The human movement is a behavior from the cooperation between central and peripheral nervous system. Previous studies confirmed the coherence between the cerebral cortex and the peripheral nervous system of upper limb by measuring the muscle signals form active or pathological muscle contraction, terming corticomuscular coherence. In addition, the specific motor cortical area would modulate the different muscle synergies, and be involved in distinct brain functional network. However, few studies focused on the relationship between the brain functional networks and peripheral nervous system. This study aimed to explore the functional coupling between the central nervous system and the peripheral nervous system of upper limb. Thirty-seven healthy subjects participated in the functional magnetic resonance imaging (fMRI) experiments. We established the imaging platform to collect the echo planar imaging (EPI) signals under the experimental design of task-based and task-free fMRI from human brain and upper limb simultaneously. All data were acquired using three coils: one 20-channels head coil, one 32-channels spine coil, and one 18-channels flexible surface coil. In the task-based sessions, the participants were instructed to execute or image hand movement; in the task-free fMRI scanning, participants were asked to open their eyes and do not think systematically. Generalized linear modeling, seed-based functional connectivity, regional pairwise correlation coefficient (RPCC) and independent component analysis were used for the functional data analyzing. Our result demonstrated that the peripheral nervous system of upper limb and the motor-related cerebral areas, including of precentral gyrus and supplementary motor area, had significant activation in the task-based fMRI. Seeding at the peripheral activation during motor tasks, the functional connectivity was identified in several brain regions, included the left dorsolateral prefrontal cortex, precentral gyrus, left inferior parietal gyrus, anterior cingulate cortex, and cerebellar lobules. The peripheral nervous system of upper limb showed that the most-linked hub-regions in middle temporal gyrus, fusiform gyrus, insula, parahippocampal gyrus, cingulate cortex, amygdala, cerebellar lobule Crus I, and cerebellar lobule VII. In the result analyzed by ICA, the peripheral nervous system of upper limb would involve in the brain functional network, including motor, sensorimotor, executive control network, default mode network, thalamus, cerebellum, and somatosensory network. We established a novel imaging-platform to collect the functional images from human brain and upper limb simultaneously. This study disclosed the functional coupling between the peripheral nervous system of upper limb and the brain cortex and demonstrated that peripheral nervous system also involved in the regulation of brain cognitive function and related network changes. We expect that it could be applied furthering investigation of central-peripheral communication and could be used in the clinical diagnosis.