Rhabdomyolysis in a Tertiary PICU: A 10-Year Study

Paediatric rhabdomyolysis: A UK centre's 10-year retrospective experience

AIMS

To describe the aetiologies of paediatric rhabdomyolysis and explore the medium-term renal consequences.

METHODS

Retrospective, single-centre review of children with rhabdomyolysis.

RESULTS

Two hundred and thirty-two children met inclusion criteria for the analysis. Mean age at presentation was 8.4 (SD ± 5.5) years. The commonest aetiology was infection (28%), with viral myositis making up the clear majority (75%). Trauma was identified as a cause in 18% of children, seizures in 10% and immune-mediated mechanisms in 8%. Acute kidney injury (AKI) was present in 32% of the cases overall. Children with AKI tended to be younger, with higher peak creatine kinase (CK) and active urinary sediment on urinalysis at presentation. AKI and the need for renal replacement therapy (RRT) were associated with a prolonged hospital stay (15 (interquartile range, IQR 6.5-33) vs. 2 (IQR 0-7) days). A total of 18 children and young people required RRT, with a mean duration of 7.1 ± 4.3 days. Those who received RRT were more likely to have abnormalities on urinalysis at presentation (46% vs. 5%). Over the period of the study, 9% of children died and 2% met criteria for a diagnosis of chronic kidney disease.

CONCLUSIONS

This large paediatric rhabdomyolysis case series provides new and unique insights into the condition. Our results highlight the common aetiologies and provide evidence of good renal recovery overall, even in the most severely affected cases. Abnormalities of urinalysis appear to be important in predicting the development of AKI and the need for RRT.

Malignant Hyperthermia in PICU—From Diagnosis to Treatment in the Light of Up-to-Date Knowledge

Malignant Hyperthermia (MH) is a rare, hereditary, life-threatening disease triggered by volatile anesthetics and succinylcholine. Rarely, MH can occur after non-pharmacological triggers too. MH was detected more often in children and young adults, which makes this topic very important for every pediatric specialist, both anesthesiologists and intensivists. MH crisis is a life-threatening severe hypermetabolic whole-body reaction. Triggers of MH are used in pediatric intensive care unit (PICU) as well, volatile anesthetics in difficult sedation, status asthmaticus or epilepticus, and succinylcholine still sometimes in airway management. Recrudescence or delayed onset of MH crisis hours after anesthesia was previously described. MH can also be a cause of rhabdomyolysis and hyperpyrexia in the PICU. In addition, patients with neuromuscular diseases are often admitted to PICU and they might be at risk for MH. The most typical symptoms of MH are hypercapnia, tachycardia, hyperthermia, and muscle rigidity. Thinking of the MH as the possible cause of deterioration of a patient’s clinical condition is the key to early diagnosis and treatment. The sooner the correct treatment is commenced, the better patient´s outcome. This narrative review article aims to summarize current knowledge and guidelines about recognition, treatment, and further management of MH in PICU.

Motor Vehicle Collision and Acute Kidney Injury in Children

OBJECTIVE

Our study aimed to determine the prevalence of acute kidney injury (AKI) in pediatric patients who sustained trauma due to motor vehicle collision (MVC) and identify factors associated with its development.

METHODS

We retrospectively reviewed the clinical information and laboratory tests of pediatric patients who were admitted because of MVC from January 2014 to April 2021. The occurrence of AKI was our primary outcome, which was defined by the Kidney Disease Improving Global Outcomes criteria. A serum creatine kinase (CK) level of 1000 IU/L or greater was defined as rhabdomyolysis.

RESULTS

Sixty-four patients (median age, 9.6 years) were included in the study. Twenty three of the patients (35.9%) developed AKI: stage 1 AKI in 18 (78.3%) and stage 2 AKI in 5 (21.7%) patients. Acute kidney injury patients had higher injury severity scores (no AKI: 5.0; stage 1 AKI: 10.5; stage 2 AKI: 26.0). Rhabdomyolysis was present in 21.1% of the patients and was associated with the overall AKI risk (odds ratio [OR], 7.3; 95% confidence interval [CI], 1.6-32.6) and stage 2 AKI (OR, 15.0; 95% CI, 1.4-163.2). Blood tests from AKI patients showed lower serum bicarbonate and base excess, higher leukocyte and CK levels on admission, and a higher peak CK in the first 72 hours of admission. Intubation in emergency department (OR, 11.1; 95% CI, 1.2-102.1) and surgical interventions (OR, 3.2; 95% CI, 1.0-9.8) were associated with AKI. Acute kidney injury patients required longer stay in pediatric intensive care unit (median 1.0 vs 2.3 days, P < 0.001) and hospital (median 4.1 vs 7.0 days, P = 0.010).

CONCLUSIONS

Approximately one third of pediatric patients who sustained trauma from MVC developed AKI. Initial blood results, including higher CK and leukocyte count, and lower bicarbonate and base excess, were associated with the development of AKI. Rhabdomyolysis occurred in approximately one fifth of the patients and was significantly associated with AKI.

Trends in Pediatric Rhabdomyolysis and Associated Renal Failure: A 10-Year Population-Based Study

OBJECTIVES

Rhabdomyolysis in children is a highly variable condition with presentations ranging from myalgias to more severe complications like acute renal failure. We sought to explore demographics and incidence of pediatric rhabdomyolysis hospitalizations and rates of associated renal failure, as our current understanding is limited.

METHODS

This was a retrospective analysis using the Healthcare Cost and Utilization Project Kids' Inpatient Database to identify children hospitalized with a primary diagnosis of rhabdomyolysis. Data were analyzed for demographic characteristics, as well as geographic and temporal trends. Multivariable logistic regression was used to identify characteristics associated with rhabdomyolysis-associated acute renal failure.

RESULTS

From 2006 to 2016, there were 8599 hospitalized children with a primary diagnosis of rhabdomyolysis. Overall, hospitalizations for pediatric rhabdomyolysis are increasing over time, with geographic peaks in the South and Northeast regions, and seasonal peaks in March and August. Though renal morbidity was diagnosed in 8.5% of children requiring hospitalization for rhabdomyolysis, very few of these patients required renal replacement therapy (0.41%), and death was rare (0.03%). Characteristics associated with renal failure included male sex, age greater than 15 years, and non-Hispanic Black race.

CONCLUSIONS

Though renal failure occurs at a significant rate in children hospitalized with rhabdomyolysis, severe complications, including death, are rare. The number of children hospitalized with rhabdomyolysis varies by geographic region and month of the year. Future studies are needed to explore etiologies of rhabdomyolysis and laboratory values that predict higher risk of morbidity and mortality in children with rhabdomyolysis.

Acute kidney injury in pediatric non-traumatic rhabdomyolysis

BACKGROUND

Our study aimed to determine the prevalence of acute kidney injury (AKI) in pediatric non-traumatic rhabdomyolysis, and to identify factors associated with its development.

METHODS

Clinical information and laboratory tests of children with rhabdomyolysis who were admitted between 2009 and 2018 were reviewed retrospectively. Rhabdomyolysis was defined by a peak serum creatine kinase (CK) level > 1000 IU/L within the first 72 h of admission. The primary outcome was the occurrence of AKI within the first 7 days of admission, which was determined by the KDIGO criteria.

RESULTS

A total of 54 patients with a median age of 7.8 years old were included. Ten (18.5%) patients developed AKI. AKI was relatively rare in children with viral myositis (2.6%), whereas all patients with rhabdomyolysis related to seizure or irritability/dystonia developed AKI. Patients with AKI had higher white cell count (10.6 vs. 4.5 × 10⁹/L) and lower serum bicarbonate (19.4 vs. 25.5 mmol/L) on admission, with higher peak serum CK (23,086.0 vs. 3959.5 IU/L). The AKI group was more likely to present with positive urine results (myoglobinuria, dipstick heme or protein ≥ 2+). Peak serum CK had a good discriminatory power for stage 2-3 AKI (AUC 0.930, p = 0.005), with an optimal cut-off of 15,000 IU/L identified from the ROC analysis.

CONCLUSIONS

The overall prevalence of AKI in pediatric non-traumatic rhabdomyolysis was 18.5%. Positive urine tests (myoglobinuria, dipstick heme or protein ≥ 2+), high white cell count, lower serum bicarbonate on admission, and high peak serum CK were associated with development of AKI.

Characteristics of pediatric rhabdomyolysis and the associated risk factors for acute kidney injury: a retrospective multicenter study in Korea

Background

The clinical features of pediatric rhabdomyolysis differ from those of the adults with rhabdomyolysis; however, multicenter studies are lacking. This study aimed to investigate the characteristics of pediatric rhabdomyolysis and reveal the risk factors for acute kidney injury (AKI) in such cases.

Methods

This retrospective study analyzed the medical records of children and adolescents diagnosed with rhabdomyolysis at 23 hospitals in South Korea between January 2007 and December 2016.

Results

Among 880 patients, those aged 3 to 5 years old composed the largest subgroup (19.4%), and all age subgroups were predominantly male. The incidence of AKI was 11.3%. Neurological disorders (53.6%) and infection (39.0%) were the most common underlying disorder and cause of rhabdomyolysis, respectively. The median age at diagnosis in the AKI subgroup was older than that in the non-AKI subgroup (12.2 years vs. 8.0 years). There were no significant differences in body mass index, myalgia, dark-colored urine, or the number of causal factors between the two AKI-status subgroups. The multivariate logistic regression model indicated that the following factors were independently associated with AKI: multiorgan failure, presence of an underlying disorder, strong positive urine occult blood, increased aspartate aminotransferase and uric acid levels, and reduced calcium levels.

Conclusions

Our study revealed characteristic clinical and laboratory features of rhabdomyolysis in a Korean pediatric population and highlighted the risk factors for AKI in these cases. Our findings will contribute to a greater understanding of pediatric rhabdomyolysis and may enable early intervention against rhabdomyolysis-induced AKI.

A rare case of metapneumovirus-induced rhabdomyolysis and multi-organ dysfunction in a 4-year-old child

Human metapneumovirus (hMPV) is a common cause of acute respiratory tract infections in children. In immunocompetent individuals, the course of hMPV infection is usually benign and self-limiting. A developmentally normal, previously healthy 4-year-old girl presented with pneumonia and later developed rhabdomyolysis and multi-organ dysfunction syndrome (MODS) which was fatal. Extensive microbiological investigation for a possible viral aetiology was positive only for hMPV, thus making it the first reported case of hMPV infection-related rhabdomyolysis.Abbreviations: ARDS, acute respiratory distress syndrome; CK, creatinine kinase; hMPV, human metapneumovirus; MODS, multi-organ dysfunction syndrome; RSV, respiratory syncytial virus.

Use of dexamethasone in idiopathic, acute pediatric rhabdomyolysis

Current rhabdomyolysis treatment guidelines vary based on the etiology and diagnosis, yet many cases evade conclusive diagnosis. In these cases, treatment options remain largely limited to fluids and supportive therapy. We present two cases of acute rhabdomyolysis diagnosed in the emergency department: a 5-year-old boy with sudden onset bilateral flank pain, and a 13-year-old boy with 2-3 days of worsening pectoral and shoulder pain. Each patient had a prior similar episode requiring hospitalization in the past. The 5-year-old had no inciting trauma or trigger, medication use, or illness. The 13-year-old previously had an upper respiratory infection during the week prior and had been strenuously exercising at the time of onset. Genetic testing results were unknown for both patients during their hospitalizations, and insurance and other barriers led to delay. Later results for the first patient revealed a heterozygous deletion in intron 19 on the LPIN1 gene interpreted as a variant of unknown significance. During their hospitalizations, both children were started on intravenous (i.v.) fluids, and creatine kinase (CK) initially trended downward, but then began to rise or plateau. After reviewing the cases, prior literature, and anecdotal evidence of benefit from corticosteroid therapy in rhabdomyolysis with our consultant metabolic physicians, dexamethasone was initiated. In both patients, dexamethasone use correlated with relief of patient symptoms, significantly decreased CK value, and our ability to discharge these patients home quickly. Our cases, discussion, and literature review all lead to the consideration of the use of dexamethasone in conjunction with standard therapy for acute rhabdomyolysis.

Pediatric Rhabdomyolysis

Pediatric rhabdomyolysis is a common diagnosis that pediatricians need to be able to recognize because prompt treatment can prevent potential complications, such as acute kidney injury. The triggers for rhabdomyolysis are extensive, with viruses being the most common cause in pediatric patients. The pathophysiology behind rhabdomyolysis is complex and still being researched, but having a firm understanding of the cascade that results when muscle injury occurs is essential for proper management. Guidelines for managing pediatric rhabdomyolysis currently do not exist, but this article aims to review the available literature and give clinicians a general approach to aid in history taking, physical examination, diagnosis, acute management, follow-up, and prevention.

Clinical Features of Acute Rhabdomyolysis in 55 Pediatric Patients

Objective: This study was designed to compare the clinical manifestations, laboratory tests, etiology, and prognosis of children with acute rhabdomyolysis (RM) at various ages. This study was designed to analyze the risk factors for acute kidney injury (AKI) in children with RM and to identify the role of neuromuscular and autoimmune disease in children with RM. Methods: Clinical data for 55 children with RM were collected and statistically analyzed. Patients were stratified to an infant group (G1) (age <1 year), preschool group (G2) (age 1-6 year), school-age group (G3) (age 7-11 year), and an adolescent group (G4) (age 12-16 year). Results: The top three clinical manifestations were dark urine (52.7%), myalgia (38.2%), and fever (23.8%). Patients in G1 had fever (71.4%), vomiting (77.8%), and urinalysis abnormalities (14.3%), without triad clinical manifestations. Fifty percent of patients in G4 group had myalgia; 70.8% had dark urine; 75% had abnormal urine tests. The most common cause in each age group was as follows: sepsis (57.1%) in G1; hereditary neuromuscular diseases (44.4%) in G2; immune diseases (40%) in G3; strenuous exercise (50%) in G4. Logistic regression analysis shown that AKI was not corelated with age, gender, or peak creatine phosphokinase. AKI was, however, associated with presence of an electrolyte disorder. Conclusion: The clinical manifestations and laboratory findings in infants with acute RM are not typical and need to be taken seriously. The presence of an electrolyte disorder is a risk factor for AKI in children with RM. The most common pathogenesis of RM varies among age groups. Congenital hereditary metabolic disease and immune diseases should not be ignored as a cause of RM in children.

Damage control orthopedics applied in an 8-year-old child with life-threatening multiple injuries: A CARE-compliant case report

RATIONALE

Damage control is a staged surgical approach to manage polytraumatized patients. The damage control approach comprises three steps. First, bleeding is controlled and fractures are stabilized temporarily; second, vital parameters are stabilized and the child is rewarmed in the intensive care unit; and third, the child is reoperated for definitive repair of injuries. We aimed to describe the feasibility of the damage control orthopedic approach in a child.

PATIENT CONCERNS

An 8-year-old girl fell from the balcony of the 5th floor onto concrete pavement and was admitted to our accident and emergency ward in a stable cardiorespiratory state, but with gross deformity of the lower limbs, left thigh, and forearm.

DIAGNOSES

The child had sustained multiple injuries with severe bilateral lung contusion, pneumothorax, fracture of first rib, liver laceration, stable spine fractures, transforaminal fracture of sacrum, pelvic ring fracture, displaced baso-cervical femoral neck fracture, displaced bilateral multifragmental growth plate fractures of both tibiae, fractures of both fibulae, displaced fracture of left forearm, and displaced supracondylar fracture of the humerus.

INTERVENTION

In the initial operation, we performed closed reduction and K-wire fixation of the right tibia, closed reduction and external fixation of the left tibia, open reduction and screw osteosynthesis of the femoral neck fracture, closed reduction and K-wire fixation of the radius, and closed reduction of the supracondylar fracture. Subsequently, we transferred the girl to the pediatric intensive care unit for hemodynamic stabilization, respiratory therapy, rewarming, and treatment of crush syndrome. In a third step, 10 days after the injury, we managed the supracondylar fracture of the humerus by closed reduction and K-wire fixation.

OUTCOMES

Growth arrest of the left distal tibial growth plate and osteonecrosis of the femoral head and neck, slipped capital femoris epiphysis (SCFE), and coxa vara of the right femur led to balanced leg length inequality 2 years after the injury. The lesion of the left sciatic nerve improved over time and the girl walked without walking aids and took part in school sports but avoided jumping exercises.

LESSONS

We emphasize the importance of damage control principles when managing polytraumatized children.