Publications by authors named "Sebastian Klug"
Bulk high-temperature superconductors (HTSs) such as BaCuO (BCO, = Y, Gd) are commonly used in rotationally symmetric superconducting magnetic bearings. However, such bulks have several disadvantages such as brittleness, limited availability and high costs due to the time-consuming and energy-intensive fabrication process. Alternatively, tape stacks of HTS-coated conductors might be used for these devices promising an improved bearing efficiency due to a simplification of manufacturing processes for the required shapes, higher mechanical strength, improved thermal performance, higher availability and therefore potentially reduced costs.
View Article and Find Full Text PDFSerotonin (5-HT) plays an essential role in reward processing, however, the possibilities to investigate 5-HT action in humans during emotional stimulation are particularly limited. Here we demonstrate the feasibility of assessing reward-specific dynamics in 5-HT synthesis using functional PET (fPET), combining its molecular specificity with the high temporal resolution of blood oxygen level dependent (BOLD) fMRI. Sixteen healthy volunteers underwent simultaneous fPET/fMRI with the radioligand [C]AMT, a substrate for tryptophan hydroxylase.
View Article and Find Full Text PDFPurpose: The human brain is characterized by interacting large-scale functional networks fueled by glucose metabolism. Since former studies could not sufficiently clarify how these functional connections shape glucose metabolism, we aimed to provide a neurophysiologically-based approach.
Methods: 51 healthy volunteers underwent simultaneous PET/MRI to obtain BOLD functional connectivity and [F]FDG glucose metabolism.
Article Synopsis
- Functional PET (fPET) is a new technique for examining brain metabolism and neurotransmitter activity, typically requiring invasive blood sampling to measure arterial input function (AIF).
- This study developed a non-invasive method using cardiac IDIF from twenty healthy individuals, validating its accuracy against traditional methods through blood sampling while participants engaged in a monetary incentive delay task.
- Results showed a strong correlation between the new IDIF method and AIF, demonstrating that this non-invasive approach provides reliable quantification of brain activity changes, making fPET more accessible in clinical settings.
Article Synopsis
- - The study presents a new functional positron emission tomography (fPET) method that quantifies glucose metabolism changes without requiring invasive arterial blood sampling, which can limit the technique's use.
- - Two datasets were used to validate this method, involving participants performing different tasks while undergoing fPET scans, with strong correlations found between task-specific metabolic changes and traditional measurements.
- - The new non-invasive approach shows reliable estimates of glucose metabolism changes and enhances the usability of fPET in research and clinical environments but sacrifices the ability to measure baseline metabolism.
Purpose: Positron emission tomography (PET) provides precise molecular information on physiological processes, but its low temporal resolution is a major obstacle. Consequently, we characterized the metabolic response of the human brain to working memory performance using an optimized functional PET (fPET) framework at a temporal resolution of 3 s.
Methods: Thirty-five healthy volunteers underwent fPET with [F]FDG bolus plus constant infusion, 19 of those at a hybrid PET/MRI scanner.
Exercise capacity of an individual describes the ability to perform physical activity. This exercise capacity is influenced by intrinsic factors such as genetic constitution and extrinsic factors such as exercise training. On the metabolic level exercise and metabolism are linked.
View Article and Find Full Text PDFArticle Synopsis
- The default mode network (DMN) in our brain shows different activity levels depending on the tasks we are doing.
- When we focus on external activities, like playing Tetris, the brain uses less energy in certain areas, but when we think hard or use our memory, it can use more energy.
- This study found that different brain networks affect how the DMN works, showing it is more complex than just being “off” during tasks and can change based on what we need to focus on.
The nervous and circulatory system interconnects the various organs of the human body, building hierarchically organized subsystems, enabling fine-tuned, metabolically expensive brain-body and inter-organ crosstalk to appropriately adapt to internal and external demands. A deviation or failure in the function of a single organ or subsystem could trigger unforeseen biases or dysfunctions of the entire network, leading to maladaptive physiological or psychological responses. Therefore, quantifying these networks in healthy individuals and patients may help further our understanding of complex disorders involving body-brain crosstalk.
View Article and Find Full Text PDFArticle Synopsis
- The study looks at how our brains change when we learn new things, like solving visual problems, and how different parts of the brain work together during this process.
- Researchers used special brain scans to see what happens in the brain before and after a month of learning.
- They found that learning changes how the brain's networks communicate, helping us do better at tasks, and that our brain uses energy differently when we're just resting versus when we're focused on a task.
Mapping the neuronal response during cognitive processing is of crucial importance to gain new insights into human brain function. BOLD imaging and ASL are established MRI methods in this endeavor. Recently, the novel approach of functional PET (fPET) was introduced, enabling absolute quantification of glucose metabolism at rest and during task execution in a single measurement.
View Article and Find Full Text PDFHow deep can straight instruments be inserted into the femoral canal: a simulation study based on cadaveric femora.
Comput Assist Surg (Abingdon)
December 2016
Determining how deep instruments can be inserted into the femoral canal without touching adjacent structures is a fundamental necessity for navigating instruments in primary and revision total hip arthroplasty. The aim of the study was to determine the reachable depth of a straight instrument inserted into the femur canal during primary and revision total hip arthroplasty. Based on the three-dimensional data of twenty-six femurs, obtained from a CT scan, the insertion depth of a virtual, straight instrument was accessed by a simulation.
View Article and Find Full Text PDFBackground: All surgical procedures in orthopedics involve the retraction of soft tissue. In this study, the performance of 3 assistants holding the medial retractor during minimally invasive hip arthroplasty was compared with a semiactive retractor holder in a cadaver setup.
Methods: A total of 40 measurements on 3 cadavers were carried out with each subject (3 human, 1 robot) measuring each cadaver 10 times.
Assessment of the Size of the Surgical Site in Minimally Invasive Hip Surgery.
Adv Wound Care (New Rochelle)
June 2014
Minimally invasive approaches to the hip are beneficial to the patient, but reduce the space available for manipulation by the surgeon. Determining the available working space is important for the development of surgical instruments, to track movements during surgery, as well as to classify the invasiveness of the procedure. We evaluate three measurement methods to assess the volume of eight surgical sites in a cadaver study.
View Article and Find Full Text PDFBackground: Time-of-flight (TOF) cameras can guide surgical robots or provide soft tissue information for augmented reality in the medical field. In this study, a method to automatically track the soft tissue envelope of a minimally invasive hip approach in a cadaver study is described.
Methods: An algorithm for the TOF camera was developed and 30 measurements on 8 surgical situs (direct anterior approach) were carried out.