlap), composition (volume fraction of the scales), morphometry (aspect ratio of the scales), and material properties (tissue modulus and scale modulus). In addition, this network of armor serves to distribute the load of a predatory attack over a large area to mitigate stress concentrations. Mechanical characterization of such layered, segmented structures is fundamental to developing design principles for engineered protective systems and composites., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

211. Bio-inspired interfacial strengthening strategy through geometrically interlocking designs.

Author

Zhang Y, Yao H, Ortiz C, Xu J, and Dao M

Subjects

Biomimetics methods, Finite Element Analysis, Tensile Strength

Abstract

Many biological materials, such as nacre and bone, are hybrid materials composed of stiff brittle ceramics and compliant organic materials. These natural organic/inorganic composites exhibit much enhanced strength and toughness in comparison to their constituents and inspires enormous biomimetic endeavors aiming to synthesize materials with superior mechanical properties. However, most current synthetic composites have not exhibited their full potential of property enhancement compared to the natural prototypes they are mimicking. One of the key issues is the weak junctions between stiff and compliant phases, which need to be optimized according to the intended functions of the composite material. Motivated by the geometrically interlocking designs of natural biomaterials, here we propose an interfacial strengthening strategy by introducing geometrical interlockers on the interfaces between compliant and stiff phases. Finite element analysis (FEA) shows that the strength of the composite depends strongly on the geometrical features of interlockers including shape, size, and structural hierarchy. Even for the most unfavorable scenario when neither adhesion nor friction is present between stiff and compliant phases, the tensile strength of the composites with proper interlocker design can reach up to 70% of the ideal value. The findings in this paper would provide guidelines to the improvement of the mechanical properties of current biomimetic composites., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

212. Introduction of misoprostol for prevention of postpartum hemorrhage at the community level in Senegal.

Author

Diadhiou M, Dieng T, Ortiz C, Mall I, Dione D, and Sloan NL

Subjects

Administration, Oral, Adult, Community Health Services methods, Community Health Services organization & administration, Cost Sharing, Data Collection, Female, Humans, Maternal Health Services methods, Maternal Health Services organization & administration, Misoprostol economics, Oxytocics economics, Senegal, Time Factors, Young Adult, Midwifery education, Misoprostol therapeutic use, Oxytocics therapeutic use, Postpartum Hemorrhage prevention & control

Abstract

Objective: To demonstrate that training ensures correct administration of oral misoprostol by auxiliary midwives for prevention of postpartum hemorrhage (PPH) among women giving birth at the community level in Senegal., Methods: A 6-day training program for auxiliary midwives and supervisors, including 1 day of PPH prevention training and a practicum of 10 deliveries at health centers and 3 deliveries at maternity huts, was conducted in 2 Senegalese districts in June-July 2009. Data were collected between July and December 2009 on the administration of oral misoprostol by trained auxiliary midwives among 245 women giving birth at health centers, health posts, and maternity huts., Results: All participating women received the correct administration of oral misoprostol; however, few women delivering in the community-based maternity huts received the supervision that is locally required to administer misoprostol. Women were willing to pay for some or all of the costs of misoprostol for PPH prevention., Conclusion: Timely management of PPH is essential to reduce maternal mortality. With limited training, auxiliary midwives achieved the correct administration of oral misoprostol that can attain this goal. Community delivery supervised by a skilled attendant limits access to, and need not be a requirement for, PPH prevention., (Copyright © 2011 International Federation of Gynecology and Obstetrics. All rights reserved.)

Published

2011

213. Dynamic mechanical properties of the tissue-engineered matrix associated with individual chondrocytes.

Author

Lee B, Han L, Frank EH, Chubinskaya S, Ortiz C, and Grodzinsky AJ

Subjects

Animals, Cattle, Cells, Cultured, Chondrocytes cytology, Computer Simulation, Elastic Modulus physiology, Models, Chemical, Biomimetic Materials chemistry, Chondrocytes physiology, Extracellular Matrix chemistry, Extracellular Matrix physiology, Mechanotransduction, Cellular physiology, Models, Biological, Tissue Engineering methods

Abstract

The success of cell-based tissue engineering approaches in restoring biological function will be facilitated by a comprehensive fundamental knowledge of the temporal evolution of the structure and properties of the newly synthesized matrix. Here, we quantify the dynamic oscillatory mechanical behavior of the engineered matrix associated with individual chondrocytes cultured in vitro for up to 28 days in alginate scaffolds. The magnitude of the complex modulus (|E*|) and phase shift (delta) were measured in culture medium using Atomic Force Microscopy (AFM)-based nanoindentation in response to an imposed oscillatory deformation (amplitude approximately 5nm) as a function of frequency (f=1-316Hz), probe tip geometry (2.5microm radius sphere and 50nm radius square pyramid), and in the absence and presence of growth factors (GF, insulin growth factor-1, IGF-1, and osteogenic protein-1, OP-1). |E*| for all conditions increased nonlinearly with frequency dependence approximately f(1/2) and ranged between approximately 1 and 25kPa. This result, along with theoretical calculations of the characteristic poroelastic relaxation frequency, f(p), (approximately 50-90Hz) suggested that this time-dependent behavior was governed primarily by fluid flow-dependent poroelasticity, rather than flow-independent viscoelastic processes associated with the solid matrix. |E*(f)| increased, (f) decreased, and the hydraulic permeability, k, decreased with time in culture and with growth factor treatment. This trend of a more elastic-like response was thought to be associated with increased macromolecular biosynthesis, density, and a more mature matrix structure/organization., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

214. Protection mechanisms of the iron-plated armor of a deep-sea hydrothermal vent gastropod.

Author

Yao H, Dao M, Imholt T, Huang J, Wheeler K, Bonilla A, Suresh S, and Ortiz C

Subjects

Animals, Computer Simulation, Finite Element Analysis, Gastropoda anatomy & histology, Marine Biology, Gastropoda physiology

Abstract

Biological exoskeletons, in particular those with unusually robust and multifunctional properties, hold enormous potential for the development of improved load-bearing and protective engineering materials. Here, we report new materials and mechanical design principles of the iron-plated multilayered structure of the natural armor of Crysomallon squamiferum, a recently discovered gastropod mollusc from the Kairei Indian hydrothermal vent field, which is unlike any other known natural or synthetic engineered armor. We have determined through nanoscale experiments and computational simulations of a predatory attack that the specific combination of different materials, microstructures, interfacial geometries, gradation, and layering are advantageous for penetration resistance, energy dissipation, mitigation of fracture and crack arrest, reduction of back deflections, and resistance to bending and tensile loads. The structure-property-performance relationships described are expected to be of technological interest for a variety of civilian and defense applications.

Published

2010

215. Materials science. Bioinspired structural materials.

Author

Ortiz C and Boyce MC

Subjects

Aluminum Oxide chemistry, Animals, Chitosan chemistry, Mollusca chemistry, Tensile Strength, Biomimetic Materials chemistry, Nanocomposites chemistry

Published

2008

216. Structural and nanoindentation studies of stem cell-based tissue-engineered bone.

Author

Pelled G, Tai K, Sheyn D, Zilberman Y, Kumbar S, Nair LS, Laurencin CT, Gazit D, and Ortiz C

Subjects

Biomechanical Phenomena, Bone and Bones pathology, Microscopy, Atomic Force, Bone Substitutes chemistry, Bone and Bones physiology, Nanotechnology, Stem Cells, Tissue Engineering

Abstract

Stem cell-based gene therapy and tissue engineering have been shown to be an efficient method for the regeneration of critical-sized bone defects. Despite being an area of active research over the last decade, no knowledge of the intrinsic ultrastructural and nanomechanical properties of such bone tissue exists. In this study, we report the nanomechanical properties of engineered bone tissue derived from genetically modified mesenchymal stem cells (MSCs) overexpressing the rhBMP2 gene, grown in vivo in the thigh muscle of immunocompetent mice for 4 weeks, compared to femoral bone adjacent to the transplantation site. The two types of bone had similar mineral contents (61 and 65 wt% for engineered and femoral bone, respectively), overall microstructures showing lacunae and canaliculi (both measured by back-scattered electron microscopy), chemical compositions (measured by energy dispersive X-ray analysis), and nanoscale topographical morphologies (measured by tapping-mode atomic force microscopy imaging or TMAFM). Nanoindentation experiments revealed that the small length scale mechanical properties were statistically different with the femoral bone (indented parallel to the bone long axis) being stiffer and harder (apparent elastic modulus, E approximately 27.3+/-10.5 GPa and hardness, H approximately 1.0+/-0.7G Pa) than the genetically engineered bone (E approximately 19.8+/-5.6 GPa, H approximately 0.9+/-0.4G Pa). TMAFM imaging showed clear residual indents characteristic of viscoelastic plastic deformation for both types of bone. However, fine differences in the residual indent area (smaller for the engineered bone), pile up (smaller for the engineered bone), and fracture mechanisms (microcracks for the engineered bone) were observed with the genetically engineered bone behaving more brittle than the femoral control.

Published

2007

217. Nanomechanical properties of individual chondrocytes and their developing growth factor-stimulated pericellular matrix.

Author

Ng L, Hung HH, Sprunt A, Chubinskaya S, Ortiz C, and Grodzinsky A

Subjects

Animals, Biomechanical Phenomena, Cattle, Cells, Cultured, Chondrocytes cytology, Chondrocytes ultrastructure, Extracellular Matrix ultrastructure, Microscopy, Atomic Force, Nanostructures ultrastructure, Chondrocytes chemistry, Chondrocytes metabolism, Extracellular Matrix metabolism, Intercellular Signaling Peptides and Proteins physiology

Abstract

The nanomechanical properties of individual cartilage cells (chondrocytes) and their aggrecan and collagen-rich pericellular matrix (PCM) were measured via atomic force microscope nanoindentation using probe tips of two length scales (nanosized and micron-sized). The properties of cells freshly isolated from cartilage tissue (devoid of PCM) were compared to cells that were cultured for selected times (up to 28 days) in 3-D alginate gels which enabled PCM assembly and accumulation. Cells were immobilized and kept viable in pyramidal wells microfabricated into an array on silicon chips. Hertzian contact mechanics and finite element analyses were employed to estimate apparent moduli from the force versus depth curves. The effects of culture conditions on the resulting PCM properties were studied by comparing 10% fetal bovine serum to medium containing a combination of insulin growth factor-1 (IGF-1)+osteogenic protein-1 (OP-1). While both systems showed increases in stiffness with time in culture between days 7 and 28, the IGF-1+OP-1 combination resulted in a higher stiffness for the cell-PCM composite by day 28 and a higher apparent modulus of the PCM which is compared to the FBS cultured cells. These studies give insight into the temporal evolution of the nanomechanical properties of the pericellar matrix relevant to the biomechanics and mechanobiology of tissue-engineered constructs for cartilage repair.

Published

2007

218. Compressive nanomechanics of opposing aggrecan macromolecules.

Author

Dean D, Han L, Grodzinsky AJ, and Ortiz C

Subjects

Algorithms, Animals, Biomechanical Phenomena, Cartilage physiology, Cattle, Computer Simulation, Microscopy, Atomic Force, Nanotechnology methods, Osmolar Concentration, Static Electricity, Stress, Mechanical, Thermodynamics, Aggrecans chemistry, Models, Molecular

Abstract

In this study, we have measured the nanoscale compressive interactions between opposing aggrecan macromolecules in near-physiological conditions, in order to elucidate the molecular origins of tissue-level cartilage biomechanical behavior. Aggrecan molecules from fetal bovine epiphyseal cartilage were chemically end-grafted to planar substrates, standard nanosized atomic force microscopy (AFM) probe tips (R(tip) approximately 50 nm), and larger colloidal probe tips (R(tip) approximately 2.5 microm). To assess normal nanomechanical interaction forces between opposing aggrecan layers, substrates with microcontact printed aggrecan were imaged using contact mode AFM, and aggrecan layer height (and hence deformation) was measured as a function of solution ionic strength (IS) and applied normal load. Then, using high-resolution force spectroscopy, nanoscale compressive forces between opposing aggrecan on the tip and substrate were measured versus tip-substrate separation distance in 0.001-1M NaCl. Nanosized tips enabled measurement of the molecular stiffness of 2-4 aggrecan while colloidal tips probed the nanomechanical properties of larger assemblies (approximately 10(4) molecules). The compressive stiffness of aggrecan was much higher when using a densely packed colloidal tip than the stiffness measured for using the nanosized tip with a few aggrecan, demonstrating the importance of lateral interactions to the normal nanomechanical properties. The measured stress at 0.1M NaCl (near-physiological ionic strength) increased sharply at aggrecan densities under the tip of approximately 40 mg/ml (physiological densities are approximately 20-80 mg/ml), corresponding to an average inter-GAG spacing of 4-5 Debye lengths (4-5 nm); this characteristic spacing is consistent with the onset of significant electrostatic interactions between GAG chains of opposing aggrecan molecules. Comparison of nanomechanical data to the predictions of Poisson-Boltzmann-based models further elucidated the regimes over which electrostatic and nonelectrostatic interactions affect aggrecan stiffness in compression. The most important aspects of this study include: the incorporation of experiments at two different length scales, the use of microcontact printing to enable quantification of aggrecan deformation and the corresponding nanoscale compressive stress vs. strain curve, the use of tips of differing functionality to provide insights into the molecular mechanisms of deformation, and the comparison of experimental data to the predictions of three increasingly refined Poisson-Boltzmann (P-B)-based theoretical models for the electrostatic double layer component of the interaction.

Published

2006

219. Effect of mineral content on the nanoindentation properties and nanoscale deformation mechanisms of bovine tibial cortical bone.

Author

Tai K, Qi HJ, and Ortiz C

Subjects

Animals, Cattle, Compressive Strength physiology, Computer Simulation, Elasticity, Hardness, Hardness Tests, In Vitro Techniques, Stress, Mechanical, Weight-Bearing physiology, Calcification, Physiologic physiology, Models, Biological, Nanotechnology methods, Tibia physiology, Tibia ultrastructure

Abstract

In this paper, a multitechnique experimental and numerical modeling methodology was used to show that mineral content had a significant effect on both nanomechanical properties and ultrastructural deformation mechanisms of samples derived from adult bovine tibial bone. Partial and complete demineralization was carried out using phosphoric and ethylenediamine tetraacetic acid treatments to produce samples with mineral contents that varied between 37 and 0 weight percent (wt%). The undemineralized samples were found to have a mineral content of approximately 58 wt%. Nanoindentation experiments (maximum loads approximately 1000 microN and indentation depths approximately 500 nm) perpendicular to the osteonal axis for the approximately 58 wt% samples were found to have an estimated elastic modulus of approximately 7-12 GPa, which was 4-6x greater than that obtained for the approximately 0 wt% samples. The yield strength of the approximately 58 wt% samples was found to be approximately 0.24 GPa; 3.4x greater than that of the approximately 0 wt% sample. These results are discussed in the context of in situ and post-mortem atomic force microscopy imaging studies which show clear residual deformation after indentation for all samples studied. The partially demineralized samples underwent collagen fibril deformation and kinking without loss of the characteristic banding structure at low maximum loads (approximately 300 microN). At higher maximum loads (approximately 700 microN) mechanical denaturation of collagen fibrils was observed within the indent region, as well as disruption of interfibril interfaces and slicing through the thickness of individual fibrils leading to microcracks along the tip apex lines and outside the indent regions. A finite element elastic-plastic continuum mechanical model was able to predict the nanomechanical behavior of all samples on loading and unloading.

Published

2005

220. Nanomechanics of opposing glycosaminoglycan macromolecules.

Author

Seog J, Dean D, Rolauffs B, Wu T, Genzer J, Plaas AH, Grodzinsky AJ, and Ortiz C

Subjects

Biomechanical Phenomena methods, Computer Simulation, Elasticity, Glycosaminoglycans analysis, Humans, Macromolecular Substances chemistry, Microscopy, Atomic Force methods, Nanostructures analysis, Nanotechnology methods, Static Electricity, Stress, Mechanical, Cartilage, Articular chemistry, Cartilage, Articular physiology, Glycosaminoglycans chemistry, Models, Chemical, Nanostructures chemistry

Abstract

In this study, the net intermolecular interaction force between a chondroitin sulfate glycosaminoglycan (GAG)-functionalized probe tip and an opposing GAG-functionalized planar substrate was measured as a function of probe tip-substrate separation distance in aqueous electrolyte solutions using the technique of high resolution force spectroscopy. A range of GAG grafting densities as near as possible to native cartilage was used. A long-range repulsive force between GAGs on the probe tip and substrate was observed, which increased nonlinearly with decreasing separation distance between probe tip and substrate. Data obtained in 0.1 M NaCl was well predicted by a recently developed Poisson-Boltzmann-based theoretical model that describes normal electrostatic double layer interaction forces between two opposing surfaces of end-grafted, cylindrical rods of constant volume charge density and finite length, which interdigitate upon compression. Based on these results, the nanomechanical data and interdigitated rod model were used together to estimate the electrostatic component of the equilibrium modulus of cartilage tissue, which was then compared to that of normal adult human ankle cartilage measured in uniaxial confined compression.

Published

2005

221. Disclosing concerns of Latinas living with HIV/AIDS.

Author

Ortiz CE

Subjects

Acquired Immunodeficiency Syndrome nursing, Acquired Immunodeficiency Syndrome psychology, Cross-Sectional Studies, Female, HIV Infections nursing, HIV Infections psychology, HIV Seropositivity ethnology, HIV-1, Humans, San Francisco, Transcultural Nursing, Acquired Immunodeficiency Syndrome ethnology, Confidentiality, HIV Infections ethnology, Hispanic or Latino psychology, Self Disclosure, Truth Disclosure

Abstract

This study described the disclosing experiences of Latinas with HIV/AIDS in the San Francisco Bay Area. Limited information is available on the disclosing processes, situations and consequences. The design was a descriptive study with 19 Latinas. Content analysis was used to analyze the data. Deciding to disclose was identified as the core category. Four major categories emerged from the data. Deciding to disclose has social, psychological and economical issues. Nurses need to be aware of the disclosing issues when caring for Latinas with HIV/AIDS.

Published

2005