A new biomimetic composite hip prosthesis (stem) was designed to obtain properties similar to those of the contiguous bone, in particular stiffness, to allow normal loading of the surrounding femoral bone. This normal loading would reduce excessive stress shielding, known to result in bone loss, and micromotions at the bone-implant interface, leading to aseptic prosthetic loosening. The design proposed is based on a hollow substructure made of hydroxyapatite-coated, continuous carbon fiber (CF) reinforced polyamide 12 (PA12) composite with an internal soft polymer-based core. Different composite configurations were studied to match the properties of host tissue. Nonlinear three-dimensional analysis of the hip prosthesis was carried out using a three-dimensional finite element bone model based on the composite femur. The performance of composite-based hip and titanium alloybased (Ti-6Al-4V) stems embedded into femoral bone was compared. The effect of core stiffness and ply configuration was also analyzed. Results show that stresses in composite stem are lower than those in Ti stem, and that the femoral bone implanted with composite structure sustains more load than the one implanted with Ti stem. Micromotions in the composite stem are significantly smaller than those in Ti stem over the entire bone-implant surface because of the favorable interfacial stress distribution.
Compositional and structural patterns play a crucial role in the function of many biological tissues. In the present work, for nanofibrillar hydrogels formed by chemically cross-linked cellulose nanocrystals (CNC) and gelatin, we report a microextrusion-based 3D printing method to generate structurally anisotropic hydrogel sheets with CNCs aligned in the direction of extrusion. We prepared hydrogels with a uniform composition, as well as hydrogels with two different types of compositional gradients. In the first type of gradient hydrogel, the composition of the sheet varied parallel to the direction of CNC alignment. In the second hydrogel type, the composition of the sheet changed orthogonally to the direction of CNC alignment. The hydrogels exhibited gradients in structure, mechanical properties, and permeability, all governed by the compositional patterns, as well as cytocompatibility. These hydrogels have promising applications for both fundamental research and for tissue engineering and regenerative medicine.
Centrins are calcium binding proteins that belong to
the EF-hand
superfamily with diverse biological functions. Herein we present the
first systematic study that establishes the relative stability of
related centrins via complementary biophysical techniques. Our results
define the stepwise molecular behavior of human centrins by two-dimensional
infrared (2D IR) correlation spectroscopy, the change in heat capacity
and enthalpy of denaturation by differential scanning calorimetry,
and the relative stability of the helical regions of centrins by circular
dichroism. More importantly, 2D IR correlation spectroscopy provides
unique information about the similarities and differences in dynamics
between these related proteins. The thermally induced molecular behavior
of human centrins can be used to predict biological target interactions
that have a relative dependence on calcium affinity. This information
is essential for understanding why certain isoforms may be used to
rescue a phenotype and therefore also for explaining the different
functions these proteins may have in vivo. Furthermore, this comparative
approach can be applied to the study of recombinant therapeutic protein
candidates for the treatment of disease states.
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