@phdthesis{Richter2021, author = {Richter, Julian Alexander J{\"u}rgen}, title = {Wave-CAIPI for Accelerated Dynamic MRI of the Thorax}, doi = {10.25972/OPUS-23207}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-232071}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {In summary, the wave-CAIPI k-space trajectory presents an efficient sampling strategy for accelerated MR acquisitions. Using wave-CAIPI in parallel imaging reconstructions leads to a reduced noise level in the reconstructed images, compared to the Cartesian standard trajectory. This effect could be quantified by means of noise and SNR calculations. An SNR gain can be traded for a reduced scan time, i.e., additional undersampling, or for an enhanced image quality, keeping scan time constant. Acceleration of MR imaging is especially important in dynamic applications, since these examinations are inherently time-consuming. The impact of wave-CAIPI sampling on image quality and its potential for scan time reduction was investigated for two dynamic applications: self-gated dynamic 3D lung MRI during free breathing and cardiac 4D flow MRI. Dynamic 3D Lung MRI By employing wave-CAIPI sampling in self-gated, free-breathing dynamic 3D lung MRI for the purpose of radiotherapy treatment planning, the image quality of accelerated scans could be enhanced. Volunteer examinations were used to quantify image quality by means of similarity between accelerated and reference images. To this end, the normalized mutual information and the root-mean-square error were chosen as quantitative image similarity measures. The wave-CAIPI sampling was shown to exhibit superior quality, especially for short scan times. The values of the normalized mutual information were (10.2 +- 7.3)\% higher in the wave-CAIPI case -- the root-mean-square error was (18.9 +- 13.2)\% lower on average. SNR calculations suggest an average SNR benefit of around 14\% for the wave-CAIPI, compared to Cartesian sampling. Resolution of the lung in 8 breathing states can be achieved in only 2 minutes. By using the wave-CAIPI k-space trajectory, precise tumor delineation and assessment of respiration-induced displacement is facilitated. Cardiac 4D Flow MRI In 4D flow MRI, acceleration of the image acquisition is essential to incorporate the corresponding scan protocols into clinical routine. In this work, a retrospective 6-fold acceleration of the image acquisition was realized. Cartesian and wave-CAIPI 4D flow examinations of healthy volunteers were used to quantify uncertainties in flow parameters for the respective sampling schemes. By employing wave-CAIPI sampling, the estimated errors in flow parameters in 6-fold accelerated scans could be reduced by up to 55\%. Noise calculations showed that the noise level in 6-fold accelerated 4D flow acquisitions with wave-CAIPI is 43\% lower, compared to Cartesian sampling. Comparisons between Cartesian and wave-CAIPI 4D flow examinations with a prospective acceleration factor R=2 revealed small, but partly statistically significant discrepancies. Differences between 2-fold and 6-fold accelerated wave-CAIPI scans are comparable to the differences between Cartesian and wave-CAIPI examinations at R=2. Wave-CAIPI 4D flow acquisitions of the aorta could be performed with an average, simulated scan time of under 4 minutes, with reduced uncertainties in flow parameters. Important visualizations of hemodynamic flow patterns in the aorta were only slightly affected by undersampling in the wave-CAIPI case, whereas for Cartesian sampling, considerable discrepancies were observed.}, subject = {Magnetresonanztomographie}, language = {en} } @phdthesis{MendesPereira2019, author = {Mendes Pereira, Lenon}, title = {Morphological and Functional Ultrashort Echo Time (UTE) Magnetic Resonance Imaging of the Human Lung}, doi = {10.25972/OPUS-18317}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-183176}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2019}, abstract = {In this thesis, a 3D Ultrashort echo time (3D-UTE) sequence was introduced in the Self-gated Non-Contrast-Enhanced Functional Lung Imaging (SENCEFUL) framework. The sequence was developed and implemented on a 3 Tesla MR scanner. The 3D-UTE technique consisted of a nonselective RF pulse followed by a koosh ball quasi-random sampling order of the k-space. Measurements in free-breathing and without contrast agent were performed in healthy subjects and a patient with lung cancer. A gating technique, using a combination of different coils with high signal correlation, was evaluated in-vivo and compared with a manual approach of coil selection. The gating signal offered an estimation of the breathing motion during measurement and was used as a reference to segment the acquired data into different breathing phases. Gradient delays and trajectory errors were corrected during post-processing using the Gradient Impulse Response Function. Iterative SENSE was then applied to determine the fully sampled data. In order to eliminate signal changes caused by motion, a 3D image registration was employed, and the results were compared to a 2D image registration method. Ventilation was assessed in 3D and regionally quantified by monitoring the signal changes in the lung parenchyma. Finally, image quality and quantitative ventilation values were compared to the standard 2D-SENCEFUL technique. 3D-UTE, combined with an automatic gating technique and SENCEFUL MRI, offered ventilation maps with high spatial resolution and SNR. Compared to the 2D method, UTE-SENCEFUL greatly improved the clinical quality of the structural images and the visualization of the lung parenchyma. Through-plane motion, partial volume effects and ventilation artifacts were also reduced with a three-dimensional method for image registration. UTE-SENCEFUL was also able to quantify regional ventilation and presented similar results to previous studies.}, subject = {Kernspintomografie}, language = {en} } @phdthesis{Carinci2017, author = {Carinci, Flavio}, title = {Quantitative Characterization of Lung Tissue Using Proton MRI}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-151189}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2017}, abstract = {The focus of the work concerned the development of a series of MRI techniques that were specifically designed and optimized to obtain quantitative and spatially resolved information about characteristic parameters of the lung. Three image acquisition techniques were developed. Each of them allows to quantify a different parameter of relevant diagnostic interest for the lung, as further described below: 1) The blood volume fraction, which represents the amount of lung water in the intravascular compartment expressed as a fraction of the total lung water. This parameter is related to lung perfusion. 2) The magnetization relaxation time T\(_2\) und T� *\(_2\) , which represents the component of T\(_2\) associated with the diffusion of water molecules through the internal magnetic field gradients of the lung. Because the amplitude of these internal gradients is related to the alveolar size, T\(_2\) und T� *\(_2\) can be used to obtain information about the microstructure of the lung. 3) The broadening of the NMR spectral line of the lung. This parameter depends on lung inflation and on the concentration of oxygen in the alveoli. For this reason, the spectral line broadening can be regarded as a fingerprint for lung inflation; furthermore, in combination with oxygen enhancement, it provides a measure for lung ventilation.}, subject = {Kernspintomografie}, language = {en} } @article{UkenaSchirrenKlotzetal.1985, author = {Ukena, D. and Schirren, C. G. and Klotz, Karl-Norbert and Schwabe, U.}, title = {Evidence for an A\(_2\) adenosine receptor in guinea pig lung}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-60202}, year = {1985}, abstract = {Adenosine receptors in guinea pig lung were characterized by measurement of cyclic AMP formation and radioligand binding. 5'-N-Ethylcarboxamidoadenosine (NECA) increased cyclic AMP Ievels in lung slices about 4-fold over basal values with an EC\(_{50}\) of 0.32 \(\mu\)mol/l. N\(^6\) - R-(- )-Phenylisopropyladenosine (R-PIA) was 5-fold less potent than NECA. 5'-N-Methylcarboxamidoadenosine (MECA) and 2-chloroadenosine had EC\(_{50}\)-values of 0.29 and 2.6 \(\mu\)mol/l, whereas adenosine and inosine had no effect. The adenosine receptors in guinea pig Iung can therefore be classified as A\(_2\) receptors. Several xanthine derivatives antagonized the NECA-induced increase in cyclic AMP levels. 1,3-Diethyl-8-phenylxanthine (DPX; K\(_i\) 0.14 \(\mu\)mol/l) was the most potent analogue, followed by 8-phenyltheophylline (K\(_i\) 0.55 \(\mu\)mol/l), 3-isobutyl-1-methylxanthine (IBMX; K\(_i\) 2.9 \(\mu\)mol/l) and theophylline (K\(_i\) 8.1 \(\mu\)mol/l). In contrast, enprofylline (1 mmol/1) enhanced basal and NECA-stimulated cyclic AMP formation. In addition, we attempted to characterize these receptors in binding studies with [\(^3\)H]NECA. The K\(_D\) for [\(^3\)H] NECA was 0.25 \(\mu\)mol/l and the maximal number of binding sites was 12 pmol/mg protein. In competition experiments MECA (K\(_i\) 0.14 \(\mu\)mol/l) was the most potent inhibitor of [\(^3\)H] NECA binding, followed by NECA (K\(_i\) 0.19 \(\mu\)mol/l) and 2-chloroadenosine (K\(_i\) 1.4 \(\mu\)mol/l). These results correlate well with the EC\(_{50}\)- values for cyclic AMP formation in lung slices. However, the K\(_i\)-values of R-PIA and theophylline were 240 and 270 \(\mu\)mol/l, and DPX and 8-phenyltheophylline did not compete for [\(^3\)H]NECA binding sites. Therefore, a complete characterization of A\(_2\) adenosine receptors by [\(^3\)H] NECA binding was not achieved. In conclusion, our results show the presence of adenylate cyclase-coupled A\(_2\) adenosiile receptors in lung tissue which are antagonized by several xanthines.}, subject = {Toxikologie}, language = {en} } @phdthesis{Arnold2008, author = {Arnold, Johannes F. T.}, title = {Funktionelle Bildgebung der Lunge und des Bronchialkarzinoms mittels Magnetresonanztomographie}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-26388}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Ziel dieser Arbeit war es, die Magnetresonanztomographie (MRT) an der Lunge als Alternative zur traditionellen Lungenbildgebung voranzutreiben. So sollten MRT-Verfahren zur regionalen und quantitativen Lungenfunktionspr{\"u}fung f{\"u}r die klinische Routine entwickelt werden. Im Hinblick auf die Strahlentherapie von Patienten mit Bronchialkarzinom sollen funktionelle Lungenareale erkannt werden, um diese w{\"a}hrend der Bestrahlung optimal schonen zu k{\"o}nnen. An den zahlreichen Luft-Gewebe-Grenzfl{\"a}chen in der Lunge entstehen Magnetfeldinhomogenit{\"a}ten. Daraus resultiert ein schneller Zerfall des MRT-Signals in der Lunge. Es wurde in dieser Arbeit ein Ansatz aufgezeigt, um die Ursache f{\"u}r den raschen Signalzerfall, n{\"a}mlich die unterschiedlichen magnetischen Suszeptibilit{\"a}ten von Luftr{\"a}umen und Lungengewebe, zu beseitigen. Durch die intravaskul{\"a}re Injektion von paramagnetischen Kontrastmitteln kann die Suszeptibilit{\"a}t des Blutes an die Suszeptibilit{\"a}t der Luftr{\"a}ume angeglichen werden. Durch die Entwicklung einer MR-kompatiblen aktiven Atemkontrolle (MR-ABC) wurde in dieser Arbeit ein weiteres fundamentales Problem der Lungen-MRT adressiert: Die Bewegung w{\"a}hrend der Datenakquisition. Die MR-ABC detektiert Herzschlag und Atemposition und ist in der Lage die Atembewegung in jeder beliebigen Atemphase reproduzierbar f{\"u}r eine definierte Zeit auszusetzen. Dies wird durch einen Verschluss der Atemluftzufuhr realisiert. Traditionelle Verfahren k{\"o}nnen zwar ebenfalls die Atemphase detektieren, gestatten jedoch nicht deren Konservierung. Es wurde demonstriert, dass mit der MR-ABC hochaufl{\"o}sende Bilder der Lunge in hoher Bildqualit{\"a}t und durch die Verwendung langer Akquisitionsfenster in relativ kurzer Messzeit erreicht werden k{\"o}nnen. Eine regionale Lungenfunktionspr{\"u}fung ist f{\"u}r die Diagnose und Evaluierung vieler Krankheitsbilder vorteilhaft. In diesem Sinne wird seit einigen Jahren das Potential der Sauerstoff-verst{\"a}rkten Lungen-MRT erforscht, die auf den paramagnetischen Eigenschaften des molekularen Sauerstoffs basiert. Im Blut gel{\"o}ster Sauerstoff f{\"u}hrt zu einer Verk{\"u}rzung der T1-Relaxationszeit. Statt diese T1-Verk{\"u}rzung quantitativ zu bestimmen wird aus praktischen Gr{\"u}nden meist ein T1-gewichteter Ansatz gew{\"a}hlt. In dieser Arbeit wurde jedoch gezeigt, dass nicht-quantitative Verfahren ein erhebliches Risiko zur Falschinterpretation beinhalten. Um Fehldiagnosen zu vermeiden, sollten deshalb prinzipiell quantitative Methoden zur Messung der durch die Sauerstoff-Verst{\"a}rkung bedingten T1-Verk{\"u}rzung in der Lunge verwendet werden. Herk{\"o}mmliche Techniken zur quantitativen T1-Messung ben{\"o}tigen allerdings l{\"a}ngere Messzeiten. Deshalb war zur Vermeidung von Bewegungsartefakten bisher die Datenaufnahme im Atemanhaltezustand notwendig. Wiederholtes Atemanhalten von mehreren Sekunden Dauer ist allerdings f{\"u}r einige Patienten sehr belastend. Aus diesem Grund wurden in dieser Arbeit zwei Methoden entwickelt, die eine quantitative Lungenfunktionspr{\"u}fung mittels MRT bei freier Atmung der Patienten erm{\"o}glichen. Eine gute Sauerstoffversorgung des Tumors wirkt sich positiv auf den Erfolg der Bestrahlung aus. Ein Ansatz zur Verbesserung der Strahlentherapie des Bronchialkarzinoms k{\"o}nnte daher in der Beatmung der Patienten mit hyperoxischen hypercapnischen Atemgasen w{\"a}hrend der Bestrahlung bestehen. In diesem Zusammenhang k{\"o}nnte die quantitative Messung der T1-Ver{\"a}nderung im Tumor nach Carbogenatmung ein Selektionskriterium darstellen, um diejenigen Patienten zu identifizieren, die von einer Carbogenbeatmung w{\"a}hrend der Bestrahlung profitieren k{\"o}nnen. Die Differenzierung zwischen vitalem Tumorgewebe, Nekrosen und atelektatischem Lungengewebe ist von großer Bedeutung bei der Bestrahlungsplanung des Bronchialkarzinoms. Einen neuen Ansatz bildet die in dieser Arbeit vorgestellte Magnetiserungstransfer-MRT. Um einen Magnetisierungstransfer zu erzeugen, wurde ein speziell auf die Bildgebung an der Lunge optimiertes Pr{\"a}parationsmodul entworfen. In Verbindung mit einer schnellen Bildakquisitionstechnik konnte die Magnetisierungstransfer-Lungenbildgebung in einem kurzen Atemstopp durchgef{\"u}hrt werden. Diese Technik wurde an mehreren Patienten mit Bronchialkarzinom evaluiert und die Ergebnisse mit denen der Fluor-Deoxyglykose-Positronen-Emissions-Tomographie (FDG-PET) verglichen. Es wurde festgestellt, dass mit diesem MRT-Verfahren {\"a}hnliche diagnostische Erkenntnisse erzielt werden k{\"o}nnen. Allerdings besitzt die MRT Vorteile im Hinblick auf r{\"a}umliche Aufl{\"o}sung, Messzeit, Bildqualit{\"a}t, Kosten und Strahlenbelastung. Das erhebliche Potential f{\"u}r die Bestrahlungsplanung des Bronchialkarzinoms durch eine Magnetisierungstransfer-Bildgebung wurde damit nachgewiesen.}, subject = {Magnetische Resonanz}, language = {de} }