Yipeng Wu scite author profile

The Simplified Reference Tissue Model (SRTM) produces functional images of receptor binding parameters using an input function derived from a reference region and assuming a model with one tissue compartment. Three parameters are estimated: binding potential (BP), relative delivery (R1), and the reference region clearance constant k'2. Since k'2 should not vary across brain pixels, the authors developed a two-step method (SRTM2) using a global value of k'2. Whole-brain simulations were performed using human input functions and rate constants for [18F]FCWAY, [11C]flumazenil, and [11C]raclopride, and parameter SD and bias were determined for SRTM and SRTM2. The global mean of k'2 was slightly biased (2% to 6%), but the median was unbiased (<1%) and was used as the global value. Binding potential noise reductions with SRTM2 were 4% to 14%, 20% to 53%, and 10% to 30% for [18F]FCWAY, [11C]flumazenil, and [11C]raclopride, respectively, with larger reductions for shorter scans. R1 noise reduction was larger than that of BP. Simulations were also performed to assess bias when the reference and/or tissue regions followed a two-tissue compartment model. Owing to the constrained k'2, SRTM2 showed somewhat larger biases due to violations of the one-compartment model assumption. These studies demonstrate that SRTM2 should be a useful method to improve the quality of neuroreceptor functional images.

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Noise Reduction in the Simplified Reference Tissue Model for Neuroreceptor Functional Imaging

Carson

2002

J Cereb Blood Flow Metab

322

167

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Comparison of electromagnetic and piezoelectric vibration energy harvesters: Model and experiments

Arroyo

Badel

Formosa

et al. 2012

Sensors and Actuators A: Physical

133

106

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Novel piezoelectric bistable oscillator architecture for wideband vibration energy harvesting

Liu¹,

Badel²,

Formosa³

et al. 2013

Smart Mater. Struct.

134

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Bistable vibration energy harvesters are attracting more and more interest because of their capability to scavenge energy over a large frequency band. The bistable effect is usually based on magnetic interaction or buckled beams. This paper presents a novel architecture based on amplified piezoelectric structures. This buckled spring–mass architecture allows the energy of the dynamic mass to be converted into electrical energy in the piezoelectric materials as efficiently as possible. Modeling and design are performed and a normalized expression of the harvester behavior is given. Chirp and band-limited noise excitations are used to evaluate the proposed harvester’s performances. Simulation and experimental results are in good agreement. A method of using a spectrum plot for investigating the interwell motion is presented. The effect of the electric load impedance matching strategy is also studied. Results and comparisons with the literature show that the proposed device combines a large bandwidth and a high power density.

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Yipeng Wu

Noise Reduction in the Simplified Reference Tissue Model for Neuroreceptor Functional Imaging

Noise Reduction in the Simplified Reference Tissue Model for Neuroreceptor Functional Imaging

Comparison of electromagnetic and piezoelectric vibration energy harvesters: Model and experiments

Novel piezoelectric bistable oscillator architecture for wideband vibration energy harvesting

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