Differences between males and females with spinal cord injury in the experience of subliminal and explicit sexual pictures.

STUDY DESIGN: Observational cross-sectional study. OBJECTIVES: To determine the differences between persons with spinal cord injury (SCI) and control individuals in terms of conscious and unconscious sexual responses to subliminally presented visual sexual stimuli. SETTING: Spinal cord injury rehabilitation center in northern Italy. METHODS: A two-part behavioral experiment was conducted on 40 participants (27 individuals with SCI; 13 controls). In first part, all participants were subliminally exposed to a prime picture (neutral or sexual) and asked to rate the extent to which they were emotionally aroused, while watching a set of explicit target pictures (neutral or sexual). In the second part, choice reaction time task was employed, wherein participants were shown a subliminal prime picture (neutral or sexual) followed by an explicit target picture (neutral or sexual) superimposed by a black dot and were asked to locate the dot as fast as possible. RESULTS: In the first part, men with SCI reported higher levels of emotional arousal to explicit sexual target pictures compared to other groups. In the second part, slower choice reaction times were found in the SCI group, particularly with sexual prime picture. Moreover, females with SCI spent more time during implicit motor learning tasks with sexual target pictures than other groups. CONCLUSION: We found differences in the experience of subliminal and explicit sexual pictures not only between the two groups, but also between females and males with SCI. Attention should thus be paid when considering sexual experience at subliminal and conscious level in SCI population for future research and rehabilitative protocols.

Experimental Protocol to Assess Neuromuscular Plasticity Induced by an Exoskeleton Training Session.

Exoskeleton gait rehabilitation is an emerging area of research, with potential applications in the elderly and in people with central nervous system lesions, e.g., stroke, traumatic brain/spinal cord injury. However, adaptability of such technologies to the user is still an unmet goal. Despite important technological advances, these robotic systems still lack the fine tuning necessary to adapt to the physiological modification of the user and are not yet capable of a proper human-machine interaction. Interfaces based on physiological signals, e.g., recorded by electroencephalography (EEG) and/or electromyography (EMG), could contribute to solving this technological challenge. This protocol aims to: (1) quantify neuro-muscular plasticity induced by a single training session with a robotic exoskeleton on post-stroke people and on a group of age and sex-matched controls; (2) test the feasibility of predicting lower limb motor trajectory from physiological signals for future use as control signal for the robot. An active exoskeleton that can be set in full mode (i.e., the robot fully replaces and drives the user motion), adaptive mode (i.e., assistance to the user can be tuned according to his/her needs), and free mode (i.e., the robot completely follows the user movements) will be used. Participants will undergo a preparation session, i.e., EMG sensors and EEG cap placement and inertial sensors attachment to measure, respectively, muscular and cortical activity, and motion. They will then be asked to walk in a 15 m corridor: (i) self-paced without the exoskeleton (pre-training session); (ii) wearing the exoskeleton and walking with the three modes of use; (iii) self-paced without the exoskeleton (post-training session). From this dataset, we will: (1) quantitatively estimate short-term neuroplasticity of brain connectivity in chronic stroke survivors after a single session of gait training; (2) compare muscle activation patterns during exoskeleton-gait between stroke survivors and age and sex-matched controls; and (3) perform a feasibility analysis on the use of physiological signals to decode gait intentions.

Developing an instrument for an early prediction model of long-term functional outcomes in people with acquired injuries of the central nervous system: protocol and methodological aspects.

Severe acquired brain injury (ABI) is a major cause of long-term disability and is the main determinant of health and societal costs. Early identification of favourable long-term recovery would allow personalized rehabilitative programs and better health care resources allocation. In light of the higher survival rate from intensive care units (ICU) in recent years, there is a growing need for early prognostication markers of functional recovery; to date, these data have been mainly collected at rehabilitation unit admission and not during the acute phase. We present the protocol and methodology to develop prediction models in people with severe acquired brain injury (GCS at admission to ICU < 8) for the functional and cognitive outcome at 12 months from the event. Predictors will be collected during the acute stage. Participants will be recruited within the first 72 h from the event in the ICUs of two teaching hospitals (Padova and Treviso). Participants will be followed up at discharge from ICU, admission and discharge from Neurorehabilitation and after 12 months from the event. Clinical and functional scales, electroencephalography, evoked potentials, magnetic resonance imaging and serological markers will be entered into a digital registry. Survival will be estimated using the Cox proportional hazard model. A multivariate prediction model will be developed for each of the functional and cognitive outcomes at 12 months from the event.

Age influences rehabilitative outcomes in patients with spinal cord injury (SCI).

BACKGROUND AND AIMS: To define differences in rehabilitative outcome after Spinal Cord Injury (SCI), according to age at injury. METHODS: This is a prospective, observational, follow-up study. Completion of a questionnaire administered by a psychologist through a telephone interview to subjects discharged about 4 years previously from 22 SCI centers in Italy, who had already participated in a prospective multicenter study. A total of 403 out of 511 patients with SCI (79%), discharged between 1997 and 1999 after comprehensive rehabilitation in SCI centers, who gave their consent to a telephone interview. Main outcome measures are: number of re-admissions and medical consultations for clinical problems during follow-up (FU) period, clinical outcome related to bowel/ bladder function, family, sentimental and personal satisfaction, mobility, three-day autonomy, subjective feelings of dependency, subjective perception of quality of life. RESULTS: The sample population was categorized into two subgroups according to severity on the Asia Spinal Injury Association (ASIA) scale by the ROC method: 276 subjects, the younger group were aged between 0 and 49 years, mean age 32 (±8 yrs), and 127 subjects in over 50 group, mean age 63 (±8 yrs). Differences in sample characteristics were found as regards cervical/dorsal lesion distribution and incompleteness of damage, more frequent in the older group. Incidence of hospital re-admissions and medical consultations, bladder autonomy, bowel autonomy and bowel continence were similar in both groups. Variables related to personal and social life, as well as life satisfaction, showed significant differences, with worse outcomes in the older group. CONCLUSIONS: Age at injury deserves major attention, as persons not yet in geriatric age may show greater vulnerability after SCI.

Walking performance, medical outcomes and patient training in FES of innervated muscles for ambulation by thoracic-level complete paraplegics.

OBJECTIVE: To discuss functional electric stimulation (FES) gait training of upper motoneuron spinal cord injured complete paraplegics considering ambulation performance, physiologic and metabolic responses as well as psychologic outcome, while providing myologic insight into ambulation via FES when training starts many years post-injury. METHODS: Transcutaneous FES using the Parastep stimulation system, gait training methods with and without major emphasis on muscle reinforcement, cardiovascular and respiratory conditioning. Examination of myofiber tissues and correlation of normal muscles histology versus innervated muscles of upper motor neuron and of denervated muscles of lower motor neuron paraplegics. RESULTS: Published works in literature reviewed in this paper report average walking distance of 440 m/walk when major muscle reinforcement and preconditioning cardiovascular and respiratory systems precedes gait training, versus average 115 m/walk when undergoing direct gait training. Medical, metabolic and psychologic outcomes, as reported in several works, point to benefits of FES walking, including 60% increase in blood flow to lower extremities. Myofiber tissues of patients with upper motor neuron paralysis compare well with those of normal tissue even many years post-injury, while adipose tissue substitute muscle fibers in patients with lower motor neuron lesions. DISCUSSION: Transcutaneous FES allows considerably longer walking distances and speed at the end of training when training involves an extensive pre-conditioning program than with direct gait training. Medical and psychologic benefits are observed, especially concerning blood flow to the lower extremities. Myofiber examinations provide myologic understanding of effectiveness of FES many years post-injury.