22 research outputs found
Depth-encoded optical coherence elastography for simultaneous volumetric imaging of two tissue faces
Australian Research Council (ARC); National Health and Medical Research Council (NHMRC); National Breast Cancer Foundation (NBCF); Department of Health, Government of Western Australia.Depth-encoded optical coherence elastography (OCE) enables simultaneous acquisition of two three-dimensional (3D) elastograms from opposite sides of a sample. By the choice of suitable path-length differences in each of two interferometers, the detected carrier frequencies are separated, allowing depth-ranging from each interferometer to be performed simultaneously using a single spectrometer. We demonstrate depth-encoded OCE on a silicone phantom and a freshly excised sample of mouse liver. This technique minimizes the required spectral detection hardware and halves the total scan time. Depth-encoded OCE may expedite clinical translation in time-sensitive applications requiring rapid 3D imaging of multiple tissue surfaces, such as tumor margin assessment in breast-conserving surgery.PostprintPeer reviewe
Preliminary Studies of Porous GaNbased Dye-Sensitized Solar Cells
This work presents the preliminary studies of porous gallium nitride (GaN) based dye-sensitized solar
cells (DSSC). Porous GaN was fabricated using photo-assisted electrochemical etching (PEC), then
characterized in terms of its morphological, structural, optical and vibrational aspects. Next, the
sample underwent sensitization through immersing in N719 ruthenium based dye for one day. For the
DSSC assembly, the dyed porous GaN would serve as anode while platinum (Pt) coated fluorinedoped
tin oxide (FTO) glass being the cathode. A thin glass spacer separates the anode/cathode,
while triiodide/iodide redox electrolyte would fill the gap between them. Current density-voltage (J-V)
curves was obtained under light illumination and used to determine the essential electrical parameters
of the DSSC. The open circuit potential <Voc). short-circuit current density (Jsc). and efficiency (TJ) for
the aforementioned were 638.8 mV, 0.81 mA/cm2
, and 0.2% respectively. Aside from that, similar
works have been repeated here for as-grown GaN, however, the resultant efficiency was ten times
lower than that of porous GaN
Stability and Decay Rates of Non-Isotropic Attractive Bose-Einstein Condensates
Non-Isotropic Attractive Bose-Einstein condensates are investigated with
Newton and inverse Arnoldi methods. The stationary solutions of the
Gross-Pitaevskii equation and their linear stability are computed. Bifurcation
diagrams are calculated and used to find the condensate decay rates
corresponding to macroscopic quantum tunneling, two-three body inelastic
collisions and thermally induced collapse.
Isotropic and non-isotropic condensates are compared. The effect of
anisotropy on the bifurcation diagram and the decay rates is discussed.
Spontaneous isotropization of the condensates is found to occur. The influence
of isotropization on the decay rates is characterized near the critical point.Comment: revtex4, 11 figures, 2 tables. Submitted to Phys. Rev.
Full Scale Instrumented Pile Load Test for the Port Mann Bridge, Surrey, British Columbia, Canada
Biocompatibility and bone formation with porous modified PMMA in normal and irradiated mandibular tissue
A cemented mandibular endoprosthesis is a potentially viable option for mandibular reconstruction after ablative surgery. The commonly used PMMA cement has the inherent weakness of a lack of bioactivity. Improvement by the addition of porosities and bioactive compounds like calcium phosphates may resolve this issue. OBJECTIVE: The objective of this study was to assess the bone and tissue response to two modified PMMA cements with post-operative radiation as an additional influencing factor. MATERIALS & METHODS: An in vivo animal study was performed using a mandibular rabbit model. A porous PMMA cement (A) and a porous cement incorporated with Beta-tricalcium phosphate particles (b-TCP) (B) were placed in bilateral mandibular defects with exposed roots and mandibular nerve of 20 animals. Half of the animals underwent additional post-operative radiation. RESULTS: The animals were healthy with only a minor complication in one rabbit. Temperature analysis showed no significant risk of thermal necrosis with the maximal in vivo cement temperature at 37.8 degrees C. Histology demonstrated: (1) good bone ingrowth around the defect as well as within the pores of the cement and defect bridging was achieved in 70% of the specimens after 12-15 weeks of implantation, (2) no pulpal injury with minor secondary cementum response, (3) an intact mandibular nerve with no inflammation, (4) extensive degradation and resorption of the b-TCP particles by 12-15 weeks, and (5) presence of an intervening thin fibrous tissue at the bone-to-cement interface. Histomorphometrical analysis revealed that there was no difference between the different cements and the presence or absence of post-operative radiation. The 12-15 weeks specimens showed significantly more bone ingrowth and bone maturity than the 4-7 weeks specimens. CONCLUSION: Both modified PMMA cements have good biocompatibility, bioactivity and support bone ingrowth and additional post-operative radiation did not show any negative effects
Depth-encoded optical coherence elastography for simultaneous volumetric imaging of two tissue faces
Depth-encoded optical coherence elastography (OCE) enables simultaneous acquisition of two three-dimensional (3D) elastograms from opposite sides of a sample. By the choice of suitable path-length differences in each of two interferometers, the detected carrier frequencies are separated, allowing depth-ranging from each interferometer to be performed simultaneously using a single spectrometer. We demonstrate depth-encoded OCE on a silicone phantom and a freshly excised sample of mouse liver. This technique minimizes the required spectral detection hardware and halves the total scan time. Depth-encoded OCE may expedite clinical translation in time-sensitive applications requiring rapid 3D imaging of multiple tissue surfaces, such as tumor margin assessment in breast-conserving surgery