Andoh JA, Flor H. DFG - Deutsche Forschungsgemeinschaft SFB 1158: B 07 - Neural circuits involved in Phantom Limb Pain . 07/2019-06/2023.
Although there has been much progress in the understanding of phantom limb pain (PLP), we still do not know which factors are antecedents and which are consequences of the pain and how central, peripheral and psychological factors interact. This project seeks to determine the development of phantom limb pain in a longitudinal fashion and will examine how central and peripheral changes as well as psychological factors develop over time. In addition, the role of central nervous system excitability and plasticity and the influence of use-dependent plasticity and body perception will be examined. Further, we will examine how evoked phantom pain is represented in the brain. Finally, we will employ high field imaging, neurofeedback using real time functional magnetic resonance imaging (fMRI) and transcranial magnetic stimulation (TMS) to identify causal circuits for phantom pain.
DFG - Deutsche Forschungsgemeinschaft SFB 1158: B 07 - Neural circuits involved in Phantom Limb Pain . 07/2015-06/2019.
EFIC-Grünenthal-Grant (EGG): Circuits of pain memory in chronic pain patients. 01/2015-12/2016.
Flor H. EU - Europäische Union 230249: ERC PHANTOMMIND: Phantom phenomena: A window to the mind and the brain. 01/2009-12/2014.
Phantom experiences occur in almost all amputees but are among the least understood sensory phenomena. Recently changes in the representation of body maps in the brain were found to be related to phantom pain and it has also been demonstrated that there are great similarities between non-painful phantoms and bodily illusions such as the rubber hand illusion. This research has also shown that the brain does not process the physical but the perceived reality, which opens the door to manipulations of the perceived reality in basic research and the treatment of phantom pain. Behavioural intervention methods such as prosthesis, sensory discrimination or mirror training influence phantom limb pain and alter brain function. Thus, phantom phenomena are an excellent tool to study the neural basis of somatosensory and specifically bodily perception and this can lead to new treatment methods such as brain-computer interfaces or virtual reality applications for phantom pain and similar pain states. The aim of this project is (1) an exact assessment and analysis of the interrelationship of various phantom phenomena such as phantom limb awareness, painful phantom sensation, telescoping, prosthesis use and proneness to bodily illusions or plasticity of body image in a large sample of amputees, (2) the analysis of the neural correlates of these phenomena in small subgroups of amputees using functional magnetic resonance imaging as well as transcranial magnetic stimulation, (3) the analysis of determinants and neural correlates of bodily illusions in healthy controls to identify potential common neural mechanisms and (4) use of prosthesis and virtual reality training early after amputation in order to understand how manipulations of the body image and sensory feedback alter the development and the brain correlates of phantoms.