CASE REPORT

TANGO-2 with Severe and Prolonged
Rhabdomyolysis in a 2-year Old Male with
Human metapneumovirus Infection

Rowida Kheireldin a Sameer Imdad a Waseem Ostwani b

Coresponding author(s): waseem.ostwanimd@promedica.org

aDivisions of Pediatrics, Department of Pediatrics, University of Toledo, College of Medicine and Life Sciences, Toledo, OH 43614, USA, and bDivisions of Critical
Care Medicine, Department of Pediatrics University of Toledo College of Medicine and Life Sciences, Toledo, OH 43614, USA

We report a unique case of prolonged acute rhabdomyolysis in
a 2-year-old male with known TANGO-2 mutation with delayed
peak in creatinine kinase levels secondary to human metapneu-
movirus infection. Creatinine kinase peaked at 424,760 U/l on day
9 of hospitalization. Resolution of rhabdomyolysis was achieved
using aggressive management with intravenous fluids with op-
timal urine output and no kidney injury. TANGO-2 patients may
develop severe and prolonged rhabdomyolysis with a delayed
peak suggesting the need for prolonged inpatient hospitaliza-
tion to prevent life-threatening complications.

TANGO-2 | rhabdomyolysis | creatinine kinase | infection

TANGO-2 Mutation usually presents with metabolic en-cephalomyopathies, hypoglycemia, recurrent rhabdomyolysis,
developmental delay and seizures. Acute rhabdomyolysis with
TANGO-2 presents with a wide array of symptoms ranging from
profound muscle weakness and disorientation to coma (1). When it
comes to rhabdomyolysis in patients with TANGO-2 mutation, CK
can be significantly elevated up to greater than 200,000 U/l (1).

Case Report

Patient Information

A 2-year-old male with a known TANGO-2 mutation presented
to the emergency department with a 3-day history of fever, upper
respiratory symptoms along with decreased oral intake. Mother also
noted that the urine was darker in color. The rest of the review of
symptoms was non-contributory.

Objective for Case Reporting

Rhabdomyolysis may progress over a week with extremely high
CK levels. We suggest prolonged inpatient hospitalization for pa-
tients with TANGO-2 mutation and rhabdomyolysis in order to pre-
vent life-threatening complications.

Case

In the ED, labs were significant for decreased bicarbonate level
at 19 mmol/L with an anion gap of 17 mmol/L and a mildly elevated
creatinine kinase of 232 U/L. Electrocardiogram showed a normal
QT interval. Patient was given a fluid bolus of normal saline then
admitted to the pediatric floor where he was continued on 1.5 times
maintenance intravenous fluids with dextrose 10% and Levocarni-
tine as per his emergency management plan. The on-call geneticist
was consulted and recommended monitoring CK levels and follow-
ing EKG daily for the increased risk of QT prolongation. Respira-
tory pathogen panel was positive for Human metapneumovirus. IV
fluids were cut to 1/2 maintenance on day 3 of admission to help
stimulate better oral feeds. On day 4 of hospitalization, the pa-
tient’s urine started to look more concentrated and CK levels were
increased to 7,031 indicating continued rhabdomyolysis. IV fluids
were increased to twice maintenance as CK level increased steadily
to 43,000 U/L, patient was refusing to walk due to pain with total

Submitted: 05/20/2020, published: 08/11/2020.

Freely available online through the UTJMS open access option

24–27 UTJMS 2020 Vol. 7 translation@utoledo.edu

mailto:waseem.ostwanimd@promedica.org


Day of Hospitalization

U
rin

e 
pH

0

2

4

6

8

10

Day 1 Day 8 Day 9 Day 12

Fig. 1. Urine pH during hospital course

Day of Hospitalization

U
rin

e 
ou

tp
ut

 (
m

l/h
r)

0

2

4

6

Day 1 Day 5 Day 7 Day 8 Day 9 Day 12 Day 15

Fig. 2. Urine output during hospital course

body aches and he was transferred to the Pediatric Intensive Care
Unit for close monitoring, foley catheter was placed and urine out-
put was maintained at 3 ml/kg/hr with subsequent alkalinization of

IV fluids utilizing sodium bicarbonate to achieve urine PH of 6-8
(Fig. 1, 2).

Kheireldin et al. UTJMS 2020 Vol. 7 25



Day of Hospitalization

C
re

at
in

e 
K

in
as

e 
(U

/L
)

0

100000

200000

300000

400000

500000

Day 1 Day 5 Day 7 Day 8 Day 9 Day 12 Day 15

Fig. 3. Creatine kinase (CK) levels during hospital course

Infection work-up did not reveal any bacterial infection as a sec-
ondary cause of this ongoing rhabdomyolysis. Patient’s CK level
peaked at 424,760 U/L on day 9 of hospitalization (Fig.3). Renal
function remained stable despite increasing CK levels with aggres-
sive medical management. Liver enzymes were elevated up to the
1000 range with normal synthetic liver function and bilirubin, which
was attributed to acute illness. Blood pressure throughout hospital
stay remained normal with mild hypertension during the PICU stay
that was resolved. This could be attributed to the high rate of fluids
administration during the management of rhabdomyolysis. Aggres-
sive medical management for rhabdomyolysis was deescalated due
to downtrending CK levels and transaminitis, along with clinical
improvement.

Discussion

TANGO-2 Mutation is an autosomal recessive disorder charac-
terized by metabolic encephalomyopathies, hypoglycemia, hyper-
ammonemia, recurrent rhabdomyolysis, developmental delay and
seizures. It is caused by variations in the transport and Golgi or-
ganization 2 (TANGO2) gene responsible for creating the proteins
that play a critical role in many functions of the body (2). The
TANGO2 Research Foundation reports fewer than 30 individuals af-
fected with the disorder worldwide (2). The onset of first symptoms
may occur as early as 4 months and up to 27 months of age (3). Dur-
ing an acute illness, affected individuals may develop arrhythmias
with QT prolongation, being the leading cause of death in children
with TANGO-2 mutations. During a metabolic crisis, some patients
may develop acute rhabdomyolysis. Acute rhabdomyolysis with
TANGO-2 presents with symptoms that vary from profound muscle
weakness, ataxia, and disorientation to coma (1). Myoglobinuria
can lead to renal failure.

Mechanisms leading to metabolic crises and rhabdomyolysis
among patients with TANGO-2 are not well understood or reported
in the literature (2). Rhabdomyolysis has been reported in patients
with TANGO-2 with age ranging between 5 months up to 13 years
of age (5). It can be recurrent resulting in acute renal tubular dam-
age, acute kidney injury and renal failure(6). Recurrent rhabdomy-
olysis can be fatal in severe cases with 8-10 % mortality rate. Acute
kidney injury with cardiac arrhythmia due to hyperkalemia are the
main causes of increasing mortality(5). Triggers for rhabdomyol-

ysis associated with genetic abnormalities include fever, exercise,
infection, general anesthesia, drugs, emotional stress and changes
in diet (7). Human metapneumovirus infection was the trigger fac-
tor in our case.

CK serum level is useful in the diagnosis and management for
rhabdomyolysis. CK levels gradually increase in the first 12 hours
of rhabdomyolysis with a peak at 3-5 days, and return to baseline
within 6-10 days (8,9). Serum CK levels exceeding five times the
upper limit of normal are commonly used for diagnosing rhabdomy-
olysis(8). In rhabdomyolysis secondary to viral myositis, the serum
CK level usually peaks at 1-5 days (10,11).

There is no available data regarding the range of CK levels when
it comes to rhabdomyolysis in patients with TANGO-2 mutation.
CK can be significantly elevated up to greater than 200,000 U/l (1).
Lalani et al reported CK ranging from 16,674 U/l and up to 287,230
U/l (5). In a case report of a 3-year-old patient with TANGO and
rhabdomyolysis, the peak for CK was 225,000 IU/l on day 4 of
his illness (6). Dines et al study showed CK elevation was present
in 11 out of 14 patients ranging from 14,000 to 278,000 U/l with
rhabdomyolysis documented in 9 of these patients, with 1 patient
presenting at 4 months with elevated creatinine kinase secondary to
rhinovirus (3). In our patient, the highest CK was 424,760 U/l on
day 9 of hospitalization which is the highest reported CK number in
the literature for rhabdomyolysis secondary to TANGO-2 mutation.

Complications of rhabdomyolysis include high anion gap
metabolic acidosis, hyperkalemia, acute kidney injury and dissem-
inated intravascular coagulopathy(12). Acute kidney injury is the
most common systemic complication of rhabdomyolysis and oc-
curs in 5-50 % of the patients with poor outcome (12,13). Elevated
serum CK has not been shown to correlate with the severity of AKI
(13,14). In spite of the highly elevated CK level in our patient, with
close monitoring and aggressive management, his renal function re-
mained stable with no evidence of AKI.

There is a lack of guidelines for the best treatment in children
with rhabdomyolysis (8,10). Management of acute rhabdomyol-
ysis involves hydration and alkalinization of the urine in order to
prevent development of AKI, monitoring for electrolyte imbalance,
correction of metabolic acidosis, and management of other compli-
cations. An emergency plan for patients with TANGO-2 should be

26 translation@utoledo.edu Kheireldin et al.



in place in order to minimize the risk of life-threatening rhabdomy-
olysis and cardiac arrhythmias. Aggressive hydration with fluids
to achieve urine output of 3 ml/kg/hr is recommended. The role
of mannitol and bicarbonate in the treatment of rhabdomyolysis in
pediatric patients remains controversial, although urine alkaliniza-
tion to pH of ≥ 7.0 using sodium bicarbonate-containing fluids has
been recommended in some studies (1,13). Hemodialysis may be
indicated for severe fluid overload and electrolyte abnormalities (1).
The rhabdomyolysis in our case peaked at day 9 of hospitalization
highlighting the importance of close monitoring and management
for rhabdomyolysis in TANGO-2 patients to a longer extent com-
pared to other causes of rhabdomyolysis.

The small number of reported cases, the lack of large clinical
studies, and the recent identification of TANGO-2 is not allowing
complete understanding of the prognosis and clinical course of this
genetic abnormality (2). Further research is needed to help under-
stand this mutation and the mechanism behind the associated rhab-
domyolysis.

Conclusion

Acute rhabdomyolysis in TANGO-2 patients presents with var-
ious levels of illness severity. Even with mild illness, rhabdomyol-
ysis may take over a week until it peaks with extremely high CK
levels suggesting the need for prolonged inpatient hospitalization in
order to prevent life-threatening complications.

Conflict of interest

Authors declare no conflict of interest.

Authors’ contributions

RK and SI wrote the initial draft of this case report. WO edited
the manuscript and reviewed the paper. All authors read and ap-
proved the final document.

1. Lalani S, et al. (2018), TANGO2-Related Metabolic Encephalopathy and Arrhyth-
mias. GeneReviews.

2. Shott B, Miyake C, Neu D, Lalani S. (2019), Engaging Patients in Outcomes Re-
search in TANGO2-related disorder. The Baylor College of Medicine and the
TANGO2 Research Foundation Family Conference. Houston, Texas. Available at
https://tango2research.org/.

3. Dines J, et al. (2019), TANGO2: expanding the clinical phenotype and spectrum
of pathogenic variants. Genet Med. 21(3):601-607.

4. Elsayed E, Reilly R. (2010),Rhabdomyolysis: a review, with emphasis on the
pediatric population. Pediatr Nephrol. 25(1):7-18.

5. Lalani S, et al. (2016) Recurrent Muscle Weakness with Rhabdomyolysis,
Metabolic Crises, and Cardiac Arrhythmia Due to Bi-allelic TANGO2 Mutations.
Am J Hum Genet. 98(2):347-357.

6. Ricci F, et al. G. (2017) Multi-system disorder and severe recurrent rhabdomyol-
ysis due to TANGO2 mutations in a 3 year-old child. Neuromuscular disorders.
Volume 27, Supplement 2, S207, October 01.

7. Scalco R, et al. (2015) Rhabdomyolysis: a genetic perspective. Orphanet J Rare
Dis. 10:51.

8. Chavez L, Leon M, Einav S, Varon J.(2016) Beyond muscle destruction: a sys-
tematic review of rhabdomyolysis for clinical practice. Crit Care 20, 135.

9. Cervellin G, et al. (2017) Non-traumatic rhabdomyolysis:Background, laboratory
features, and acute clinical management. Clin Biochem. 50(12):656-662.

10. Attanasi M, et al.(2018) A pediatric case of rhabdomyolysis with acute renal fail-
ure due to co-infection with Epstein-Barr virus and Human herpesvirus 6. Arch
Med Sci. 14(1):254-256.

11. Goldsmith B, Hicks J. (1985)Rhabdomyolysis: two pediatric case reports., Clini-
cal Chemistry, Volume 31, Issue 2, 314{317

12. Williams J,Thorpe C. (2014) Rhabdomyolysis, Continuing Education in Anaes-
thesia, Critical Care and Pain, Volume 14, Issue 4, 163{166

13. Chen CY, et al. (2013) Clinical spectrum of rhabdomyolysis presented to pediatric
emergency department. BMC Pediatr. 13:134.

14. De Meijer A, Fikkers B,De Keijzer M, Van Engelen B, Drenth J. (2003) Serum crea-
tine kinase as predictor of clinical course in rhabdomyolysis: a 5-year intensive
care survey. Intensive Care Med. 29(7):1121-1125.

15. Lalani S, Miyake C, Burrage L. (2018) TANGO2-Related Metabolic Encephalopa-
thy and Arrhythmias. National Organization for Rare Disorders (NORD).

Kheireldin et al. UTJMS 2020 Vol. 7 27