A case report of peripheral neuropathy as a complication of diabetic ketoacidosis in a child with newly diagnosed diabetes type 1

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Created On: 03/02/2020

A case report of peripheral neuropathy as a complication of diabetic ketoacidosis in a child with newly diagnosed diabetes type 1

A 9-year-old girl with newly diagnosed Type 1 DM, DKA, brain oedema, multifocal vasogenic brain lesions and lower limb paresis was presented for treatment. She had reported polydipsia and polyuria over the past week and weight loss of 3 kg over the last month with severe dehydration. She experienced agitation and motor restlessness followed by upper limb spasms. CT scan revealed a hypodense lesion in the left temporal region and brain oedema. Nerve conduction studies showed dysfunction in both the right tibial nerve and peroneal nerves, which results in damage of motor neurons in both lower limbs.

What will most likely explain the pathogenesis of acute neuropathy in this case?

Diabetic ketoacidosis
Peripheral ischemia

Neuropathy associated with diabetic ketoacidosis is rare. It presents severe clinical complications. The most common complication is brain oedema, specifically related to central nervous system (CNS) which is prevalent in approximately 0.5-1% of cases with diabetic ketoacidosis (DKA) and has a 20% mortality rate. Other less frequent complications are hemorrhagic and ischemic strokes, accounting for 10% of intracerebral complications. Among all these complications, sinus thrombosis and cerebral vein are less frequent than brain oedema.

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Key take away

In a child with newly diagnosed diabetes type 1 the diabetic ketoacidosis led to neuropathy. The Alpha-lipoic acid and vitamins B1, B6 and B12 were initiated to manage the neuropathy and for ketoacidosis, the patient was kept under careful observation.

Medical history

Examination & lab investigations

The laboratory examination included evaluation of Blood glucose levels (mg/dL), Osmolarity levels (mOsm/kg H₂O), Base excess (mEq/L), Corrected sodium levels (mmol/L), Potassium levels (mmol/L), Phosphate levels (mmol/L), CRP levels (mg/dL), D-dimer levels(ug/L), Fibrinogen levels(g/L). Other investigations made were Computed Tomography Scan, Brain Magnetic Resonance Imaging and lower limb nerve conduction studies.

The blood glucose level initially was found to be 1136 mg/dL, and severe acidosis was also present (pH 7.1; BE-25.9). Intravenous fluid therapy and insulin therapy did not show any improvement in her medical and neurological state. Glasgow Coma Scale (GCS) scores depleted from 13 points to 7 points. CT scan showed hypodense lesion in the left temporal region and brain oedema. An anti-edematous treatment helped to improve her medical condition, but she had developed symmetric lower limbs paresis. Brain MRI and nerve conduction studies indicated numerous, diffuse lesions and damaged motor neurons in both lower limbs.

Management

Treatment included intravenous initial fluid therapy containing 1250 mL 0.9% sodium chloride (NaCI) and 1000 mL of 5% dextrose with 0.9% NaCl (2:1 proportion, sodium concentration-51.34 mEq/L) to restore fluid loss due to excessive dehydration. Insulin was infused at a slower rate to prevent a rapid decrease in glycaemia. No improvement was observed in patient medical condition. After CT scan, an anti-edematous therapy with mannitol 0.3 g/kg/dose, three times a day was introduced for brain oedema; also alpha lipoic acid, vitamins B1, B6 and B12 were added to the therapeutic regimen that helped in improving her medical condition. The patient's health gradually improved with treatment and physiotherapy.

Discussion

Diabetic neuropathy affects approximately 54-59% patients with T1DM and 45% of patients with T2DM. It is the most common complication of diabetes mellitus and viewed as an independent entity comprising many types of nerve dysfunction due to various symptoms, clinical courses and pathogenic mechanisms. About 80% of patients with symptomatic DN suffers from various generalised symmetric, chronic polyneuropathy including motor, sensory and autonomic nerve dysfunctions. In most of the cases, DN develops in patients with hyperglycemia. Evidence report the occurrence of neuropathy related to newly diagnosed DM1. It can be classified as hyperglycemic neuropathy, acute painful DN, and neuropathy after ketoacidosis. Asymptomatic as well as symptomatic changes were observed in nerve function at the time of DM1 diagnosis.

Previous studies suggested that diabetes mellitus was responsible for mononeuropathy as the onset of neuropathy and motor dysfunction was dependent on the start of DM1 and glycemic control respectively. In the present case, patient suffered from acute motor peripheral neuropathy which may occur as a result of the peripheral ischemia, haemodynamic and metabolic changes associated with ketoacidosis.

One hypothesis explains that the procoagulent state during DKA may lead to nerve damage through dysfunction in vascular endothelial, which is the first line of defense against thrombosis. Endothelial dysfunction results in the activation of coagulation factor and platelet. Elevated levels of fibrinogen, factors VII, VIII, XI, XII and von Willebrand were found in DKA. Disrupted anticoagulant mechanisms such as a low protein C level can lead to worsening of a procoagulant state. Impairment of fibrinolysis may occur due to various factors such as an increased concentration of plasminogen activator inhibitor type 1 and more severe degradation of the thrombi. There was an elevation in d-Dimer levels as indicated by the study, but there is a need for further diagnostic tests.

In the present case study, other etiologies of neuropathy, such as hypophosphatemia were also observed and considered during admission to hospital. Hypophosphatemia is generally asymptomatic, but its severity can cause peripheral polyneuropathy that can be both sensory and motor. After normalisation of the phosphate levels, neurological symptoms remains that suggests another alternative mechanism for the pathogenesis of neuropathy.

Diabetic neuropathy treatment includes the use of strong antioxidants such as alpha lipoic acid. The efficacy of this therapy has been proved in the meta analysis. The use of Benfotiamine, a derivative of vitamin B1, is also utilised, although less effective than alpha lipoic acid.

Learning

Neuropathy can be developed any time after or even before Diabetes mellitus diagnosis. Acute neuropathy after ketoacidosis is rare, but its cause is not apparent yet. It is suggested that patients with DKA need careful monitoring of neurological conditions even after normalization of glycemic parameters.

References

Edge JA, Hawkins MM, Winter DL, Dunger DB. The risk and outcome of cerebral oedema developing during diabetic ketoacidosis. Archives of Disease in Childhood 2001;85:16-22.
Dunger DB, Sperling MA, Acerini CL, Bohn DJ, Daneman D, Danne TP, Glaser NS, Hanas R, Hintz RL, Levitsky LL, Savage MO, Tasker RC, Wolfsdorf JI; ESPE; LWPES. ESPE/LWPES consensus statement on diabetic ketoacidosis in children and adolescents. Arch Dis Child 2004;89:188-194.
Bialo SR, Agrawal S, Boney CM, Quintos JB. Rare complications of pediatric diabetic ketoacidosis. World J Diabetes 2015;6:167-174.
Zilliox L, Russell JW. Treatment of Diabetic Sensory Polyneuropathy. Curr Treat Options Neurol 2011;13:143-159.
Tesfaye S, Boulton AJ, Dyck PJ, Freeman R, Horowitz M, Kempler P, Lauria G, Malik RA, Spallone V, Vinik A, Bernardi L, Valensi P; Toronto Diabetic Neuropathy Expert Group. Diabetic Neuropathies: Update on Definitions, Diagnostic Criteria, Estimation of Severity, and Treatments. Diabetes Care 2010;33:2285-2293.
Rangel MA, Baptista C, Santos F, Real MV, Campos RA, Leite AL. Acute mononeuropathy in a child with newly diagnosed type 1 diabetes mellitus. J Pediatr Endocrinol Metab 2015;28:341-344.
Tracy JA, Dyck PJ. The Spectrum of Diabetic Neuropathies. Phys Med Rehabil Clin N Am 2008;19:1-26.
Carr ME. Diabetes mellitus - A hypercoagulable state. J Diabetes Complications 2001;15:44-54.
Foster JR, Morrison G, Fraser DD. Diabetic Ketoacidosis-Associated Stroke in Children and Youth. Stroke Res Treat 2011;2011:219706.
Ziegler D, Nowak H, Kemplert P, Vargha P, Low PA. Treatment of symptomatic diabetic polyneuropathy with the antioxidant alpha-lipoic acid: a meta-analysis. Diabetic Med 2004;21:114-121.
Mijnhout GS, Kollen BJ, Alkhalaf A, Kleefstra N, Bilo HJ. Alpha Lipoic Acid for Symptomatic Peripheral Neuropathy in Patients with Diabetes: A Meta-Analysis of Randomized Controlled Trials. Int J Endocrinol 2012;2012:456279.