Keywords
COVID-19 - posterior fossa tumor - pediatrics - myocardial damage
Palavras-chave
COVID-19 - tumor da fossa posterior - pediatria - dano miocárdico
Background and Importance
The relatively small number of pediatric neurosurgical subjects that coped a COVID-19
course of disease makes it a matter of debate to deal with these patients in their
neurosurgical procedures.[1] Guidelines suggest the postponement of non-urgent procedures until the period of
crisis is over.[2] The present article points out that patients who have recovered from COVID-19 would
require of thorough work-ups that could be lifesaving prior to specific procedures.
There are still some conditions that pediatric neurosurgeons may face in the context
of COVID-19 which have not been fully addressed so far.[3] The presence of acute ischemic events and fat embolism are common in children with
hemoglobinopathies and COVID-19. Shchedrygina et al.[4] have postulated an ongoing inflammatory myocardial status in a significant proportion
of patients who have recovered from COVID-19. They have concluded that the initiation
and propagation of the inflammatory cascade following viral invasion takes place irrespective
of the severity of COVID-19. This process would involve patients in all age groups,
including pediatric patients. Hence, COVID-19 could lead to a significant chance of
progressive heart failure. We herein report our experience with a 10-month-old girl
who had recovered form COVID-19 and had a case of fourth-ventricle mass in the midline
of the posterior fossa. She was scheduled for microneurosurgical resection of the
mass.
Case Presentation
The patient was had been born through normal vaginal delivery without any known peripartum
complications, and was brought to the Shiraz pediatric neurosurgery ward, a referral
center in the south of Iran, with a chief complaint of repeated episodes of nausea
and vomiting despite thorough gastrointestinal investigations. A non-contrast brain
computed tomography (CT) scan revealed a fourth-ventricle mass in the midline with
severe obstructive hydrocephalus and a globular third ventricle. Insertion of a ventriculoperitoneal
shunt (VPS) was scheduled, as our policy is to proceed with the VPS, but we chose
to give the patient at least one week to try to cool the brain edema via cerebrospinal
fluid diversion along with dexamethasone in an outpatient setting.
During this period, she developed a COVID-19 infection that was confirmed. So, we
delayed the next operative stage for three weeks until she tested negative for severe
acute respiratory syndrome coronavirus 2 (SARS-COV-2).
The patient was admitted about a month later in a stable condition. She was brought
to the operating theater in an elective setting for microneurosurgical resection of
the posterior-fossa lesion. It is worth noting that a thorough preoperative evaluation
was performed by the pediatric anesthesiology team.
There were no significant isssues regarding the induction of anesthesia. A central
access line was drawn, and we changed her to a prone position. A midline suboccipital
approach was chosen, and the patient was fully prepared and draped. Suboccipital soft
tissues and muscles were dissected layer by layer through the midline avascular line,
from the inion to the level of the C2 vertebrae. No significant bleeding occurred
during this stage of dissection. A total of two burr holes were made using the Medtronic
(Dublin, Ireland) Midas Rex Legend AD03 Perforator Driver, and craniectomy was carried
out exposing the posterior fossa from the confluent sinus to the rim of the magnum.
A marked gush of blood off the midline was observed during the opening in Y of the
dura mater. Hemostasis was achieved using surgical and two cotton balls. We proceeded
with the opening of the midline portion of the dura mater, but, suddenly, ∼ 100 mL
of blood was lost despite the millimeter-by-millimeter advancement of the dural opening.
We packed the field and filled it with copious amount of normal saline. The vital
signs were still stable except for relative tachycardia (180 beats per minute). The
anesthesiologist replaced the amount of blood lost drop by drop throughout the operation.
We started to approach the occipital sinus. However, there was an unusual loss of
∼ 200 mL of blood from this area. Despite the proper packed-cell transfusion, the
patient developed bradycardia and a sudden rhythm of asystole. The cardiopulmonary
cerebral resuscitation (CPCR) was initiated immediately, and the position of the patient
was changed to supine while the surgical field remained wide open and just packed
with enough gauze. The CPCR continued for ∼ 90 minutes. Despite the maximal effort,
the heart rate did not even change to one beat per minute. In the meantime, chest
tubes were inserted bilaterally, but no pneumothorax was found. The electromechanical
dissociation rhythm did not change. The patient passed away regardless of the attempts
to reverse the rhythm.
Discussion
Valverde et al.,[1] in a thorough investigation on cardiovascular involvement in pediatric COVID-19
patients, stated that the SARS-COV-2 infection resulted in direct myocardial damage,
a vicious inflammatory cascade which could lead to myocardial dysfunction and ventricular
arrhythmia. Furthermore, COVID-19 would exhibit a kindling phenomenon, known in cases
of temporal-lobe epilepsy, which would result in myocardial dysfunction and arrhythmia.
This kindling phenomenon induces fever, increased oxygen consumption, ion alterations,
and, finally, a metabolic crisis.[1] Ludvigsson et al.[5] reported their experience with five children in who had recovered from COVID-19,
and reviewed the literature for the long-term effects of the disease on the heart,
such as perimyocarditis. The authors[5] claimed that these symptoms follow a similar trend in children and adults. Ley-Vega[6] pointed out the potential cardiac problems in a population of Cuban children previously
diagnosed with convulsion. The author[6] found myocarditis, pericarditis, and arrhythmias in 18% of the sample (20 patients
out of 110 cases), and an interesting finding was that the patients evolved satisfactorily
following several weeks of monitoring and treatment. Ley-Vega[6] stated that these abnormalities may be reversible, but potentially time-consuming
for proper recovery.
The retrospective analysis of the preoperative brain magnetic resonance imaging scan
of our patient revealed nothing unusual regarding the occipital sinus. There are two
plausible scenarios for our case: a post-COVID-19 subclinical myocardial damage that
made this patient decompensated following a blood loss; the second scenario is based
on air embolism. However, the latter is less likely because the embolus would theoretically
pass through the right ventricle following our vigorous CPCR.
Conclusion
We recommend that pediatric neurosurgeons postpone the procedures to be performed
in patients who have recovered from COVID-19 for more than one month after a thorough
preoperative cardiac evaluation has been performed, even if there is no frank clinical
disorder to estimate the cardiac reserve of a given patient.
