Hi everyone!

Welcome back to Trauma Tuesday! Today's POTD will be on splenic injuries, inspired by a question I got wrong on NY ACEP bizz buzz board review. Did you know splenic injuries are the most commonly injured organ in blunt abdominal trauma (BAT)? I didn't. And just like that, my dreams of showing up on the Kahoot leader board were destroyed (though I'm sure all the other questions I got wrong before that didn't help).

Background: In BAT, the spleen is the most commonly injured intraabdominal organ, followed by the liver and kidneys. BAT leads to injury through shearing (rapid deceleration between fixed vs unfixed points of organs; think our aortic friend last week when we covered aortic transection), crushing (organs getting crushed between its neighboring organs, abdominal wall, or bony structures like ribs and vertebrae), and external compression forces (physical force pushing against abdomen leading to rise in intraabdominal pressure).

Workup and initial ED management:

At its core, assessing for splenic injury in blunt abdominal trauma falls under the ATLS algorithm.

ABCs come first, as always. IV x 2, O2, monitor. Rainbow labs, T+S. CXR and PXR. Fluids and blood as needed. Pain control. Though we are talking about BAT, usually force significant enough to cause intraabdominal injury is associated with intracranial, cervical spine, intrathoracic, and extremity injury. Perform your primary survey as normal and resuscitate as usual.

Your EFAST and vitals will determine what happens next to the patient. Unstable vitals and positive free fluid in abdomen? The patient needs the OR. When dealing with a splenic injury, you may note a few findings on your LUQ US during your efast: you may see free fluid in the LUQ, signs of a hematoma, or no findings on LUQ view but positive free fluid in RUQ.

However, a negative eFAST does not exclude splenic injury.

Clues on your physical exam that you may be dealing with a splenic injury include a positive seatbelt sign, tenderness or pain over LUQ, left flank, and kehr sign (referred pain to tip of left shoulder from blood in the peritoneal cavity, performed on supine patient and elevating legs, suggestive of splenic rupture). There may also be no findings on physical exam.

If the patient is stable, next step is CT scan with IV contrast, the results of which allow grading of splenic injury. Splenic injuries can also be graded in the OR if the patient went straight to exlap instead.

American Association for Surgery of Trauma (AAST) Splenic Injury Grading I-V:

https://media.springernature.com/lw785/springer-static/image/prt%3A978-3-642-00418-6%2F19/MediaObjects/978-3-642-00418-6_19_Part_Fig1-517_HTML.gif

Management:

The grade of splenic injury is one of several factors dictating management. There are several options available including operative, embolization, and nonoperative management. Most (up to 80%) of these patients can be managed effectively nonoperatively. As general rules, the patient who is circling the hemodynamic drain, required more than two units of blood, or is showing signs of continued bleeding, requires intervention.

Operative Management:

Used in patients with hemodynamically instability, evidence of peritonitis, pseudoaneurysm formation, and associated intraabdominal injuries requiring operative repair, such as bowel injuries. Goal is to preserve as much spleen as possible, though splenectomy is definitive treatment.

Embolization:

Consider in cases with contrast extravasation on CT scan, moderate hemoperitoneum, signs of ongoing bleeding. Embolization is associated with complications, such as devascularization of spleen defined as infarction in more than 25% of spleen, re-hemorrhage, and abscess formation.

Nonoperative management:

Consider in the hemodynamically stable patient without evidence of bleeding or peritonitis. Usually grade 1-2 injuries, though has been used for patients with higher grade injuries. These patients are admitted with monitoring and serial abdominal exams/CT scans, with urgent exlap possible if needed. Nonoperative management has a failure rate of 10-50%, and these patients continue onto the operative/embolization route.

Be wary of patients returning to ED following an admission for splenic injury/BAT!

*Beware the delayed splenic rupture: Can occur up to 10 days after initial injury. Oftentimes a result of of a small injury not visualized on imaging. Other complications may include rebleeding, pseudoaneurysm formation of splenic artery, abscess, pancreatitis, and infection, especially if patient received splenectomy.

Happy Tuesday!

-SD

Sources:

https://link.springer.com/referenceworkentry/10.1007%2F978-3-642-00418-6_517

https://www.ncbi.nlm.nih.gov/books/NBK441993/

https://www.saem.org/about-saem/academies-interest-groups-affiliates2/cdem/for-students/online-education/m4-curriculum/group-m4-trauma/abdominal-trama

https://www.uptodate.com/contents/management-of-splenic-injury-in-the-adult-trauma-patient?search=splenic%20injury&source=search_result&selectedTitle=1~98&usage_type=default&display_rank=1

https://wikem.org/wiki/Splenic_trauma

https://www.ncbi.nlm.nih.gov/books/NBK441993/

Welcome to today's POTD: Aspirin overdose, and by extension, salicylate poisoning!

Background: Salicylates are found in a lot of over the counter drugs and "natural" remedies. Most commonly in the form of Aspirin (acetylsalicylic acid, or ASA), it also exists in Pepto-Bismol, Maalox, Alka-seltzer, and the classic stem question, Oil of Wintergreen. Aspirin is rapidly converted to salicylic acid in the body. Fun fact: Aspirin used to exist as Aspergum, with each stick dosed at 227mg of aspirin. You even had your choice between orange and cherry flavors. Discontinued in 2006.

Normally, at therapeutic levels, aspirin is ingested and absorbed in the stomach. It makes its way to the blood stream, and almost all of it is bound to protein. It is first metabolized by the liver, and these metabolites are then excreted by the kidneys into the urine.

This method of metabolism is quickly overwhelmed in overdose. More free salicylate exists unbound by protein, and the liver's ability to detox becomes saturated. Elimination then proceeds via renal elimination, which is much slower.

Pathophysiology and Symptoms:

The effects salicylates have on specific organs and generalized metabolism are what produce its toxicity.

Acid Base Abnormality

-Salicylates directly stimulates the medullary respiratory center, causing hyperventilation. This hyperventilation blows off CO2 and leads to a respiratory alkalosis. This is usually the first acid-base disturbance.

-This is followed by an anion gap metabolic acidosis. Salicylates uncouple oxidative phosphorylation in the mitochondria, leading to a reliance on anaerobic metabolism and a resultant increase in lactic acid. Build up of organic acids lead to a metabolic acidosis. This is on top of the original respiratory alkalosis, leading to a mixed acid-base picture.

Uncoupling oxidative phosphorylation produces heat; patients are usually hyperthermic.

Tinnitus: Salicylate is ototoxic, and can cause temporary hearing loss and reversible tinnitus. Symptoms usually subside 1-3 days following cessation of salicylate cessation.

Vomiting:

Aspirin and salicylates are gastric irritants, and in overdose, leads to direct stimulation of the chemoreceptor trigger zone in the medulla that causes vomiting. Large amounts of emesis may also create a metabolic alkalosis.

AMS and seizures: Salicylates can cross the blood brain barrier, and can build up in the CNS. This can cause AMS in three different ways: through direct toxicity to CNS through acidemia, neuroglycopenia (through increased demand in CNS), and cerebral edema.

Pulmonary edema and acute lung injury: Salicylate toxicity leads to increased pulmonary vascular permeability.

Arrhythmia: Acidosis and electrolyte disturbances lead to cardiac arrhythmia through altering membrane permeability of cardiac myocytes. 

Bleeding: Acidosis lead to thrombocytopenia and platelet dysfunction.

Word to the wise: Aspirin as a means to suicide is often accompanied by a coingestion of one or more medications. Have a low threshold to check levels/treat for other common overdoses.

Workup:

ASA, Acetaminophen, and levels of any other suspected measureable coingestant

BGM, CBC, BMP, repeated blood gas, mag, phos, UA, utox, coags, LFTs

CT head, EKG, CXR, KUB

Treatment:

These patient are potentially SICK. As always, start with you ABCs.

Airway and Breathing: These patients are tachypneic and may go on to develop respiratory distress when they can no longer compensate for their metabolic acidosis. However, for similar reasons to your DKA patients, avoid intubating if possible. It will be difficult to match the patient's respiratory drive, and the short period of apnea occurring when intubating may spell disaster for your patient.

Circulation: These patients are usually volume down from insensible losses and from vomiting. Help them out with some IVF. Be wary if there are signs of cerebral edema pulmonary edema.

Consider activated charcoal and whole bowel irrigation for decontamination.

Administer glucose. There is a real risk of neuroglycopenia, even if plasma levels are normal.

Alkalinize that urine: Providing sodium bicarb helps alkalinize the urine, facilitating renal clearance and also helps with decrease in CNS/plasma levels of salicylic acid. Alkalinization (increasing pH) increases conversion of salicylic acid to its base form.

Dosing is 1-2meq per kg bolus followed by infusion of 100 to 150meq in 1L sterile water with 5% dextrose.

Correct electrolyte abnormalities.

DIALYSIS: Indications are as follows:

AMS or cerebral edema, pulmonary edema, AKI/chronic kidney disease as this will impair salicylate clearance, salicylate level >90, pH <7, or if patient continues to get worse despite care.

Keep your nephro, tox, and ICU friends handy.

Special notes:

AVOID ACETAZOLAMIDE: though it may make sense to try to alkalinize urine via acetazolaminde, it does it at the cost of reducing bicarb reabsorption.

Chronic Salicylate poisoning: Occurs in patients who routinely take salicylates, and sometimes to the point of excess. More common in young children and elderly patients. Symptoms may be all of the above, but the levels of salicylate may be normal or only mildly elevated. Have a lower threshold for dialysis.

Sources:

https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3341117/

https://wikem.org/wiki/Salicylate_toxicity

https://www.uptodate.com/contents/salicylate-aspirin-poisoning-in-adults

https://www.ncbi.nlm.nih.gov/books/NBK499879/

Hot off the press! FANTASTIC conference this fine Wednesday morning. Special thanks to all of our speakers, and everyone else for being present. We kicked this morning off with an M+M from none other than Dr. Shang:

M+M with Dr. Shang

EMS arriving with an unresponsive woman in her third trimester at 33 weeks gestation, actively seizing. They had called L+D directly to notify them of patient’s arrival.

What is your differential?

Eclampsia is highest. But important to consider other causes: Metabolic, Infectious, structural, toxicologic, hypoxia, epilepsy, pseudoseizure

Pregnant and seizing with ______?

Seizure and low BGM? Glucose.

Na 110: 3% hypertonic or sodium bicarb

Being treated for Tb: B6

Pregnant: magnesium

Recent space shuttle launch: Also vitamin B6

Returning to the case. Initial vitals: Pulse 149, Resp: 32, BP: 164/125, O2 99% on NRB. She is actively seizing. BGM 117

HPI: 26 year old F g1po, 33 weeks gestation, husband heard fall and saw her seizing. No prior seizure history. Patient found seizing on arrival. Possibly seizing up to 30-40 min at this point.

PE otherwise normal.

Interventions in ED: 4g magnesium, 6mg Ativan, intubated with propofol and rocuronium

CTH: to rule out intracranial hemorrhage. READ: Was some white matter hypodensities. Likely PRES, seizure related changes, or less likely embolic infarct.

Went to OR for STAT C section

Still hypertensive in the ED: given 15mg labetalol and 20mg hydralazine given without improvement

Seizure controlled.

Labwork: WBC 22.5, Electrolytes wnl. LFTs normal.

Course:

Patient had C section, baby delivered and intubated in NICU

Patient admitted to SICU, EEG later showed no epileptiform activity

Extubated without difficulty, transferred to floor, discharged 1 week later.

CT READ: Was some white matter hypodensities. Likely PRES, seizure related changes, or less likely embolic infarct.

MRI read several days later: PRES syndrome: subcortical hypodensities, not involving gray matter: suggestive of vasogenic edema. Patchy parietooccipital cortical/subcortical edema without associated DWI. Obtain CT dry followed by MRI with and without contrast when possible.

Hypertensive Disorders in Pregnancy:

Less severe to more severe: gestational htn, preeclampsia, eclampsia, HELLP syndrome

Gestational HTN: new onset htn at 20 weeks gestations or more

SBP > 140, DBP >90

Absence of proteinuria, signs of end organ dysfunction

10-50% develop preeclampsia

Severe if persistently SBP 160, DBP> 110

Plan is for good follow up with OB, if severe, then treat with antihypertensives in ED

Preeclampsia:

SBP >140, DBP 90 WITH

Proteinuria, platelet count, creatinine >1.1, elevated LFTs, pulmonary edema, new onset and persistent headache, visual symptoms.

Can occur after delivery as well.

Red flag symptoms: severe headache, visual abnormalities, epigastric/abdominal pain, AMS, dyspnea, orthopnea: if these present: considered severe preeclampsia. Give magnesium.

Eclampsia: preeclampsia and seizure

HELLP Syndrome: hemolysis, elevated liver enzymes, low platelets. Unclear if this is a part of preeclampsia or its own disease.

• Hemolysis: transfuse if hb less than 7

• Elevated Liver enzymes: chance of hepatic bleeding, liver rupture, hematoma

• Low platelets: transfusion controversial, but consider if actively bleeding, <20,000, <50,000 with plan to operate

Why do we care?

• 10-15% maternal deaths attributed to pre/eclampsia

• Abruptio placentae

• Fetus: they may have growth restriction, prematurity, stillbirth

Treatment: Severe HTN SBP 160, DBP >110

• Labetalol

  • Start with 20IV. Double dose to max of 80 at 10 minute intervals if needed. Cumulative max is 300.

  • Be careful if they have asthma! If so, consider hydralazine

• Hydralazine

• Oral nifedipine (but not preferred, onset is slow)

• Nicardipine (not preferred)

Treatment: Seizure:

• Magnesium sulfate for ppx (preventing preeclampsia to eclampsia), and for breaking seizure as well. Initiated at onset of labor or prior to and during C section.

• If seizing past 15-20 min, proceed down normal status epilepticus pathway

• Magnesium Pharmacology

  • 4-6mg IV loading over 15-20 min

    1. Repeat seizure can give additional 2g over 3-5 min

  • 2g/h maintenance OR 10mg IM (5mg each buttock)

  • Side effects: diaphoresis, flushing, hypotension

• Severe side effects: cardiotoxicity and cardiac arrest

  • Antidote: Calcium gluconate 3g or calcium chloride 1g

• Definitive treatment: Delivery

PRES: Posterior Reversible Encephalopathy Syndrome (though not always reversible, not always posterior)

• Clinical radiographic syndrome of heterogenous etiologies that are grouped together based on neuro imaging studies

• Symptoms: HA, visual disturbance, ams, seizures

• Related to htn encephalopathy and eclampsia

• Treat the htn and seizure, same as you would eclampsia patient

These patients can be difficult regarding airway management, given normal changes in pregnancy.

• Always be set up for intubation in case things go wrong with this type of patient

• Increased edema and hyperemia

• Decreased caliber upper airways

• Consider smaller ET tube when intubating

• Decreased FRC

• They have increased O2 consumption

• Decreased safe apnea time for patient- importance of early preoxygenation

• IVC compression by gravid uterus

• Increased likelihood of post intubation hypotension

• Decreased lower tone of LES, increased risk of vomit

• Increased intraabdominal pressure from uterus

• Minimize BVM, intubate semi-upright position if possible

• Prefer rocuronium over succinylcholine in the seizing patient in case there is associated rhabdo/electrolyte abnormality

• Don’t use ketamine- can increase BP in this patient

EKGs with Dr. Weizberg

EKGs- ISCHEMIA

EKGs measures vectors. If electricity coming at sensor, registers upward deflection. If going to lead and then passes by, get biphasic deflection.

Lead 2 3 avf- inf wall

V1-v6: anterior wall. 1 and 2- interventricular septum. V5-6-avl: lateral wall

Coronary anatomy: in most patients:

• V2, 3, avf suggest RCA

• V1-2-3-4: LAD artery

• Circumflex: lateral wall v5,v6, avl

QRS complex

Q wave: can recognize old MI

-ST segment: whatever connects QRS complex to t wave

Ischemia:

• Ischemia

  • Atherosclerosis, atherosclerosis with blood clot, coronary spasms

  • T wave inversions

  • ST depressions

• Acute MI

  • ST elevations

    1. means 100% occlusion of respective coronary artery

• Old MI

  • MI happened, myocardium already dead

  • Q waves

EKG 1: normal

EKG 2: T wave inversions of inferior wall. Neighbors are V2 and AVF: also has inversions. Inferior wall ischemia

3: lateral wall ischemia

Normal T wave inversions: 3, AVR, V1. Not a sign of ischemia.

EKG 4: normal

EKG 5: st depressions with more significant ischemia. Compare to baseline.

ST depressions v2-v5: anterior wall ischemia

EKG 6: lateral wall v4-v6 ischemia

Acute MI: ST elevations.

EKG 7: anterior and septal elevations

EKG 8: inferior wall MI

Old MIs.

EKG 9: Lead 2 Q wave. Is this normal? Look at neighboring leads. Same in neighboring leads in inferior wall. Old inferior wall MI

How to determine if q waves are normal? Width and depth. Normal q waves small and narrow.

Bad Q waves >1box wide, depth >25% size of qrs complex

EKG 10: anterior septal wall q waves, old MI V1-V2

Get V4R EKG if concerned about involvement/to detect R ventricular MI.

When we have both ST elevations and Q waves in same leads, represents EVOLVING MI.

Myocardium starts to die from inside out: inside dies first: representing Q waves, and outer layer dies last represented with ST elevations. This is still salvageable with reperfusion.

See isolated ST depressions in anterior wall? Get R sided EKG to check for posterior wall MI

Small Groups with Drs. Chung, Eng, Evans

Rheumatologic and Collagen Vascular Diseases with Dr. Chung

High Yield Kahoot!

• Lupus is more common in women

• SLE with hip pain, xrays negative: Obtain MRI. Concern for avascular necrosis

• SLE patient with fever, remains hypotensive despite fluids and pressors. Give 100mg hydrocortisone

• Scleroderma with elevated BP and respiratory distress? Renal crisis. ACE inhibitors

• Alveolar hemorrhage associated with lupus: hemoptysis, pulmonary infiltrate, new anemia. Triad. Give steroids.

• 72 year old with progressive R sided headache x 1 week. CT head negative. Consider Giant cell arteritis, treat prednisone

• What is not a treatment for Raynauds disease? Lisinopril. You can use nifedipine, topical nitroglycerin, sildenafil.

Hypersensitivity- Allergies, Angioedema & anaphylaxis with Dr. Eng

• Patient with “panic attack”

• Tachycardic, tachypneic.

• Oral boards case: First thing is what do I see, hear smell? Obtain ABCs

• Patient looks like she is panicking, holding chest, SOB. Talking normally, BL breath sounds with bit of wheeze

• Obtain monitor, O2, large bore IVs x 2, labs

• Differentials: PE, ACS, pneumonia, DKA, asthma, anxiety/panic attack, thyroid

• Next ask HPI: PMH of history and anxiety attacks. On beta blocker. Patient was sitting eating lunch, 30 min later had palpitations and feeling BL hands, globus feeling throat. Started 30 min ago. Was eating at new sushi restaurant. No GI symptoms.

• Allergic to PCN.

• Start with fluids and Benadryl

• Secondary exam: wheezing, non-stridulous, some mild mucosal swelling in aiway. Mild distress. Swelling upper lip. Managing secretions.

• Patient in anaphylaxis: IM epi, solumedrol, Benadryl, albuterol, O2, famotidine, NS

• Refractive to additional IM injection. Use glucagon for beta blocker. Consider epi drip, prepare for awake intubation.

• Could use fiberoptic, video laryngoscopy

• ICU consult, admission

Transplant Related Problems with Dr. Evans

• 40 year old TIDM htn, 11 months post kidney transplant. Has epigastric tenderness, UA positive for 6-10 wbc, positive for bacteria, large protein. Creatinine 3.4. T 100.1. Elevated BP

• High on differential: infection, rejection, toxicity of transplant meds, vascular such as thrombosis

• Infection:

  • UTI of native kidney, transplanted kidney

  • Patients are immunocompromised. May not have “true” fever. May not have leukocytosis

  • Basic labs, UA, get US and possibly CT

  • IV abx, look at prior urinary cultures/hospital biogram

• Rejection:

  • Elevated Cr, elevated BP, pain over transplanted kidney, protein in urine

  • May need biopsy at some point

  • Tx: steroids high dose

• Toxicity transplant meds:

  • More on this later

When is patient at highest risk at opportunistic infection? What are most common infection?

• 1-6 months

• 1st months: consider regular post op issues, infections from donor

• >6 months: increased susceptibility to common infections

How would you determine if there is transplant medication toxicity?

• No fever, ruling out infection and rejection

• Cyclosporine, tacrolimus

• Any drugs that inhibit/alter CP450 metabolism

30 year old male s/p lung transplant 10 months ago. Dry cough, SOB, low grade fevers. Mildly tachypneic. Breath sounds with crackles. CXR shows BL small effusions, perihilar opacities and diffuse infiltrates.

Workup/Differential/Treatment:

-ekg cxr basic labs, chest CT, IV abx

Ddx: transplant rejection, infection

Lung transplant Complications

• Infection

  • Labs, blood cultures, cxr, bronchioalveolar lavage, possibly transbronchial biopsy

  • Donor infection manifesting in recipient immunocompromised patient

  • Consider bacterial, fungal, viral

• Rejection

  • Rule out infection

  • Pulm consult for bronch and biopsy

  • Steroids in patient and then taper outpt

Lung transplant patients have higher incident of chronic rejection

• Cellular

  • most common acute lung rejection. Mediated by t cells. Histocompatibility complexes

• Humoral

  • Antibodies against donor tissue

• Chronic

  • Bronchiolitis obliterans, multiple acute rejections over time, people with history of gerd

• Restrictive allograft

  • Less common. Restrict pattern on pfts

40 year old s/p pancreatic transplant

• How frequently are pancreas only transplant done? Not very.

• How do they present? DKA, abdominal pain, n/v, asymptomatic, elevated lipase/amylase

Agitation and Psychiatric meds with Pharmacy: Matt Williams Pharm D

Agitation:

• Heightened response to stimuli

• Aggressive or non-aggressive

Etiology and Incidence:

• Variety of causes:

  • Alcohol/drug intox

  • Medical illness

  • Electrolyte abnormalities

• Incidence

  • 2.6 of patients in hospital

  • 72% requiring IM injection sedation

Agitation Severity Assessment: AMS Score AMSS

• +4 to -4. +4 more agitated.

Rapid sedation for acutely agitated patients: ACEP guidance

• BZRD or conventional antipsychotic (Haldol, droperidol)

• If rapid sedation required, consider droperidol over Haldol

• Either atypical or typical antipsychotic effective if known psychiatric diseases

• Ketamine added recently as treatment option

Antipsychotics:

• Pharmacokinetics

  • Olanzapine fastest onset of action, followed by haloperidol, and then ziprasidone

• Side effect profiles:

  • Haldol worst as first generation antipsychotic

Droperidol:

• Black box warning long ago for QTC prolongation

• But more recently deemed safe and more effective than Haldol

• Obtain EKG if possible before (or after) use if possible

• QTC prolongation effect present in very high doses

• Onset of action 5 min compared to 20 min for Haldol

• AAEP: no EKG for doses < 2.5, up to 10mg is safe and effective in patient with agitation

QTCs

• Olanzapine least qtc prolonging

• In patients with prolonged qtc, haloperidol, olanzapine, or benzo may be preferred to droperidol or ziprasidone

First vs Second gen antipsychotics

• 2nd gen have less EPS symptoms. Has higher risk of metabolic syndrome

Benzodiazepines

• GABA A receptor

• Lorazepam faster onset, but wider range compared to midazolam.

• Lorazapam higher half life.

Benzodiazepines or Antipsychotics?

• Strongest efficacy with combination therapy Haldol and midaz

• Midaz/droperidol, droperidol, or olanzapine

  • IV midaz and droperidol superior to single dose droperidol and olanzapine

• Droperidol vs ziprasidone vs Ativan

  • Droperidol had best number of patients with adequate sedation at 15minutes

Ketamine

• NMDA antagonist

• Dissociative Sedation: 1-2mg/kg 4-6mg/kg IM dose

• Onset: IV 30seconds, IM 3-4 minutes; similar bioavailability

• Hepatic metabolism

• Extremely efficacious in violently agitated patients

Adverse effects ketamine

• Htn, tachycardia

• Prolonged emergence reactions

• Hypersalivation, laryngospasm

• Respiratory depression

Research Recap with Dr. Motov

Started off with a reminder of the vast resources we under utilize:

Use the hospital library and our knowledgeable librarians!!

MMC Sharepoint-->

Institutional research library has a ton of useful resources- be sure to use it!

Has templates, resources on statistical analysis, access to published research

Followed by an extensive and awe-inspiring list of our attendings, fellows, and residents hard at work with their emergency medicine publications throughout 2021.

Thank you all and have a wonderful Wednesday!

-SD