Category Archives: PHARM

Prehospital and Retrieval Medicine

All Updates, PHARM, Resus, Trauma

Open thoracostomy

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Not a new paper to cite here, just a collection of resources that refer to open thoracostomy in trauma.
A longstanding practice by some European and Australasian HEMS physicians, open thoracostomy is essentially a chest tube procedure without the actual intercostal catheter: the surgical incision is made, blunt dissection is performed, and the pleura penetrated. The wound is then left open.
This is a rapid way of decompressing a tension pneumothorax in a critically injured trauma patient who is intubated. The positive pressure ventilation prevents the thoracostomy wound from acting as an open, ‘sucking’, chest wound.
In many pre-hospital services this is the preferred approach to pleural decompression in an intubated patient, and also forms part of the approach to resuscitation in traumatic cardiac arrest.
Some principles to consider are:

  • A tube and drainage system are not necessary for the drainage of air, but should be used if there is signficant haemothorax
  • The tissues may re-appose during transport so physiological deterioration should prompt a re-fingering of the thoracostomy to re-establish the drainage tract and allow air to escape
  • Standard intravenous cannula devices may be shorter than the distance from chest wall to pleural space in many adults, adding to the inadequacy of needle decompression
  • Signs of tension pneumothorax are rarely if ever as obvious as the textbooks suggest – unexplained shock or hypoxaemia in a patient with actual or probably thoracic trauma should prompt consideration of pleural decompression even in the absence of obvious clinical signs of pneumothorax – subtle evidence only may exist, such as palpable subcutaneous emphysema
  • This should only be done in intubated patients undergoing positive pressure ventilation!

This video shows the procedure, done by a relative beginner; a slightly larger incision with more assertive dissection would make it faster and more effective

Not yet heard Scott Weingart’s excellent podcast on traumatic arrest, which includes open, or ‘finger’, thoracostomy? You can find it here
Thoracostomy references

Simple Thoracostomy Avoids Chest Drain Insertion in Prehospital Trauma
J Trauma 1996 39(2):373-374
Simple thoracostomy in prehospital trauma management is safe and effective: a 2-year experience by helicopter emergency medical crews
European Journal of Emergency Medicine 2006, 13:276–280
Prehospital thoracostomy
European Journal of Emergency Medicine 2008, 15:283–285
Chest decompression during the resuscitation of patients in prehospital traumatic cardiac arrest
Emerg. Med. J. 2009;26;738-740
Life-saving or life-threatening? Prehospital thoracostomy for thoracic trauma
Emerg Med J 2007;24:305–306
Pre-Hospital and In-Hospital Thoracostomy: Indications and Complications
Ann R Coll Surg Engl. 2008 January; 90(1): 54–57
Needle decompression is inadequate:
Needle Thoracostomy in the Treatment of a Tension Pneumothorax in Trauma Patients: What Size Needle?
J Trauma. 2008;64:111–114
Pre-hospital management of patients with severe thoracic injury
Injury 1995 26(9):581-5

All Updates, PHARM, Trauma

Pre-hospital iv and increased mortality

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The US media seem to be making a big thing of a recent article published ahead of print which demonstrates an association between increased mortality from trauma and the insertion of an intravenous line with or without the administration of fluid.
This was a retrospective cohort study of over 770 000 patients from the National Trauma Data Bank. Approximately half (49.3%) received ‘prehospital IV’, which could mean fluids, or could just mean insertion of an intravenous cannula: ‘we could not definitively differentiate IV fluid administration versus IV catheter placement alone‘.
Unadjusted mortality was significantly higher in patients in the prehospital IV group, although the abstract inaccurately reports this to be ‘in patients receiving prehospital IV fluids‘ (4.8% vs. 4.5%, P < 0.001).
Multivariable logistic regression was used to examine the relationship between prehospital IV and mortality in the 311,071 patients with complete data. After adjustment, prehospital IV patients had significantly higher mortality than those without a prehospital IV. The odds ratio of death associated with prehospital IV placement was 1.11 (95% CI 1.06–1.17). When Dead-On-Arival patients were excluded from the group as a whole, the association persisted (OR 1.17, 95% CI 1.11–1.23).

Hey you're killing me here!

On subgroup analyses, the association between IV placement and excess mortality was maintained in nearly all patient subsets; the effect was more exaggerated in penetrating trauma victims.
Media speculation as to the reason for this association abounds, like USA Today‘s ‘those who are given pre-hospital IV fluids are actually 11% more likely to die than those who aren’t, not only because of transport delays but also in part because of the increased risk for bleeding that can accompany a fluid-induced increase in blood pressure‘. However the study did not record any pre-hospital times and could not tell which patients received fluid, let alone what the effect of fluid on blood pressure was.
The authors are open about this and other limitations: ‘The NTDB did not report prehospital transport times or differentiate urban versus rural care. Thus, we could not examine whether excess mortality in patients treated with IVs was directly associated with delays in transport to definitive care. We were also not able to control for transport time within the multiple regression model or perform a stratified analysis by urban versus rural patients. Perhaps this analysis would have identified a subset of patients who may benefit from IV placement‘.
No doubt this will be added to the pile of mainly hypothesis-generating literature quoted by the scoop-and-run brigade whose black-and-white worldview includes paramedics who want to delay proper treatment and a homogeneous trauma population whose lives can only be saved by a trauma surgeon in a hospital. Those who have evolved colour vision find this an interesting, but hardly practice-changing study; caution regarding injudicious fluid administration has been the game plan for many civilian and military pre-hospital providers since early last decade, and it is clear that different patients with different injury patterns, different degrees of physiological derangement, and different distances from the right hospital will continue to have different clinical needs specific to their presentation, some of which are likely to be of benefit if provided in the field, through an intravenous line.
Prehospital Intravenous Fluid Administration is Associated With Higher Mortality in Trauma Patients: A National Trauma Data Bank Analysis
Ann Surg. 2010 Dec 20. [Epub ahead of print]

Acute Med, All Updates, PHARM, Resus

Body position in poisoning

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You come across a patient in the community who has taken an overdose of pills. The ambulance is on its way and you have no medical equipment. Is there any first aid that might help? How should you position the patient if they are unconscious?

Authors of a BestBet in the EMJ searched the literature to answer the three-part question:
In [orally poisoned patients] does [a specific body position] result in [a better outcome for the patient]?

The limited evidence they found from just two papers suggests that drug absorption is lowest in patients lying on their left side, so you might want to consider placing an unconscious overdose patient in the left-sided recovery position prior to definitively managing them in hospital. The theoretical increased risk of pulmonary aspiration on the left side should be considered however. The table shows just how limited this evidence base is – but the idea is an interesting one.

Optimal body position in oral poisoning cases
Emerg Med J 2010;27:952-953 Full text from the BestBets site

All Updates, ICU, PHARM, Resus

Bleeding Tracheostomy

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Adapted from the UK Intensive Care Society’s ‘Standards for the care of adult patients with a temporary tracheostomy

Bleeding from an established tracheostomy (ie. ‘late bleeding’, as to opposed to peri-operative bleeding that is more common and often benign) may occur because of erosion of blood vessels in and around the stoma site. This is more likely if there has been infection of the stoma site. Such bleeding may settle with conservative management. More worryingly, however, is the prospect of such bleeding being the result of erosion of a major artery in the root of the neck where there has been pressure from the tracheostomy tube itself or the cuff tube. Most commonly, this erosion occurs into the right brachiocephalic artery (also known as the innominate artery), resulting in a tracheo-innominate artery fistula. This situation may be heralded in the preceding hours by a small, apparently insignificant, sentinel bleed. Bleeding from such a fistula will be massive. THIS IS A LIFE-THREATENING EMERGENCY and so decisions need to be rapidly made.

  1. Call for help– senior medical and nursing staff, other health professionals with tracheostomy care skills (e.g. respiratory therapist, physiotherapist).
  2. Clear airway – blood clots may need to be suctioned.
  3. Replace blood products as required
  4. Bleeding may be temporarily reduced or stopped by applying finger pressure to the root of the neck in the sternal notch, or by inflating the tracheostomy tube cuff (if present) with a 50ml syringe of air. This inflation should be done slowly and steadily to inflate the balloon to a maximum volume without bursting it. Depending on the type and size of the tracheostomy tube this may be anywhere between 10 and 35 ml.
  5. Urgent referral for surgical exploration must now be made, if not already done so. In addition to an ENT or maxillofacial surgeon, it may be necessary to get help from a vascular surgeon. Sometimes, the damage can only be repaired utilising cardio-pulmonary bypass, and so a cardiothoracic surgeon may also be needed to help.
  6. Consider palliation – it is well recognised that fatalities occur in this situation, and that this may be the mode of death for some patients with head and neck cancers
Acute Med, All Updates, ICU, PHARM, Resus

Tracheostomy resources

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The National Tracheostomy Safety Project at www.tracheostomy.org.uk in the UK aims to allow patients with tracheostomies or laryngectomies to be safely cared for in hospitals.
The site contains a wealth of educational resources of use to the critical care practitioner. For example, have you thought about what do with a laryngectomy patient who presents with dyspnoea, or even apnoea? Remember that although applying oxygen to the face & neck is a default emergency action for all patients with a tracheostomy, these patients cannot be intubated and ventilated through the normal oral route since their tracheostomy is an end stoma – it does not communicate with the mouth:

Compare this with the algorithm for other patients with a tracheostomy, in whom attempts to oxygenate and ventilate, including intubation, can be made in an emergency either from the ‘top end’ (mouth) or via the stoma:

There are also a number of multimedia resources and a link to the UK Intensive Care Society’s Tracheostomy Guidelines

All Updates, ICU, PHARM, Resus, Trauma

A tracheal tube in the chest

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Intercostal catheters can kink, obstruct, or get pulled out. These hazards are greater during transport of the patient. Critical care and retrieval medicine doctors in Queensland, Australia (where many people are having a bad time right now) have invented an elegant alternative: using a cuffed tracheal tube in the pleural space instead. It can be attached to a Heimlich valve.
They even used a bit of science to demonstrate its effectiveness, by creating pneumothoraces and haemothoraces in sheep and comparing the tracheal tube with a standard intercostal catheter (ICC).
The method for insertion is simple:

  1. Breach the pleura
  2. Insert a 14 Fr Cook intubating bougie into the thoracic cavity
  3. Railroad a 7.0 mm internal diameter tracheal tube (ETT) into the chest cavity
  4. Inflate the cuff
  5. Retract the tube until resistance is felt.
  6. Remove the ETT connector
  7. Attach a Heimlich valve

The results of the comparison are convincing: ‘The ETT proved faster to insert for both sheep. This was likely because it did not require suturing. Both the ETT and the ICC were comparable in draining blood. It was noted that neither tube was particularly effective when the haemothorax was positioned ‘side-up’. When turned ‘side-down’, both tubes successfully drained blood. Despite having multiple drainage ports, the ICC required more manipulation and was noted to kink. Conversely, the ETT with a single lumen and a Murphy eye, was stiffer and drained a similar amount of blood without the catheter having to be milked.’
Proposed advantages of this method include:

  • More portable equipment
  • Faster insertion
  • Provides kit redundancy
  • Does not require suturing
  • Avoids operator trauma from any sharp edges such as a fractured rib. (No attempt was made to place a finger into the chest cavity in the ETT group).
  • Allows for a smaller incision
  • Less trauma to the insertion site
  • Might also offer a back up, when conventional equipment has been exhausted.

The authors graciously note that both Portex and Cook have developed ICC kits that now go some way in supporting the original idea behind this study. These include flexible introducers (Portex) and guidewire insertion technique (Cook).
Appraisal of the endotracheal tube as an alternative to the intercostal catheter
Emerg Med Australas. 2010 Dec;22(6):573-4

All Updates, ICU, PHARM, Resus

Cuff pressures and tracheal injury

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We all intubate patients with cuffed tubes, but we’re far too busy and important to fart around measuring tracheal tube cuff pressures when we’re saving lives right? Surely something the ICU nurses can sort out between ‘eye care’ and swabbing for MRSA.
The modern ‘high volume low pressure’ cuff has certainly led us to worry less about cuff pressures, and in frontline critical care specialties like emergency medicine and pre-hospital and retrieval medicine it’s the last thing on our minds. However we should consider the accumulating pool of evidence that tells us:

  1. Physicians are hopelessly poor at estimating cuff pressures based on palpating the pilot balloon
  2. Cuff pressures are frequently very high
  3. Tracheal mucosal injury can occur even after short term intubation (a few hours)
  4. When the pressure in the cuff exceeds 22 mm Hg, blood flow in the tracheal mucosa begins decreasing
  5. Tracheal mucosal blood flow reduces markedly when the pressure reaches 30 mm Hg
  6. When the pressure in the cuff reaches 50 mm Hg for 15 minutes, ischemic injury to the tracheal mucosa can occur

Patchy hemorrhagic ulceration in tracheal mucosa

A study from China tested the hypothesis that an appropriate tracheal tube cuff (ETTc) pressure even in short procedures would reduce endotracheal intubation–related morbidity. They compared bronchoscopic appearance of tracheal mucosa, and patient symptoms of tracheal injury, in two groups of elective surgical patients anaesthetised and intubated between 120 and 180 minutes: a control group without measuring ETTc pressure, and a study group with ETTc pressure measured and adjusted to a range 15-25 mmHg. The endoscopist was blinded to the study group allocation.

The mean ETTc pressure measured after estimation by palpation of the pilot balloon of the study group was 43 +/- 23.3 mm Hg before adjustment (the highest was 210 mm Hg), and 20+/- 3.1 mm Hg after adjustment (p< 0.001). The incidence of postprocedural sore throat, hoarseness, and blood-streaked expectoration in the control group was significantly higher than in the study group. As the duration of endotracheal intubation increased, the incidence of sore throat and blood-streaked expectoration in the control group increased. The incidence of sore throat in the study group also increased with increasing duration of endotracheal intubation. Fiberoptic bronchoscopy showed that the tracheal mucosa was injured in varying degrees in both groups, but the injury was more severe in the control group than in the study group.
So..time to get a cuff manometer for your ED or helicopter? Perhaps you already have one. What do you think?
Correlations Between Controlled Endotracheal Tube Cuff Pressure and Postprocedural Complications: A Multicenter Study
Anesth Analg. 2010 Nov;111(5):1133-7
Related posts:
Cuff pressure in flight
Paediatric cuff pressures

All Updates, ICU, Kids, PHARM

Better outcome with paediatric retrieval teams

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Data from the England and Wales Paediatric Intensive Care Audit Network on children (aged 16 years or younger) admitted to 29 regional paediatric intensive care units (PICUs) between 1 January 2005 and 31 December 2008 were analysed in a retrospective cohort study to assess the effectiveness of the specialist retrieval teams.

The type of transferring team (specialist or non-specialist) was known for 16 875 cases and was specialist in 13 729 (81%). Compared with children transferred to PICUs from within the same hospital, children transferred from other hospitals were younger (median age 10 months vs 18 months), more acutely ill (mortality risk 6% vs 4% using the Paediatric Index of Mortality), needed more resources (such as invasive ventilation, vasoactive drugs, renal replacement therapy, extracorporeal membrane oxygenation and/or multiple-organ support), had longer stays in the PICU (median 75 h vs 43 h) and had a higher crude mortality (8% vs 6%). On multivariable analysis after adjustment for case mix and organisational factors, the risk of death among interhospital transfers was significantly (35%) lower than among intrahospital transfers. With similar analysis, the times spent in PICU did not differ significantly between these two groups. When the type of transferring team was considered, crude mortality was similar with specialist and non-specialist teams, although the children transferred by the specialist teams were more severely ill. On multivariable analysis, the risk of death was 42% lower with specialist team transfer.
These findings appear to confirm the value of specialist retrieval teams. Why children transferred from other hospitals did better than children transferred to the PICU in the same hospital is not explained.
Effect of specialist retrieval teams on outcomes in children admitted to paediatric intensive care units in England and Wales: a retrospective cohort study
Lancet. 2010 Aug 28;376(9742):698-704

All Updates, ICU, PHARM, Resus, Trauma

Less smelly than chicken drumsticks

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Emergency and orthopaedic doctors Elizabeth and Anthony Bateman from Britain describe their method of making a bone simulator for intraosseous cannulation training:

  • Take up to one Crunchie bar per trainee (leave in wrapper!) – this simulates the cancellous bone that is cannulated.
  • Tightly plaster cast with four layers of polyester cast tape (12.5 cm width matches closely to Crunchie bar length), cutting lengths of the cast tape as needed prior to immersing in water – this simulates the hard cortical bone.
  • Foam padding, or two layers of wool band from the plaster room, can be added to simulate soft tissue.


A quick google reveals it can be a challenge getting Crunchie bars in the United States. Maybe there’s a suitable honeycomb-centred alternative. If not you can resort to ordering them from Amazon.
Intraosseus access simulation: the Crunchie solution
Emerg Med J. 2010 Dec;27(12):961

All Updates, ICU, PHARM, Resus, Trauma

Paramedic RSI in Australia

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A prospective, randomized, controlled trial compared paramedic rapid sequence intubation with hospital intubation in adults with severe traumatic brain injury in four cities in Victoria, Australia. The primary outcome was neurologic outcome at 6 months postinjury.
Training
Paramedics already experienced in ‘cold’ intubation (without drugs) undertook an additional 16-hour training program in the theory and practice of RSI, including class time (4 hours), practical intubating experience in the operating room under the supervision of an anesthesiologist (8 hours), and completion of a simulation-based examination (4 hours).
Methods
Patients included in the study were those assessed by paramedics on road ambulances as having all the following: evidence of head trauma, Glasgow Coma Score ≤9, age ≥15 years, and ‘intact airway reflexes’, although this is not defined or explained. Patients were excluded if any of the following applied: within 10 minutes of a designated trauma hospital, no intravenous access, allergy to any of the RSI drugs (as stated by relatives or a medical alert bracelet), or transport planned by medical helicopter. Drug therapy for intubation consisted of fentanyl (100μg), midazolam (0.1 mg/kg), and succinylcholine (1.5 mg/kg) administered in rapid succession. Atropine (1.2 mg) was administered for a heart rate <60/min. A minimum 500 mL fluid bolus (lactated Ringers Solution) was administered. A half dose of the sedative drugs was used in patients with hypotension (systolic blood pressure <100 mm Hg) or older age (>60 years).

Cricoid pressure was applied in all patients. After intubation and confirmation of the position of the endotracheal tube using the presence of the characteristic waveform on a capnograph, patients received a single dose of pancuronium (0.1 mg/kg), and an intravenous infusion of morphine and midazolam at 5 to 10 mg/h each. If intubation was not achieved at the first attempt, or the larynx was not visible, one further attempt at placement of the endotracheal tube over a plastic airway bougie was permitted. If this was unsuccessful, ventilation with oxygen using a bag/mask and an oral airway was commenced and continued until spontaneous respirations returned. Insertion of a laryngeal mask airway was indicated if bag/mask ventilation using an oral airway appeared to provide inadequate ventilation. Cricothyroidotomy was indicated if adequate ventilation could not be achieved with the above interventions. In all patients, a cervical collar was fitted, and hypotension (systolic blood pressure <100 mm Hg) was treated with a 20 mL/kg bolus of lactated Ringers Solution that could be repeated as indicated. Other injuries such as fractures were treated as required. In the hospital emergency department, patients who were not intubated underwent immediate RSI by a physician prior to chest x-ray and computed tomography head scan.
Follow up
At 6 months following injury, surviving patients or their next-of-kin were interviewed by telephone using a structured questionnaire and allocated a score from 1 (deceased) to 8 (normal) using the extended Glasgow Outcome Scale (GOSe). The interviewer was blinded to the treatment allocation.
Statistical power
A sample size of 312 patients was calculated to achieve 80% power at an alpha error of 0.05. Three hundred twenty-eight patients met the enrollment criteria. Three hundred twelve patients were randomly allocated to either paramedic intubation (160 patients) or hospital intubation (152 patients). A mean Injury Severity Score of 25 indicated that many patients had multiple injuries.
Success of intubation
Of the 157 patients administered RSI drugs, intubation was successful in 152 (97%) patients. The remaining 5 patients had esophageal placement of the endotracheal tube recognized immediately on capnography. The endotracheal tube was removed and the patients were managed with an oropharyngeal airway and bag/mask ventilation with oxygen and transported to hospital. There were no cases of unrecognised esophageal intubation on arrival at the emergency department during this study and no patient underwent cricothyroidotomy.
Outcome
After admission to hospital, both groups appeared to receive similar rates of neurosurgical interventions, including initial CT scan, urgent craniotomy (if indicated), and monitoring of intracranial pressure in the intensive care unit.
Favorable neurologic outcome was increased in the paramedic intubation patients (51%) compared with the hospital intubation patients (39%), just reaching statistical significance with P = 0.046. A limitation is that 13 of 312 patients were lost to follow-up and the majority of these were in the hospital intubation group. The authors do point out that the difference in outcomes would no longer be statistically significant whether one more patient had a positive outcome in the treatment group (P = 0.059) or one less in the control group (P = 0.061). The median GOSe was higher in the paramedic intubation group compared with hospital intubation (5 vs. 3), however, this did not reach statistical significance (P = 0.28).
More patients in the paramedic intubation group suffered prehospital cardiac arrest. There were 10 cardiac arrests prior to hospital arrival in the paramedic RSI group and 2 in the patients allocated to hospital intubation. Further detail on these patients is provided in the paper. The authors state that it is likely that the administration of sedative drugs followed by positive pressure ventilation had adverse hemodynamic consequences in patients with uncontrolled bleeding, and that it is possible that the doses of sedative drugs administered in this study to hemodynamically unstable patients were excessive and consideration should be given to a decreasing the dose of sedation.
Authors’ conclusions
The authors overall conclusion is that patients with severe TBI should undergo prehospital intubation using a rapid sequence approach to increase the proportion of patients with favorable neurologic outcome at 6 months postinjury. Further studies to determine the optimal protocol for paramedic rapid sequence intubation that minimize the risk of cardiac arrest should be undertaken.
Prehospital rapid sequence intubation improves functional outcome for patients with severe traumatic brain injury: a randomized controlled trial.
Ann Surg. 2010 Dec;252(6):959-65.
Victorian Ambulance Service protocols are available here, which include their current paramedic RSI protocol