Successful management of pulmonary edema secondary to accidental electrocution in a young dog.

BACKGROUND: Human records describe pulmonary edema as a life-threatening complication of electric shock. Successful management requires prompt recognition and intensive care. However, in companion animals, electrocutions are rarely reported, even though domestic environments are full of electrical devices and there is always the possibility of accidental injury. Therefore, it is important for veterinarians to know more about this condition in order to achieve successful patient outcomes. CASE PRESENTATION: A 3-month-old male Labrador Retriever was presented with a history of transient loss of consciousness after chewing on a household electrical cord. On admission, the puppy showed an orthopneic position with moderate respiratory distress. Supplemental oxygen via nasal catheter was provided, but the patient showed marked worsening of respiratory status. Point-of-care ultrasound exams suggested neurogenic pulmonary edema due to electrical shock close to the central nervous system and increased B-lines without evidence of cardiac abnormalities. Mechanical ventilation of the patient was initiated using volume-controlled mode with a tidal volume of 9 to 15 ml/kg until reaching an end-tidal carbon dioxide ≤ 40 mm Hg, followed by a stepwise lung-recruitment maneuver in pressure-controlled mode with increases of the peak inspiratory pressure (15 to 20 cm H2O) and positive end-expiratory pressure (3 to 10 cm H2O) for 30 min, and return to volume-controlled mode with a tidal volume of 15 ml/kg until reaching a peripheral oxygen saturation ≥ 96%. Weaning from the ventilator was achieved in six hours, and the patient was discharged two days after admission without neurological or respiratory deficits. CONCLUSIONS: We present a rather unusual case of a neurogenic pulmonary edema subsequent to accidental electrocution in a dog. Timely diagnosis by ultrasound and mechanical ventilation settings are described. Our case highlights that pulmonary edema should be considered a potentially life-threatening complication of electrical shock in small animal emergency and critical care medicine.

[Electrical Accidents]. / Stromunfälle.

Electrical Accidents Abstract: When persons seek medical help after an electrical injury, physicians have to inquire on the type (AC/DC) and strength of current (>1000V is considered "high voltage") as well as the exact circumstances (loss of consciousness, falls) of the accident. In the advent of high-voltage accidents, loss of consciousness, arrhythmias, abnormal ECG or elevated troponin levels, in-hospital rhythm monitoring is warranted. In all other cases, the type of extra cardiac injury primarily directs the management. Superficial skin marks may disguise more extensive thermal injuries of inner organs.

Pediatric electrical injuries in the emergency department: an evidence-based review.

Electrical injuries in pediatric patients are uncommon but can be life-threatening and require efficient and effective identification and management. Injury severity is based on the characteristics of the electricity, the duration of contact with the electrical source, and the current's pathway through the body. This issue discusses the specific threats posed by high-voltage, low-voltage, and lightning injuries. The various presentations are described, including burns, arrhythmias, respiratory arrest, cardiac arrest, blunt trauma from falls or blast events, rhabdomyolysis, tympanic membrane rupture, and altered mental status, among others. The most current literature is reviewed, and an evidence-based approach is provided for the diagnosis and management of electrical injuries in pediatric patients presenting to the emergency department.

Multiple Beneficial Effects of High-dose BoNT-A Injection to Improve Wound Healing and Spasticity in a Patient With Hypoxic Encephalopathy Due to High-voltage Electrical Injury.

INTRODUCTION: High-voltage electrical injuries remain a difficult challenge for physicians. The survivors often have complicated wounds over the trunk or extremities, and some of them may develop hypoxic encephalopathy. The emergence of spasticity following hypoxic encephalopathy may further interfere with the healing of wounds. CASE REPORT: The authors report the case of a 17-year-old male with strong spasticity of finger flexors graded 4 by the Modified Ashworth Scale (0-5) after electric shock. He also had a nonhealing wound on the flexor side of the left index finger after 6 weeks of standard wound care. The wound measured 0.3 cm × 0.3 cm × 0.2 cm in size. The authors hypothesized that wound healing was negatively affected by spasticity and expected the wound might heal gradually after reducing the strong spasticity of the index finger. The authors employed electrical stimulator for guidance and injected high-dose (50 units/muscle) botulinum toxin type A into the flexor digitorum superficialis and the flexor digitorum profundus of his left index finger. At 7 days following administration, focal spasticity of these muscles in the left index finger decreased from 4 to 1 on the Modified Ashworth Scale. At 21 days post administration, the wound healed completely. CONCLUSIONS: For patients with hypoxic encephalopathy due to high-voltage electrical injury, botulinum toxin type A injection may be an option of therapeutic approach for both reduction of spasticity and facilitation of wound healing.

Veno-arterial extracorporeal membrane oxygenation for electrical injury induced cardiogenic shock support: a case report.

BACKGROUND: High voltage electrical injury (HVEI) of more than 1000 V is a potentially devastating form of a multisystem injury associated with high morbidity and mortality. We present the first case of veno-arterial extracorporeal membrane oxygenation (VA-ECMO) as a life saving device for treating a patient with severe cardiogenic shock after a high voltage electrical injury. CASE PRESENTATION: A 26-year-old male sustained HVEI while working with a concrete mixer pump that came in contact with a high voltage cable of 10,000 V. He was immediately disconnected from the mixer pump, underwent cardiopulmonary resuscitation and was transported to the nearest medical centre with severe cardiogenic shock with an ejection fraction (EF) of < 10%. Upon arrival, he was in critical condition, sedated and mechanically ventilated, haemodynamically unstable and supported by intravenous (IV) inotropes after a few events of ventricular fibrillation, with an electrical entry point on the left hand and an exit point located on his right leg. Blood pH was 6.8, PCO2 53 mmHg, PaO2 of 57 mmHg, lactate 8 mmol/L, and Troponin 38,000 ng/dl. The EF was 10% with global severe left ventricular dysfunction. During cardiopulmonary resuscitation (CPR), including cardiac massage and few electrical shocks, he was immediately connected to the VA-ECMO via open right femoral approach with distal arterial leg perfusion. He was treated with IV broad spectrum antibiotics, and high volume fluids to prevent rhabdomyolysis-induced acute kidney injury, total parenteral nutrition, topical silver sulfadiazine cream, and Granuflex for severe electrical burns. He was gradually weaned from inotropes over the next 3 days, during which his clinical condition and bloodwork improved tremendously. His EF gradually increased to 50% and he was weaned from the VA-ECMO, and underwent decannulation 86 h after initialization. He was discharged on day 27 without any sequelae. CONCLUSION: The VA-ECMO treatment can be a lifesaving device for treating severe cardiogenic shock caused by high voltage electrical injury, and should be considered while treating these "high-mortality risk" patients.

Retrospective study of prognosis and relating factors of cardiac complications associated with electrical injuries at a single centre in Korea.

OBJECTIVES: To date, no research has investigated the association between cardiac complication and electrical injury; hence, we aimed to assess the consequences and relating factors of cardiac complications from electrical injuries in South Korea. DESIGN: Retrospective single-centre study. PARTICIPANTS: 721 patients who had electrical injury-related admission during 2007-2017. An electronic medical record system was used to extract records of patients admitted for electrical injury treatment. RESULTS: Cardiac complications included abnormal parameters of myocardial damage, abnormal regional wall motion detected via echocardiogram, dysrhythmia (eg, bradycardia, atrial flutter/fibrillation) and ventricular tachycardia or fibrillation. Overall, 107 patients (14.8%) experienced cardiac complications. The average admission duration and intensive care unit stay duration were significantly longer in patients with cardiac complications than in those without them (75.0±45.3 vs 56.6±48.0 days and 19.3±24.1 vs 10.4±15.5 days, respectively, p<0.01 for both). Of the total cardiac cases, 72.9% had Troponin I elevation, 3.7% had regional wall motion abnormality, and 5.6% had atrial flutter/fibrillation. Overall, seven patients from the cardiac complication group and three patients from the control group died (p=0.01). All deaths occurred within 32 days, and the most common cause of death was septic shock. Total body surface area (TBSA) was only positively related factor to cardiac complications. CONCLUSION: This study is the first in South Korea to reveal that electrical accident patients with cardiac complications experience poorer in-hospital prognosis, and TBSA was the only risk factor of cardiac complications. And initial treatment for infection and inflammations could be important in electrical injury.

GDNF-ADSCs-APG embedding enhances sciatic nerve regeneration after electrical injury in a rat model.

The pluripotency of adipose-derived stem cells (ADSCs) makes them appropriate for tissue repair and wound healing. Owing to the repair properties of autologous platelet-rich gel (APG), which is based on easily accessible blood platelets, its clinical use has been increasingly recognized by physicians. The aim of this study was to investigate the effect of combined treatment with ADSCs and APG on sciatic nerve regeneration after electrical injury. To facilitate the differentiation of ADSCs, glial cell line-derived neurotrophic factor (GDNF) was overexpressed in ADSCs by lentivirus transfection. GDNF-ADSCs were mingled with APG gradient concentrations, and in vitro, cell proliferation and differentiation were examined with 5-ethynyl-2'-deoxyuridine staining and immunofluorescence. A rat model was established by exposing the sciatic nerve to an electrical current of 220 V for 3 seconds. Rat hind-limb motor function and sciatic nerve regeneration were subsequently evaluated. Rat ADSCs were characterized by high expression of CD90 and CD105, with scant expression of CD34 and CD45. We found that GDNF protein expression in ADSCs was elevated after Lenti-GDNF transfection. In GDNF-ADSCs-APG cultures, GDNF was increasingly produced while tissue growth factor-ß was reduced as incubation time was increased. ADSC proliferation was augmented and neuronal nuclei (NeuN) and glial fibrillary acidic protein (GFAP) expression were upregulated in GDNF-ADSCs-APG. In addition, limb motor function and nerve axon growth were improved after GDNF-ADSCs-APG treatment. In conclusion, our study demonstrates the combined effect of ADSCs and APG in peripheral nerve regeneration and may lead to treatments that benefit patients with electrical injuries.

Acute and long-term clinical, neuropsychological and return-to-work sequelae following electrical injury: a retrospective cohort study.

OBJECTIVE: To determine acute and long-term clinical, neuropsychological, and return-to-work (RTW) effects of electrical injuries (EIs). This study aims to further contrast sequelae between low-voltage and high-voltage injuries (LVIs and HVIs). We hypothesise that all EIs will result in substantial adverse effects during both phases of management, with HVIs contributing to greater rates of sequelae. DESIGN: Retrospective cohort study evaluating EI admissions between 1998 and 2015. SETTING: Provincial burn centre and rehabilitation hospital specialising in EI management. PARTICIPANTS: All EI admissions were reviewed for acute clinical outcomes (n=207). For long-term outcomes, rehabilitation patients, who were referred from the burn centre (n=63) or other burn units across the province (n=65), were screened for inclusion. Six patients were excluded due to pre-existing psychiatric conditions. This cohort (n=122) was assessed for long-term outcomes. Median time to first and last follow-up were 201 (68-766) and 980 (391-1409) days, respectively. OUTCOME MEASURES: Acute and long-term clinical, neuropsychological and RTW sequelae. RESULTS: Acute clinical complications included infections (14%) and amputations (13%). HVIs resulted in greater rates of these complications, including compartment syndrome (16% vs 4%, p=0.007) and rhabdomyolysis (12% vs 0%, p<0.001). Rates of acute neuropsychological sequelae were similar between voltage groups. Long-term outcomes were dominated by insomnia (68%), anxiety (62%), post-traumatic stress disorder (33%) and major depressive disorder (25%). Sleep difficulties (67%) were common following HVIs, while the LVI group most frequently experienced sleep difficulties (70%) and anxiety (70%). Ninety work-related EIs were available for RTW analysis. Sixty-one per cent returned to their preinjury employment and 19% were unable to return to any form of work. RTW rates were similar when compared between voltage groups. CONCLUSIONS: This is the first investigation to determine acute and long-term patient outcomes post-EI as a continuum. Findings highlight substantial rates of neuropsychological and social sequelae, regardless of voltage. Specialised and individualised early interventions, including screening for mental health concerns, are imperative to improvingoutcomes of EI patients.

Protocols for documentation of electrical injuries for electrical safety inspectors and emergency medical practitioners.

BACKGROUND: Electric shocks are common, and victims report difficulty in finding practitioners with knowledge of the injury. Medical Practitioners, especially in private practice, report lack of knowledge of the injury and lack of expertise in assessing and treating the injury. The authors are often requested to suggest investigation protocols, assessment protocols, and treatment protocols, and to provide educational information. METHODS: The international body establishing electrical standards on the effects of current on the body (International Electrotechnical Commission, Maintenance Team 4 (MT4) of Technical Committee 64 (TC64)) have established protocols for the factors which require documentation and reporting of the injury. This article provides a narrative approach to using these protocols in accord with the standards (IEC 60479). The level of evidence is Level III (US/Canada classification). TYPE: This article collects together and collates physical and medical aspects of investigating electric shocks, and summarizes those of importance, and which are potentially forgotten. The thoroughness of initial assessment is emphasized. SUBSTANCE: Summaries are set out to guide first attenders and emergency medical personnel as to findings and observations which must be recorded for later comprehensive medicolegal reporting and which are often overlooked. CONCLUSION: Wider teaching in the nature of electric shocks will enhance assessment of victims and thorough recording of pertinent information and thus will enhance later medicolegal reporting. Many such factors are initially overlooked and lead to inadequate reporting for forensic purposes.

Points & Pearls: Electrical injuries in the emergency department: an evidence-based review

Electrical injuries can be caused by exposure to current from low-voltage and high-voltage sources as well as lightning strikes, and the circumstances of the exposure will dictate management strategies. Human tissues have varying resistance characteristics and susceptibility to damage, so injuries may be thermal, electrical, and/or mechanical, potentially causing burns, thrombosis, tetany, falls, and blast injury. This issue reviews the types of trauma seen with electrical injury and how body systems can be affected by occult or delayed effects, and the optimal evidence-based resuscitation and management strategies associated with each. [Points & Pearls is a digest of Emergency Medicine Practice.]

Electrical injuries in the emergency department: an evidence-based review.

Electrical injuries can be caused by exposure to current from low-voltage and high-voltage sources as well as lightning strikes, and the circumstances of the exposure will dictate management strategies. Human tissues have varying resistance characteristics and susceptibility to damage, so injuries may be thermal, electrical, and/or mechanical, potentially causing burns, thrombosis, tetany, falls, and blast injury. This issue reviews the types of trauma seen with electrical injury and how body systems can be affected by occult or delayed effects, and the optimal evidence-based resuscitation and management strategies associated with each.

Continuous Veno-Venous Hemofiltration During Intercontinental Aeromedical Evacuation.

Overseas contingency operations which occur in areas lacking medical infrastructure pose challenges to the stabilization and transportation of critically ill patients. In particular, metabolic derangements resulting from acute kidney injury (AKI) make long-distance aeromedical evacuation risky. Here, we report the first modern use of in-flight continuous veno-venous hemofiltration (CVVH) for intercontinental aeromedical evacuation. Hospital and transport records were reviewed for a 31-yr-old male active duty service member who sustained 40% total body surface area full thickness burns after high-voltage electrical exposure in the southern Philippines. He was evacuated to the Burns Centre at Singapore General Hospital, where CVVH was initiated for anuric AKI secondary to rhabdomyolysis. The United States Army Institute of Surgical Research (USAISR) Burn Flight Team transported the patient to the USAISR Burn Center at Fort Sam Houston, TX, USA. CVVH was performed in-flight for 15 h out of 19.5 h of total flight time. CVVH settings were maintained as follows: blood flow 250 mL/min; replacement fluid rate 3,500 mL/h; and no ultra-filtrate removal. Unfractionated heparin at 500 units/h was utilized for regional anticoagulation. No filter clotting was encountered; a planned filter change was performed during a midway refueling stop. Pre-flight hyperkalemia was managed with low-potassium replacement fluid. No fluid was removed in the setting of large wound insensible losses. The patient remained hemodynamically stable and required no vasoactive medications. Continuous veno-venous hemofiltration can be used safely during high-altitude flight to evacuate casualties with AKI from distant contingency operations. The use of portable hemodialysis equipment in this case also proves the feasibility of deploying renal replacement therapies to more forward facilities than previously considered.

Pediatric Emergency Medicine Simulation Curriculum: Electrical Injury.

Introduction: Electrical injuries are rare but potentially life-threatening medical emergencies that require providers to manage a critically ill patient while recognizing and treating the unique sequelae associated with the diagnosis. This simulation case is designed to give pediatric and emergency medicine residents, fellows, attendings, and nurses the opportunity to practice these skills in a realistic setting. Methods: This simulation-based curriculum was designed for a high-fidelity mannequin in an emergency department resuscitation room but can be adapted to fit a variety of learning environments. The case featured a 16-year-old boy presenting to the emergency department after arresting in the field after sustaining an electrical injury. He developed ventricular tachycardia during the simulation and had significant hyperkalemia, requiring emergent management. The included debriefing tools assisted instructors in providing formative feedback to learners. Results: A total of 40 residents, medical students, and fellows participated in this scenario and provided overwhelmingly positive feedback about the learning experience. Mean Likert scores for participant confidence related to learning objectives after the simulation were 4 or greater on a 5-point scale. Discussion: This case was developed to help learners at various levels of training recognize and manage a low-frequency, high-acuity scenario in a standardized environment. Participants specifically had the opportunity to perform airway management, cardiopulmonary resuscitation, defibrillation, and management of hyperkalemia, which may present in real life from a multitude of etiologies. The included materials helped prepare and assist facilitators with debriefing, supplemental education, and bidirectional feedback.

Applications of 256-Slice, Spiral Computed Tomography Perfusion Scanning in Limb Salvage After High-Voltage Electrical Injury.

OBJECTIVE: This study aimed to investigate the applications of intelligent 256-slice computed tomography (iCT) perfusion imaging in high-voltage electrical injuries (HVEIs). METHODS: 256-slice iCT was used to perform perfusion scanning for 48 patients with HVEI to detect the perfusion parameters. RESULTS: The blood flow (BF) and peak enhancement intensity (PEI) values of the plane lower than the amputation level of the diseased side (ALD) were smaller than those of the corresponding healthy side (P<0.05); therefore, the differences were statistically significant. The BF value of the plane beyond the ALD was bigger than that of the ALD (t=2.99 and P=0.042); therefore, the difference was statistically significant. The BF, PEI, and blood volume values of the plane below the ALD were smaller than those of the ALD (P<0.05); therefore, the differences were statistically significant. CONCLUSIONS: The technique of 256-slice iCT perfusion imaging could provide richer and more comprehensive imaging data for the clinical treatment of HVEIs, thus exhibiting its benefit in reducing the disability of patients with HVEIs. (Disaster Med Public Health Preparedness. 2018;12:478-485).

Electrical cardiac injuries: current concepts and management.

Electrical injuries are a commonly encountered hazard in both the home and workplace. However, clinicians are often uncomfortable when faced with the patient who presents with an electric shock due to sparse literature and lack of systematic recommendations on this topic. Electrical injuries can range from minor skin burns to life threatening internal organ damage. A thorough clinical assessment to ascertain the path of current through the body and possible internal injury is essential. The main concern in an apparently stable individual after an electric shock is the potential for delayed occurrence of cardiac arrhythmias which will require monitoring in the intensive care setting. While it may be reasonable to discharge home from the emergency room selected patients with low voltage injuries, absence of syncope and a normal ECG, others may require monitoring for at least 24 h. Public education and increasing workplace as well as home safety measures are key steps in prevention. The present review summarizes current knowledge in pathophysiology, manifestations and management of electrical injuries, with specific focus on cardiac effects.

Epidemiology of electrical and lightning-related injuries among Canadian children and youth, 1997-2010: A Canadian Hospitals Injury Reporting and Prevention Program (CHIRPP) study.

IntroductionAlthough death due to electrical injury and lightning are rare in children, these injuries are often preventable. Twenty years ago, most injuries occurred at home, precipitated by oral contact with electrical cords, contact with wall sockets and faulty electrical equipment. We sought to assess the epidemiology of electrical injuries in children presenting to Emergency Departments (EDs) that participate in the Canadian Hospitals Injury Reporting and Prevention Program (CHIRPP). METHODS: This study is a retrospective review of electrical and lightning injury data from CHIRPP. The study population included children and youth aged 0-19 presenting to participating CHIRPP EDs from 1997-2010. Age, sex, year, setting, circumstance and disposition were extracted. Variables were tested using Fisher's exact test and simple linear regression. RESULTS: The dataset included 1183 electrical injuries, with 84 (7%) resulting in hospitalization. Most events occurred at home in the 2-5 year age group and affected the hands. Since 1997 there has been a gradual decrease in the number of electrical injuries per year (p<0.01) and there is an annual surge in electrical injuries over the summer (p<0.01). Forty-six percent of injuries involved electrical outlets, 65% of injuries involved some sort of electrical equipment. Injuries due to lightning were rare (n=19). No deaths were recorded in the database. CONCLUSION: Despite the decrease in the number of electrical injuries per year, a large portion of injuries still appear to be preventable. Further research should focus on effective injury prevention strategies.

[Immediate and delayed outcomes after electrical injury. A guide for clinicians]. / Elolyckor kan ge skador som visar sig efter lång tid - Det akuta omhändertagandet kan vara avgörande på sikt.

Immediate and delayed outcomes after electrical injury. A guide for clinicians In Sweden about 300 electrical injuries are recorded each year at the Swedish National Electrical Safety Board. Most of our knowledge of the health consequences of these arise from clinical case series. Severe electrical injuries have direct thermal effects and may result in ventricular fibrillation, skin burns, as well as muscular and nerve affection. Long-term consequences include pain, vascular symptoms, cognitive and neurological symptoms and signs. These sequelae may occur even though the initial symptoms were relatively modest. Mechanisms are better understood for the immediate symptoms, compared to long-term and delayed non-thermal medical consequences. Attention to and treatment of patients with electrical injury needs to be improved to minimize long-term consequences. Good medical care in the acute phase and early multidisciplinary follow-up of severe cases will likely reduce associated morbidity. Each electrical injury should result in an inquiry to identify the cause of the accident in order to suggest actions to prevent new incidents.