3-Methylchrotonyl-CoA (3-MCC) Dehydrogenase Deficiency
These acute illness materials are a guideline for healthcare professionals treating the sick infant/child who has previously been diagnosed with 3-methylchrotonyl-CoA dehydrogenase deficiency (3-MCC), a leucine disorder. The materials were developed at Boston Children’s Hospital under the direction of Dr. Harvey Levy, Senior Physician in Medicine/Genetics and Dr. Jonathan Picker, Fragile X Program Director.
Metabolic crises in infants/children with leucine disorders are medical emergencies and must be treated as such to avoid death or serious brain injury.
Disclaimer
Metabolic crises in infants and children with organic acid disorders are complex medical emergencies and must be treated as such to avoid death or serious brain injury. These materials are only a guideline and should not be used for definitive treatment without metabolic consultation. It is essential to call or page the on-call genetics/metabolism fellow, or failing this, the on-call metabolic attending at your hospital or nearest pediatric tertiary care center, as rapidly as possible. Please read our Terms of Use.
Introduction
3-MCC deficiency is one of several defects in the degradation pathway of leucine (a major branched-chain amino acid). Most of the defects produce metabolic ketoacidosis but ketones are absent or low despite acidosis and hypoglycemia in 3-MCC deficiency. Thus, this is a cause of hypoketotic hypoglycemia. The degradative pathway is as follows:
In the presence of catabolism or substantially reduced food intake (e.g. infection, severe exertion), the combination of an increased cellular requirement for energy and reduced glucose intake results in proteolysis with release of amino acids and fatty acids. Enhanced leucine and fatty acid degradation is an attempt by the body to produce the needed energy in the form of ketones. The increased flux in leucine degradation results in accumulation of 3-methylcrotonyl-CoA when 3- MCC is deficient. The accumulated substrate produces metabolic acidosis, inhibits gluconeogenesis resulting in hypoglycemia, and inhibits the urea cycle resulting in hyperammonemia.
Presentation
Vomiting
Lethargy
Encephalopathy
Hypotonia
Failure to thrive
Reye syndrome picture
Developmental delay
Seizures
Sudden death
Parents of children with metabolic disorders know the early signs of decompensation in THEIR children. Listen to them !!!
ASSESSMENT
Assess for dehydration, fever, infection or other stessors that may precipitate an acute metabolic episode. Clinical decompensation can occur rapidly in an infant and may be more gradual in older children.
Investigations
Blood glucose (? hypoglycemia)
pH, blood gases, (? metabolic acidosis)
electrolytes (? low biocarbonate)
ammonia (? hyperammonemia)
urine ketones (? absent or trace)
urinalysis
AST, ALT, AP, PT, PTT
urine organic acids
culture of blood, throat, urine as indicated
ASSESS BIOCHEMICAL PARAMETERS REGULARLY AND FREQUENTLY WHILE SICK
Treatment
1. INDICATION FOR IV (NEVER less than 10% dextrose infusion)
One or more indication is sufficient for IV
Vomiting
Hypoglycemia
Poor PO intake
Dehydration- Do not rely on ketones as indicating dehydration!
Decreased alertness
Metabolic acidosis
Start 10% glucose continuous infusion at 1.5x maintenance to provide 7- 8mg/kg/min
2. HYPOGLYCEMIA
Push 25% dextrose 2ml/kg and follow with a continuous 10% dextrose infusion at 1.5x maintenance to provide 7-8mg/kg/min glucose
3. METABOLIC ACIDOSIS (Bicarbonate level<16)
Must be treated aggressively with IV Sodium bicarbonate (1 mEq/kg). Treating conservatively in the expectation of a re-equilibration of acid/base balance as other biochemical/clinical parameters are normalized can lead to tragic consequences.
4. CARNITINE
Should be provided PO (100-200 mg/kg/day divided TID) or IV (30- 50 mg/kg/day).
5. PRECIPITATING FACTORS
Should be treated aggressively to help minimize further catabolism
6. APPARENTLY WELL
If drinking oral fluids well and none of the above factors present, there is no need for emergent IVI. But history of earlier vomiting, pyrexia, or other stressor should be taken seriously and a period of observation undertaken to ensure that PO fluids are taken frequently and well tolerated, with glucose status monitored periodically.
In conjunction with this protocol, please call or have paged the genetics metabolism fellow on call, or failing this, the metabolic attending on call at your hospital or nearest pediatric tertiary care center