Self-reinforced Hybrid Polyethylene/MCM-41 Nanocomposites: In-situ Polymerisation and Effect of MCM-41 Content on Rigidity

Campos, J. M.; Perez, E.; Ribeiro, M. R.; Paulo Lourenco, J.; Cerrada, M. L.

doi:10.1166/jnn.2009.1298

Journal Article

Self-reinforced Hybrid Polyethylene/MCM-41 Nanocomposites: In-situ Polymerisation and Effect of MCM-41 Content on Rigidity

Campos, J. M. ; Paulo Lourenco, J. ; Perez, E. ; Cerrada, M. L. ; Ribeiro, M. R. ; DESY

2009
American Scientific Publ. Stevenson Ranch, Calif.

Journal of nanoscience and nanotechnology 9, 3966-3974 (2009) [10.1166/jnn.2009.1298]

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Please use a persistent id in citations: doi:10.1166/jnn.2009.1298

Abstract: Dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) is a widely used technique for assessing tissue physiology. Spoiled gradient echo (SPGR) pulse sequences are one of the most common methods for acquisition of DCE-MRI data, providing high temporal and spatial resolution with strong T(1)-weighting. Conversion of SPGR signal to concentration is briefly reviewed, and a new closed-form expression for concentration measurement uncertainty for finite signal-to-noise ratio (SNR) and baseline scan time is derived. This result is applicable to arbitrary concentration-dependent relaxation rate and is valid over the same domain as the theoretical SPGR signal equation. Expressions for the lower and upper bounds on measurable concentration are also derived. The existence of a concentration- and tissue-dependent optimal flip angle that minimizes concentration uncertainty is demonstrated and it is shown that, for clinically relevant pulse sequence parameters, this optimal flip angle is significantly larger than the corresponding Ernst angle. Analysis of three pulse sequences from the DCE-MRI literature shows that optimization of flip angle using the methods discussed here leads to potential improvements of 10-1166% in effective SNR over the 0.5-5.0 mM concentration range with minimal or no loss of measurement accuracy down to 0.1 mM. In vivo data from three study patients provide further support for our theoretical expression for concentration measurement uncertainty, with predicted and experimental estimates agreeing to within +/- 30%. Equations for concentration bias resulting from biases in flip angle and from pre-contrast relaxation time and contrast relaxivity (both longitudinal and transverse) are also derived in closed-form. The resulting equations show the potential for significant contributions to bias in concentration measurement arising from even relatively small mis-specification of flip angle and/or pre-contrast longitudinal relaxation time, particularly at high contrast concentrations.

Keyword(s): Air (MeSH) ; Algorithms (MeSH) ; Contrast Media: pharmacology (MeSH) ; Dose-Response Relationship, Drug (MeSH) ; Humans (MeSH) ; Image Processing, Computer-Assisted: instrumentation (MeSH) ; Image Processing, Computer-Assisted: methods (MeSH) ; Imaging, Three-Dimensional: instrumentation (MeSH) ; Imaging, Three-Dimensional: methods (MeSH) ; Kinetics (MeSH) ; Magnetic Resonance Imaging: instrumentation (MeSH) ; Magnetic Resonance Imaging: methods (MeSH) ; Models, Statistical (MeSH) ; Phantoms, Imaging (MeSH) ; Reproducibility of Results (MeSH) ; Sensitivity and Specificity (MeSH) ; Uncertainty (MeSH) ; Contrast Media