Bradycardia and hypotension have been observed in a large number of patients after spinal cord injury specially injuries involving the level of C5 or above (
2). In this article we reported a patient with bradycardia and hypotension due to cervical spinal cord injury which was successfully treated with midodrine and aminophylline.
There is limited data regarding the use of methylxanthines for the management of cervical spine injury related bradycardia. In 2005, Schulz-Stübner reported three patients with bradycardia due to spinal cord injury that were successfully treated with methylxanthines (intravenous aminophylline or oral theophylline). In two of the patients theophylline was used as a second line therapy after administration of anti-cholinergic agents (atropine and glycopyrolates) and the third patient received methylxanthine as a first line agent. Additionally, Theophylline therapy was associated with increased respiratory drive and minute ventilation in the treated patients. No serious adverse effects regarding methylxanthine administration were reported and the theophylline serum concentrations in all of the patients were below 3.4 mg/L (one case didn’t have theophylline plasma levels) (
6). In 2004, Pasnoori reported two patients with acute cervical spinal cord injury who had bradycardia resistant to atropine. They successfully managed these patients using intravenous aminophylline (
5). In 2007, Sakamoto described that sequential use of aminophylline and theophylline was effective and safe for the management of spinal cord injury induced bradycardia in one Japanese man whose bradycardia was refractory to atropine (
7). In 2008, Whitman
et al. described a patient with recurrent symptomatic bradycardia secondary to high cervical spinal cord injury who was treated successfully with administration of intravenous aminophylline.
The theophylline plasma levels were 1.9-3.4 mg/L (
8). In 2007, Weant
et al. showed the effectiveness and safety of oral theophylline for the treatment of cervical spine injury induced symptomatic bradycardia and asystole in one patient. The patient′s serum theophylline concentrations were ≤ 3.2 mg/L (
9). In 2010, Sadaka
et al. published one case series including 6 cervical spine cord injury cases with bradycardia who were successfully managed with the administration of oral theophylline (via nasogastric tube). Oral theophylline was effective in all patients and no serious adverse effects were observed. Theophylline was used in four patients as a second line or adjunct therapy and in two patients as first line therapy. The theophylline plasma levels throughout the therapy in all patients were ≤7.6 mg/L (below the toxic range) (
2).
There is limited data on the use of midodrine for management of hypotension secondary to spine injury. Midodrine as a selective oral alpha1-receptor agonist has been used for the treatment of spinal cord injury induced orthostatic hypotension in a few cases.
Nieshoff
et al. in one double-blind, placebo-controlled, randomized trial on four patients suffering from cervical spine injury demonstrated that midodrine 10 mg orally was effective and safe for the management of orthostatic hypotension in this population (
10). In 1991, Senard
et al. reported that midodrine 10 mg orally has been beneficial for the treatment of orthostatic hypotension due to spine injury in one patient (
11). In 2000, Barber
et al. also described two patients with spinal cord injury related orthostatic hypotension that were successfully treated with midodrine (
12). In 2001, Mukand
et al. showed that midodrine was effective and safe for maintaining blood pressure and reducing orthostatic symptoms in one patient with cervical spine injury induced orthostatic hypotension (
13). In a prospective dose-response trial on ten patients with chronic cervical spine injury in 2010, Wecht
et al. suggested that midodrine 10 mg could be considered for the treatment of hypotension and orthostatic hypotension in this population (
14). In 2014, Phillips
et al. demonstrated that midodrine may improve orthostatic hypotension and cerebral blood flow velocity of the posterior cerebral artery in ten patients with history of spinal cord injury (
15).
In our case we managed post cervical spine injury associated bradycardiaand hypotension in a fluid unresponsive patient with aminophylline and midodrine. Dopamine drip was changed to oral midodrine after 3 days of dopamine infusion. We did not measure aminophylline serum concentration; on the other hand we did not observe any adverse effect related to aminophylline or midodrine and the patient was successfully treated. In all above mentioned studies theophylline serum concentrations were below lower limit of therapeutic range (therapeutic range: 10-20 mg/L) and not only all the patients were successfully managed, but also none of them suffered from any serious adverse effects. Therefore, low doses of methylxanthines and midodrine have been shown to be safe and effective in post spine injuries.
The patients with acute spinal injury may have disturbances in the absorption of medication from gastrointestinal tract that may affect pharmacokinetic and plasma concentration of the drugs. However, it has been shown that oral administration of theophylline was effective in case reports which were published by Schulz-Stübner, Sakamoto, Weant et al. and Sadaka et al. Midodrine also has been used orally in this population in some cases and its efficacy in elevation of blood pressure was
demonstrated.
| Day 1 Admission to the ICU | Day 3On Aminophylline and dopamine | Day4Off dopamine On Aminophyllineand midodrine | Day 5On midodrine | Day 35, Discharge to the wardOn midodrine |
|---|
| HgB | 9.9 | 9.6 | 9.7 | 9.5 | 10.1 |
| Na | 130 | 137 | 140 | 141 | 140 |
| K | 4.3 | 3.5 | 4 | 4.2 | 4.1 |
| BUN | 15 | 17 | 17 | 15 | 19 |
| SrCr | 0.69 | 0.8 | 0.8 | 0.9 | 0.7 |
| BP | 99/45 | 126/72 | 120/70 | 118/65 | 137/73 |
| HR | 50 | 76 | 70 | 65 | 73 |
| RR | 14 | 16 | 15 | 15 | 16 |