Abdominal functional electrical stimulation to improve respiratory function after spinal cord injury: a systematic review and meta-analysis.

This corrects the article DOI: 10.1038/sc.2016.31.

Abdominal functional electrical stimulation to improve respiratory function after spinal cord injury: a systematic review and meta-analysis.

OBJECTIVES: Abdominal functional electrical stimulation (abdominal FES) is the application of a train of electrical pulses to the abdominal muscles, causing them to contract. Abdominal FES has been used as a neuroprosthesis to acutely augment respiratory function and as a rehabilitation tool to achieve a chronic increase in respiratory function after abdominal FES training, primarily focusing on patients with spinal cord injury (SCI). This study aimed to review the evidence surrounding the use of abdominal FES to improve respiratory function in both an acute and chronic manner after SCI. SETTINGS: A systematic search was performed on PubMed, with studies included if they applied abdominal FES to improve respiratory function in patients with SCI. METHODS: Fourteen studies met the inclusion criteria (10 acute and 4 chronic). Low participant numbers and heterogeneity across studies reduced the power of the meta-analysis. Despite this, abdominal FES was found to cause a significant acute improvement in cough peak flow, whereas forced exhaled volume in 1 s approached significance. A significant chronic increase in unassisted vital capacity, forced vital capacity and peak expiratory flow was found after abdominal FES training compared with baseline. CONCLUSIONS: This systematic review suggests that abdominal FES is an effective technique for improving respiratory function in both an acute and chronic manner after SCI. However, further randomised controlled trials, with larger participant numbers and standardised protocols, are needed to fully establish the clinical efficacy of this technique.

Changing demographics of spinal cord injury over a 20-year period: a longitudinal population-based study in Scotland.

STUDY DESIGN: A retrospective cohort study. OBJECTIVES: To review demographic trends in traumatic spinal cord injury (TSCI) and non-traumatic spinal cord injury (NTSCI). SETTING: The Queen Elizabeth National Spinal Injuries Unit (QENSIU), sole provider of treatment for TSCI in Scotland; a devolved region of the UK National Health Service. METHODS: A retrospective review of the QENSIU database was performed between 1994 and 2013. This database includes demographic and clinical data from all new TSCI patients in Scotland, as well as patients with severe NTSCI. RESULTS: Over this 20-year period there were 1638 new cases of TSCI in Scotland; 75.2% occurring in males. TSCI incidence increased non-significantly (13.3 per million population to 17.0), while there were significant increases in mean age at time of TSCI (44.1-52.6 years), the proportion of TSCIs caused by falls (41-60%), the proportion of TSCIs resulting in an American Spinal Injury Association Impairment Scale score of C and D on admission (19.7-28.6% and 34.5-39.5%, respectively) and the proportion of cervical TSCIs (58.4-66.3%). The increase in cervical TSCI was specifically due to an increase in C1-C4 lesions (21.7-31.2%). NTSCI patients (n=292) were 5 years older at injury, more likely to be female (68.1% male) and had a range of diagnoses. CONCLUSION: This study supports the suggestion that demographic profiles in SCI are subject to change. In this population, of particular concern is the increasing number of older patients and those with high level tetraplegia, due to their increased care needs. Prevention programmes, treatment pathways and service provision need to be adjusted for optimum impact, improved outcome and long-term care for their target population.

Detection of the motor points of the abdominal muscles.

PURPOSE: Abdominal functional electrical stimulation (AFES) is a technique intended to improve respiratory function in tetraplegia where breathing is affected due to abdominal muscle paralysis. Although it is known that optimal muscle contraction is achieved when electrical stimulation is applied close to the muscle motor point, AFES studies have used a variety of electrode positions. This study aims to investigate the feasibility of using Neuromuscular Electrical Stimulation to detect the motor points of the abdominal muscles, and to evaluate the intrasubject repeatability and intersubject uniformity of their positions, to find the most suitable AFES electrode location. METHODS: Low frequency stimulation (0.5 Hz) was applied to the abdominal muscles of 10 able bodied and five tetraplegic participants. The electrode positions which achieved the strongest muscle contractions were recorded as the motor point positions, with measurements repeated once. For five able bodied participants, assessments were repeated after 18 months, in seated and supine positions. RESULTS: Intersubject uniformity ranged from 2.8 to 8.8%. Motor point positions were identified with intrasubject repeatability of <1.7 cm, deemed adequate relative to standard AFES electrode size. Intrasubject repeatability shows motor point positions changed little (<1.7 cm) after 18 months but varied between seated and supine positions with repeatability of up to 3.1 cm. CONCLUSIONS: A simple technique to locate the motor points of the abdominal muscles is presented and shown to have an adequate intrasubject repeatability, enabling the optimum AFES electrode location to be identified for each user.

Spinal cord injury as a result of Staphylococcus aureus pyogenic spinal infection complicating infected atopic eczema: two case reports.

INTRODUCTION: Pyogenic spinal infections (PSI) are a rare cause of spinal cord injury (SCI). These most often affect the lumbar spine, followed by the thoracic spine and least commonly the cervical spine, with Staphylococcus aureus being the most common causative organism. Atopic eczema is a dermatological condition which can lead to a breakdown of the skin's natural barrier function, allowing bacterial colonisation and infection. Haematological seeding of bacteria from a distant source of infection, including the skin and soft tissues, is a recognised aetiology of PSI. CASE PRESENTATION: We present two patients who sustained a SCI as a result of PSI secondary to infected atopic eczema. Methicillin-sensitive Staphylococcus aureus (MSSA) was identified as the causative organism in both patients. The two patients required prolonged courses of intravenous followed by oral antibiotics. Neurological outcomes varied between the two patients. One patient had incomplete tetraplegia (C3 AIS C), and upon discharge required hoisting from their bed to a power chair, had an indwelling urethral catheter and required bowel care. The other patient had incomplete paraplegia (L3 AIS D), and at discharge was independent with activities of daily living and was mobile with two elbow crutches. DISCUSSION: We believe that the two cases presented here represent the only examples of secondarily infected atopic eczema causing PSI and resultant SCI in the published literature. As SCI is a serious and potentially life-altering complication, medical professionals treating patients with atopic eczema should be aware of this risk.

Differential activation of the human costal and crural diaphragm during voluntary and involuntary breaths.

The diaphragm is the primary muscle that generates the negative intrathoracic pressure to drive inspiratory airflow. The diaphragm consists of two parts, the costal and crural portions, with different roles during inspiration in animals, particularly when the stimulus to breathe is increased. In this study, the neural drive to the costal and crural portions of the diaphragm was assessed in nine healthy participants [8 male, aged 32 ± 13 yr (mean ± SD)]. Inspiratory electromyographic activity (EMG) was recorded from the costal diaphragm by using an intramuscular electrode and from the crural diaphragm with a multipair gastroesophageal catheter. Participants performed voluntary augmented breaths at 120%, 140%, and 160% of their tidal volume and also underwent progressive hypercapnia to induce involuntary breathing. Irrespective of the task, the increase in crural activity (normalized to quiet breathing) was only ~60% of the increase in costal activity (slope: 0.56 ± 0.30, P < 0.001). The onset and peak timing of EMG activity was similar for the costal and crural diaphragm during quiet breathing. Thus, when stimulated by either a voluntary or involuntary drive to breathe above tidal volume, the neural drive to the diaphragm was greater to the costal than to the crural portion.NEW & NOTEWORTHY Simultaneous electromyographic recordings from the human costal and crural diaphragm during voluntary augmented breathing and involuntary rebreathing show that the increase in inspiratory crural diaphragm activity was ~60% of the increase in costal diaphragm activity. However costal to crural diaphragm activation did not differ between the two tasks. The dissociation in the amplitude of activation of the costal and crural diaphragm becomes apparent only as the drive to breathe increases above tidal breathing.

Abdominal Functional Electrical Stimulation to Augment Respiratory Function in Spinal Cord Injury.

Background: Functional electrical stimulation (FES) is the application of electrical pulses to a nerve to achieve a functional muscle contraction. Surface electrical stimulation of the nerves that innervate the abdominal muscles, termed abdominal FES, can cause the abdominal muscles to contract, even when paralysed after spinal cord injury. As the abdominal muscles are the major expiratory muscles, and commonly partially or completely paralysed in tetraplegia, abdominal FES offers a promising method of improving respiratory function for this patient group. Objective: The aim of the article is to provide readers with a better understanding of how abdominal FES can be used to improve the health of the spinal cord-injured population. Methods: A narrative review of the abdominal FES literature was performed. Results: Abdominal FES can achieve an immediate effective cough in patients with tetraplegia, while the repeated application over 6 weeks of abdominal FES can improve unassisted respiratory function. Ventilator duration and tracheostomy cannulation time can also be reduced with repeated abdominal FES. Conclusion: Abdominal FES is a noninvasive method to achieve functional improvements in cough and respiratory function in acute and chronically injured people with tetraplegia. Potential practical outcomes of this include reduced ventilation duration, assisted tracheostomy decannulation, and a reduction in respiratory complications. All of these outcomes can contribute to reduced morbidity and mortality, improved quality of life, and significant potential cost savings for local health care providers.

Non-intrusive real-time breathing pattern detection and classification for automatic abdominal functional electrical stimulation.

Abdominal Functional Electrical Stimulation (AFES) has been shown to improve the respiratory function of people with tetraplegia. The effectiveness of AFES can be enhanced by using different stimulation parameters for quiet breathing and coughing. The signal from a spirometer, coupled with a facemask, has previously been used to differentiate between these breath types. In this study, the suitability of less intrusive sensors was investigated with able-bodied volunteers. Signals from two respiratory effort belts, positioned around the chest and the abdomen, were used with a Support Vector Machine (SVM) algorithm, trained on a participant by participant basis, to classify, in real-time, respiratory activity as either quiet breathing or coughing. This was compared with the classification accuracy achieved using a spirometer signal and an SVM. The signal from the belt positioned around the chest provided an acceptable classification performance compared to the signal from a spirometer (mean cough (c) and quiet breath (q) sensitivity (Se) of Se(c)=92.9% and Se(q)=96.1% vs. Se(c)=90.7% and Se(q)=98.9%). The abdominal belt and a combination of both belt signals resulted in lower classification accuracy. We suggest that this novel SVM classification algorithm, combined with a respiratory effort belt, could be incorporated into an automatic AFES device, designed to improve the respiratory function of the tetraplegic population.