| 1. |
- Brismar, Torkel B., et al.
(författare)
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Magnetite Nanoparticles Can Be Coupled to Microbubbles to Support Multimodal Imaging
- 2012
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Ingår i: Biomacromolecules. - : American Chemical Society (ACS). - 1525-7797 .- 1526-4602. ; 13:5, s. 1390-1399
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Tidskriftsartikel (refereegranskat)abstract
- Microbubbles (MBs) are commonly used as injectable ultrasound contrast agent (UCA) in modern ultrasonography. Polymer-shelled UCAs present additional potentialities with respect to marketed lipid-shelled UCAs. They are more robust; that is, they have longer shelf and circulation life, and surface modifications are quite easily accomplished to obtain enhanced targeting and local drug delivery. The next generation of UCAs will be required to support not only ultrasound-based imaging methods but also other complementary diagnostic approaches such as magnetic resonance imaging or computer tomography. This work addresses the features of MBs that could function as contrast agents for both ultrasound and magnetic resonance imaging. The results indicate that the introduction of iron oxide nanoparticles (SPIONs) in the poly(vinyl alcohol) shell or on the external surface of the MBs does not greatly decrease the echogenicity of the host MBs compared with the unmodified one. The presence of SPIONs provides enough magnetic susceptibility to the MBs to accomplish good detectability both in vitro and in vivo. The distribution of SPIONs on the shell and their aggregation state seem to be key factors for the optimization of the transverse relaxation rate.
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| 2. |
- Hamid Muhammed, Hamed, et al.
(författare)
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Evaluation of Dental Implant Osseointegration Using Ultrasonic Spectrometry : A Phantom Study
- 2014
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Ingår i: WSEAS Transactions on Signal Processing. - 1790-5052 .- 2224-3488. ; 10:1, s. 194-204
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Tidskriftsartikel (refereegranskat)abstract
- One of the challenging and important problems that still needs solution within the field of dental implant surgery is to monitor the osseointegration process. Therefore, this work aims to achieve a reliable noninvasive automatic method to evaluate dental implant stability which is directly related to the grade of osseointegration. For this purpose, an experimental phantom study was performed to simulate this process and evaluate it. Ultrasonic pectrometry was proposed and used to take measurements that were processed and analyzed to estimate the stability of the simulated dental implant. The phantom that was designed and used in the experiments simulated a jawbone with a dental implant and was made of a little pool filled with soft-tissueequivalent material (with respect to ultrasound waves) and a solid cylinder of fresh oak-wood immersed into it to simulate the jawbone. A metal screw was used to simulate the dental implant. By screwing this screw into or out of the wooden cylinder, varying grades of stiffness and contact between the screw and the wooden tissues were obtained. And by this way, varying screw stability grades which simulate varying osseointegration grades were achieved. Pulse-echo ultrasound was used to measure the power spectra of the received ultrasonic echosignals. These power spectra were, at first, processed and normalized then analyzed by using the partial least squares method to estimate the corresponding implant stability or stiffness grades. The number of screwing turns (for the screw into or out of the wooden cylinder) was used as a measure of stiffness grade.The feasibility of this approach was investigated through experimental tasks and romising results were achieved. A coefficient of determination R2 of 96.4% and a mean absolute error of ±0.23 screwing turns were achieved when comparing real and estimated stiffness-grade values, indicating the high efficiency and good accuracy of this approach.
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| 3. |
- Hamid Muhammed, Hamed, et al.
(författare)
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Using Ultrasonic Spectrometry to Estimate the Stability of a Dental Implant Phantom
- 2013
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Ingår i: Engineering. - 1947-3931 .- 1947-394X. ; 5, s. 570-574
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Tidskriftsartikel (refereegranskat)abstract
- A challenging problem in dental implant surgery is to evaluate the stability of the implant. In this simulation study, an experimental phantom is used to represent a jawbone with a dental implant. It is made of a little pool filled with soft-tissue equivalent material and a disc of fresh Oakwood with a metal screw. Varying levels of contact between screw and wood are simulated by screwing in or out the screw. Initially, the screw is screwed in and fixed firmly in wood. Thereafter, the screw is screwed out, a half turn each time, to increase the gap gradually between wood and screw. Pulse-echo ultrasound is used and the power spectra of the received echo-signals are computed. These spectra are normalized then analyzed by using the partial least squares method to estimate the corresponding implant stiffness grade in terms of number of turns when beginning from the initial tight-screw state then screwing out the screw. A coefficient of determination R2 of 96.4% and a mean absolute error of ±0.23 turns are achieved when comparing real and estimated values of stiffness grades, indicating the efficiency of this approach.
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| 4. |
- Kothapalli, Satya V. V. N., 1985-, et al.
(författare)
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Dynamic and Structural Behavior of Magnetic PVA-Shelled Microbubbles : Acoustic Characterization
- 2013
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Ingår i: IEEE International Ultrasonics Symposium. - 9781467356862 ; , s. 1509-1512
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Konferensbidrag (refereegranskat)abstract
- Combination of superparamagnetic iron oxide nanoparticles (SPOINs) and the polymer-shelled microbubble (MB) are proposed to be a contrast agent for both magnetic resonance and ultrasound imaging. The introduction of nanoparticles into MBs changes the material properties of encapsulating shell, which further influences on MBs performance as an ultrasound contrast agent. Magnetic MBs were prepared in two following strategies: 1. SPIONs were attached on the surface of MBs (Type A) and 2. SPIONs were physically entrapped in the MBs shell during the initial formation of PVA shell (Type B). A modified Church model was used to fit the attenuation coefficient spectra acquired experimentally. This allowed to recalculate the viscoelastic properties, i.e. storage and loss modulus, and dynamical properties, i.e. resonance frequency and damping coefficient of two types of magnetic MBs. The cross-correlation analysis of the time-domain response from the MBs suspension was used to identify pressure threshold at which MBs shell fractures. Higher values of both viscoelastic and dynamic characteristic were identified for MBs Type B. The estimated total damping ratio above 1 suggested that the MBs Type B behave as an overdamped harmonic oscillator whereas MBs Type A with total damping ratio below 1 possess underdamped harmonic oscillator nature. The predicted resonance frequencies are approximately 13 and 27 MHz for MBs Type A and B respectively. Moreover, the fracture pressure threshold measurements revealed that, higher peak negative pressure is required to fracture MBs Type B than Type A. When the driving pulse consists of 12 cycles, pressure threshold was 1.1 MPa and 1.3 MPa for MBs Type A and B respectively. In conclusion, MBs with nanoparticles loaded on the surface (Type A) appear to be more acoustically active, demonstrate lower resonance frequency, damping and fracture pressure threshold, than MBs with nanoparticles incorporated in the shell (Type B).
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| 5. |
- Kothapalli, Satya V. V. N., et al.
(författare)
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Investigation of polymer-shelled microbubble motions in acoustophoresis
- 2016
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Ingår i: Ultrasonics. - : Elsevier. - 0041-624X .- 1874-9968. ; 70, s. 275-283
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Tidskriftsartikel (refereegranskat)abstract
- The objective of this paper is to explore the trajectory motion of microsize (typically smaller than a red blood cell) encapsulated polymer-shelled gas bubbles propelled by radiation force in an acoustic standing-wave field and to compare the corresponding movements of solid polymer microbeads. The experimental setup consists of a microfluidic chip coupled to a piezoelectric crystal (PZT) with a resonance frequency of about 2.8 MHz. The microfluidic channel consists of a rectangular chamber with a width, w, corresponding to one wavelength of the ultrasound standing wave. It creates one full wave ultrasound of a standing-wave pattern with two pressure nodes at w/4 and 3w/4 and three antinodes at 0, w/2, and w. The peak-to-peak amplitude of the electrical potential over the PZT was varied between 1 and 10 V. The study is limited to no-flow condition. From Gor'kov's potential equation, the acoustic contrast factor, Phi, for the polymer-shelled microbubbles was calculated to about -60.7. Experimental results demonstrate that the polymer-shelled microbubbles are translated and accumulated at the pressure antinode planes. This trajectory motion of polymer-shelled microbubbles toward the pressure antinode plane is similar to what has been described for other acoustic contrast particles with a negative Phi. First, primary radiation forces dragged the polymer-shelled microbubbles into proximity with each other at the pressure antinode planes. Then, primary and secondary radiation forces caused them to quickly aggregate at different spots along the channel. The relocation time for polymer-shelled microbubbles was 40 times shorter than that for polymer microbeads, and in contrast to polymer microbeads, the polymer-shelled microbubbles were actuated even at driving voltages (proportional to radiation forces) as low as 1 V. In short, the polymer-shelled microbubbles demonstrate the behavior attributed to the negative acoustic contrast factor particles and thus can be trapped at the antinode plane and thereby separated from particles having a positive acoustic contrast factor, such as for example solid particles and cells. This phenomenon could be utilized in exploring future applications, such as bioassay, bioaffinity, and cell interaction studies in vitro in a well-controlled environment.
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| 6. |
- Kothapalli, Satya V.V.N. 1985-, et al.
(författare)
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Investigation of Polymer-Shelled Microbubble Motions in Acoustophoresis
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Annan publikation (övrigt vetenskapligt/konstnärligt)abstract
- The objective of this paper is to explore the trajectory motion of microsize (typically smaller than a redblood cell) encapsulated polymer-shelled gas bubbles propelled by radiation force in an acousticstanding-wave field and to compare the corresponding movements of solid polymer microbeads. Theexperimental setup consists of a microfluidic chip coupled to a piezoelectric crystal (PZT) with aresonance frequency of about 2.8 MHz. The microfluidic channel consists of a rectangular chamberwith a width, w, corresponding to one wavelength of the ultrasound standing wave. It creates one fullwave ultrasound of a standing-wave pattern with two pressure nodes at4w and43w and threeantinodes at 0,2w , and w. The peak-to-peak amplitude of the electrical potential over the PZT wasvaried between 1 and 10 volts. From Gor’kov’s potential equation, the acoustic contrast factor, Φ, forthe polymer-shelled microbubbles was calculated to about -60.7. Experimental results demonstratethat the polymer-shelled microbubbles are translated and accumulated at the pressure antinode planes.This trajectory motion of polymer-shelled microbubbles toward the pressure antinode plane is similarto what has been described for other acoustic contrast particles with a negative Φ. First, primaryradiation forces dragged the polymer-shelled microbubbles into proximity with each other at thepressure antinode planes. Then, secondary radiation forces caused them to aggregate at different spotsalong the channel. The relocation time for polymer-shelled microbubbles was 40 times shorter thanthat for polymer microbeads, and in contrast to polymer microbeads, the polymer-shelledmicrobubbles were actuated even at driving voltages (proportional to radiation forces) as low as 1 volt.In short, the polymer-shelled microbubbles demonstrate the behavior attributed to the negativeacoustic contrast factor particles and thus can be trapped at the antinode plane and thereby seperatedfrom solid particles, such as cells. This phenomenon could be utilized in exploring future applications,such as bioassay, bioaffinity, and cell interaction studies in vitro in a well-controlled environment.
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| 7. |
- Kothapalli, Satya V.V.N. 1985-
(författare)
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Nano-Engineered Contrast Agents : Toward Multimodal Imaging and Acoustophoresis
- 2015
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Diagnostic ultrasound (US) is safer, quicker and cheaper than other diagnostic imaging modalities. Over the past two decades, the applications of US imaging has been widened due to the development of injectable, compressible and encapsulated microbubbles (MBs) that provide an opportunity to improve conventional echocardiographic imaging, blood flow assessment and molecular imaging. The encapsulating material is manufactured by different biocompatible materials such as proteins, lipids or polymers. In current research, researchers modify the encapsulated shell with the help of advanced molecular chemistry techniques to load them with dyes (for fluorescent imaging), nanoparticles and radioisotopes (for multimodal imaging) or functional ligands or therapeutic gases (for local drug delivery). The echogenicity and the radial oscillation of MBs is the result of their compressibility, which undoubtedly varies with the encapsulated shell characteristics such as rigidity or elasticity.In this thesis, we present acoustic properties of novel type of polyvinyl alcohol (PVA)-shelled microbubble (PVA-MB) that was further modified with superparamagnetic iron oxide nanoparticles (SPIONs) to work as a dual-modal contrast agent for magnetic resonance (MR) imaging along with US imaging. Apparently, the shell modification changes their mechanical characteristics, which affects their acoustic properties. The overall objective of the thesis is to investigate the acoustic properties of modified and unmodified PVA-MBs at different ultrasound parameters.The acoustic and mechanical characterization of SPIONs modified PVA-MBs revealed that the acoustical response depends on the SPION inclusion strategy. However they retain the same structural characteristics after the modification. The modified MBs with SPIONs included on the surface of the PVA shell exhibit a soft-shelled behavior and produce a higher echogenicity than the MBs with the SPIONs inside the PVA shell. The fracturing mechanism of the unmodified PVA-MBs was identified to be different from the other fracturing mechanisms of conventional MBs. With the interaction of high-pressure bursts, the air gas core is squeezed out through small punctures in the PVA shell. During the fracturing, the PVA-MBs exhibit asymmetric (other modes) oscillations, resulting in sub- and ultra-harmonic generation. Exploiting the US imaging at the other modes of the oscillation of the PVA-MBs would provide an opportunity to visualize very low concentrations of (down to single) PVA-MBs. We further introduced the PVA-MBs along with particles mimicking red blood cells in an acoustic standing-wave field to observe the acoustic radiation force effect. We observed that the compressible PVA-MBs drawn toward pressure antinode while the solid blood phantoms moved toward the pressure node. This acoustic separation method (acoustophoresis) could be an efficient tool for studying the bioclearance of the PVA-MBs in the body, either by collecting blood samples (in-vitro) or by using the extracorporeal medical procedure (ex-vivo) at different organs.Overall, this work contributes significant feedback for chemists (to optimize the nanoparticle inclusion) and imaging groups (to develop new imaging sequences), and the positive findings pave new paths and provide triggers to engage in further research.
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| 8. |
- Poehlmann, Melanie, et al.
(författare)
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On the interplay of shell structure with low- and high-frequency mechanics of multifunctional magnetic microbubbles
- 2014
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Ingår i: Soft Matter. - : Royal Society of Chemistry (RSC). - 1744-683X .- 1744-6848. ; 10:1, s. 214-226
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Tidskriftsartikel (refereegranskat)abstract
- Polymer-shelled magnetic microbubbles have great potential as hybrid contrast agents for ultrasound and magnetic resonance imaging. In this work, we studied US/MRI contrast agents based on air-filled poly(vinyl alcohol)-shelled microbubbles combined with superparamagnetic iron oxide nanoparticles (SPIONs). The SPIONs are integrated either physically or chemically into the polymeric shell of the microbubbles (MBs). As a result, two different designs of a hybrid contrast agent are obtained. With the physical approach, SPIONs are embedded inside the polymeric shell and with the chemical approach SPIONs are covalently linked to the shell surface. The structural design of hybrid probes is important, because it strongly determines the contrast agent's response in the considered imaging methods. In particular, we were interested how structural differences affect the shell's mechanical properties, which play a key role for the MBs' US imaging performance. Therefore, we thoroughly characterized the MBs' geometric features and investigated low-frequency mechanics by using atomic force microscopy (AFM) and high-frequency mechanics by using acoustic tests. Thus, we were able to quantify the impact of the used SPIONs integration method on the shell's elastic modulus, shear modulus and shear viscosity. In summary, the suggested approach contributes to an improved understanding of structure-property relations in US-active hybrid contrast agents and thus provides the basis for their sustainable development and optimization.
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| 9. |
- Sciallero, Claudia, et al.
(författare)
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Acoustic characterization and contrast imaging of microbubbles encapsulated by polymeric shells coated or filled with magnetic nanoparticles
- 2013
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Ingår i: Journal of the Acoustical Society of America. - : Acoustical Society of America (ASA). - 0001-4966 .- 1520-8524. ; 134:5, s. 3918-3930
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Tidskriftsartikel (refereegranskat)abstract
- The combination of superparamagnetic iron oxide nanoparticles with polymeric air-filled microbubbles is used to produce two types of multimodal contrast agents to enhance medical ultrasound and magnetic resonance imaging. The nanoparticles are either covalently linked to the shell or physically entrapped into the shell. In this paper, the characterization of the acoustic properties (backscattered power, fracturing pressure, attenuation and dispersion of the ultrasonic wave) and ultrasound imaging of the two types of magnetic microbubbles are presented. In vitro B-mode images are generated using a medical ultrasound scanner by applying a nonconventional signal processing technique that is suitable to detect polymeric bubbles and based on the combination of multipulse excitation and chirp coding. Even if both types of microbubbles can be considered to be effective ultrasound contrast agents, the different structure of the shell loaded with nanoparticles has a pronounced effect on the echogenicity and the detection sensitivity of the imaging technique. The best results are obtained using microbubbles that are externally coated with nanoparticles. A backscattered power of 20 dB was achieved at lower concentration, and an increment of 8 dB in the contrast-to-tissue ratio was observed with respect to the more rigid microbubbles with particles entrapped into the shell.
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