Erector spinae plane block and altered hemostasis: is it a safe option? -a case series-

ESP block and altered hemostasis

Article information

Korean J Anesthesiol. 2020;73(5):445-449

Publication date (electronic) : 2020 February 26

doi : https://doi.org/10.4097/kja.20078

João Galacho

, Mariano Veiga

, Lucindo Ormonde

Department of Anesthesiology, Santa Maria University Hospital-North Lisbon Hospital Center, Lisbon, Portugal

Corresponding author: João Galacho, M.D. Department of Anesthesiology, Santa Maria University Hospital-North Lisbon Hospital Center, Av. Professor Egas Moniz, 1649-028 Lisbon, Portugal Tel: +351-217805193 Fax: +351-217805610 Email: joaogalacho@gmail.com

Received 2020 February 18; Revised 2020 February 25; Accepted 2020 February 25.

Abstract

Background

We described 5 cases of uneventful administration of the erector spinae plane (ESP) block to patients with altered hemostasis.

Case

Five patients were admitted to the intensive care unit with altered hemostasis, defined by the activated partial thromboplastin time ratio or internatinal normalized ratio exceeding 1.5 times the normal value; platelet count equal to or below 80000/μl; or use of anticoagulation therapy. A multimodal analgesic regimen was used for all patients, which proved unsatisfactory and limited successful ventilator weaning, until the administration of the ESP block. Effective analgesia was observed in all patients, with at least 70% reduction in numeric pain scale scores and 83% reduction in opioid consumption, which enabled successful ventilator weaning. No neurologic or hemorrhagic complications were recorded during daily surveillance over 5 days.

Conclusions

The ESP block may be a suitable regional analgesia technique for patients with altered hemostasis. Further studies are needed to support this finding.

Keywords: Acute pain; Critical care; Hemostasis; Interventional ultrasonography; Pain management; Postoperative pain; Ventilator weaning

The erector spinae plane (ESP) block is a novel interfascial regional analgesic technique that was described by Forero et al. [1] in 2016, to treat thoracic neuropathic pain. Growing evidence of its efficacy and relative simplicity of performance has resulted in an increase in its use for managing acute and chronic pain [2–5]. The spread of local anesthetic through the paravertebral spaces is thought to be responsible for its analgesic effect on somatic and visceral pain, and thus, it has been reported to be as effective as thoracic epidural analgesia when administered bilaterally [6].

The ESP block may have some advantages over thoracic epidural analgesia, as it is a moderately simple technique that can be used unilaterally. It provides lesser sympathetic blockade with fewer cardiovascular effects, compared to the paravertebral block. However, the administration of the ESP block requires ultrasonographic guidance.

The ESP block seems to be similar to a superficial block compared to the epidural and paravertebral blocks, with a lower risk of hemorrhage, especially in patients with altered hemostasis, i.e., the risk of spinal hematoma and spinal cord compression is lower, as the block is administered superficial to the transverse processes, allowing the spinal cord to be protected by the vertebral canal. However, these aspects have not been studied in depth and established firmly in current literature [7].

We describe a case series of 5 patients with altered hemostasis (activated partial thromboplastin time [aPTT] ratio or internatinal normalized ratio [INR] exceeding 1.5 times the normal value, a platelet count equal to or below 80000/μl, or use of anticoagulant medication) in whom the ESP block was performed for acute pain management. The risks of the technique were described to all the patients and discussed with them or their legal representatives. We believed that the benefits outweighed the risks of the technique in each patients. All procedures were performed by one of the two principal authors. We monitored the patients daily for the first 5 days after the technique. No neurologic or hemorrhagic complications were recorded.

There seems to be growing evidence supporting the fact that the ESP block is a superficial block. We believe that the relationship with the surrounding anatomical structures, absence of major vessels in the vicinity, compressibility, and the use ultrasonographic guidance are facts that support this argument.

Case Reports

We described a series of 5 patients in whom inadequate acute pain control caused difficulty in weaning them off the ventilator. Conventional neuraxis analgesia techniques, namely epidural or paravertebral blocks, were contraindicated due to a well-established risk of severe bleeding and spinal cord compression.

All the potential risks and benefits were discussed with all patients when possible, or their legal guardians, and verbal and written informed consent were obtained in all situations for reporting these cases.

All procedures were performed under ultrasonographic guidance (M-Turbo^®, Sonosite Inc., USA), using a linear high-frequency probe (HFL38x^®, Sonosite Inc., USA) in the longitudinal position, after identifying the transverse processes of the desired vertebra. Once identified, a 100-mm needle (Echoplex^®, Vygon, France) was inserted in plane along the cephalad to caudal direction, until the needle tip contacted bone, between the erector spinae muscle and the transverse process.

Daily assessment of potential complications was performed for 5 days.

We have described all the clinical cases and the rationale behind our decision-making process as follows.

Case 1

A male patient, weighing 88 kg, was diagnosed with septic shock caused by acute necrotizing pancreatitis with multiorgan disfunction and altered hemostasis (thrombocytopenia: 18000/μl, INR: 2.52, and aPTT: 45.2/29 s).

There was difficulty in weaning the patient off the ventilator due to poor acute pain management. He was under deep sedoanalgesia with midazolan (2 mg/h), propofol (1 mg/kg/h), paracetamol (3 g/day), ketamine (0.15 mg/kg/h), and fentanyl (2.5 μg/kg/h or 5280 μg/day, equivalent to morphine 245 mg/day).

We proposed a bilateral ultrasound-guided single-shot ESP block, was perform which was performed at the level of T7 and 20 ml of 0.5% ropivacaine was administered to each side. We were able to stop all sedatives and successfully wean the patient off the ventilator over the next few hours, after which a score of 0 was recorded on the numerical pain scale (NPS). A score of 3 was recorded the day after and an infusion of morphine was started, with an average requirement of 24 mg/day.

No ESP-technique related complications were observed.

Case 2

A 16-year-old boy, weighing 80 kg, was admitted to the pediatric intensive care unit due to polytraumatism. He had pelvic fracture, right femoral fracture, and severe lesions of the right femoral artery and vein, which were responsible for below-knee amputation of the lower right limb.

A multimodal strategy with paracetamol (3 g/day), metamizol (4 g/day), ketamine (0.3 mg/kg/h), gabapentin (1400 mg/day), and morphine (300 mg/day) afforded poor pain control in the lower limb, which was consistent with neuropathic pain (Douleur Neuropathique 4 [DN4] score of 6/10, NPS score of 6/10 at rest, and 10/10 during nursing care, needed twice daily).

He also presented with persistent altered hemostasis (INR: 1.8–2.24).

We performed a continuous ESP block at the level of T10 using 0.375% ropivacaine (20 ml every 6 h), which produced a better analgesic effect over 5 days (maximum NPS score of 3/10) and reduced the daily dose of morphine to 44 mg/day.

No technique-related complications were observed.

Case 3

A 69-year-old man was admitted to the intensive care unit due to hemorrhagic shock after elective open splenectomy and left nephrectomy, due to refractory immune thrombocytopenic purpura and left kidney tumour.

He had a left subcostal incision, approximately 30 cm in length. His usual platelet count was around 30000–40000/μl, which plumetted to a minimum count of 5000/μl.

Poor acute pain management with a multimodal strategy with paracetamol (4 g/day), ketamine (0.5 mg/kg/h), and morphine (140 mg/day) caused difficulty in ventilator weaning.

We performed a continuous left ESP block at the level of T7 with 0.2% ropivacaine (20 ml every 4 h), which allowed adequate analgesia and extubation after 6 h.

No technique-related complications were observed.

Case 4

A 71-year-old man was admitted to the intensive care unit after open endoluminal aortic thrombectomy, with a left subcostal incision, and a thoracotomy at the level of the sixth intercostal space.

Post-operative systemic anticoagulation was required after surgery and he was also under anticoagulant therapy with enoxaparin (1 mg/kg/day, adjusted for acute kidney injury and an estimated glomerular filtration rate below 30 ml/min) and presented with thrombocytopenia (platelet count: 80000/μl).

He experienced acute pain with an NPS score of 7/10 despite a multimodal analgesic regimen with paracetamol (4 g/day), ketamine (0.2 mg/kg/h), and fentanyl (3 μg/kg/h), which did not permit ventilatory weaning.

We performed a continuous left ESP block at the level of T6, with 0.2% ropivacaine (20 ml every 4 h), which produced adequate analgesia, permitting extubation after 4 h.

No technique-related complications were observed.

Case 5

A 21-year-old man was admitted to the intensive care unit due to hemorrhagic shock caused by a massive left hemothorax and hypertensive pneumothorax after penetrating thoracic trauma, which was complicated by cardiac arrest. Emergency atypical lung resection was performed with a left thoracotomy at the level of the sixth intercostal space.

Thrombocytopenia was observed (43000/μl) despite correction of INR and aPTT.

A multimodal regimen with paracetamol (4 g/day), ketamine (0.3 mg/kg/h) and fentanyl (3 μg/kg/h) provided poor pain control as an NPS score of 9/10 was recorded, which made ventilator weaning difficult.

We performed a continuous left ESP block at the level of T5, with 0.2% ropivacaine (20 ml every 4 h), and adequate analgesia was achieved, which allowed extubation after 4 h.

No technique-related complications were observed.

Discussion

Few regional analgesia techniques are available for ameliorating thoracic or abdominal visceral pain (such as the thoracic or lumbar epidural or paravertebral block) for patients with altered hemostasis. The ESP block is a fascial plane block, which is performed between the transverse processes and erector spinae muscles, with a moderate level of difficulty, and can provide adequate analgesia through multiple dermatomes by cephalocaudal spread, as reported by Ivanusic et al. [8]. Although this study reported no spread of dye to the ventral rami, several (published) studies have provided evidence, supporting the idea that anterior spread of local anesthetic provides visceral fiber blockade, explaining its use in thoracic, cardiac and abdominal surgery [9–13]. A recent case report described Harlequin syndrome after the ESP block, which is clearly consistent with the anterior spread of local anesthetic solution responsible for sympathetic fiber chain blockade [14].

We believe that although the anterior spread of the dye has not been well-established in cadaveric studies, a sufficient number of clinical reports currently support the existence of anterior spread that is responsible for the visceral analgesia provided by this block. We believe that the lack of dye spread in cadavers may be dependent on the lack of thoracic wall movement caused by respiratory movement (either spontaneous breathing or by mechanical ventilation), which may be a major factor that facilitates anterior spread of the local anesthetic.

We achieved adequate analgesia in all patients. We observed 70% to 89% of reduction in the NPS scores and 83% to 100% reduction in opioid consumption (Table 1). This amelioration in pain allowed all patients to be successfully weaned off the ventilator, within the next few hours.

Table 1.

Description of the Five Clinical Cases

There is a safe distance between the anatomical fascial plane and neuraxis or pleura, which renders this block suitable for patients with altered hemostasis under ultrasonographic guidance. This hypothesis has not been tested in randomized controlled trials and the safety of this technique in these circumstances has not been tested yet.

We used this technique in 5 patients with major alterations in hemostasis, such as severe thrombocytopenia, INR > 1.5, and one patient under therapeutic anticoagulation with low molecular weight heparin.

We did not observe any neurological complications, including spinal hematoma or nerve root compression, or hemorrhagic complications, including internal or external bleeding 5 days after administration of the ESP block.

Although these observations may represent a small pool of patients, it is the largest sample of such patients to the best of our knowledge and may represent a major contribution that establishes the safety of this block in patients with altered hemostasis.

The duration of mechanical ventilation and use of deep sedation have been linked with increased mortality and delirium in intensive care practice. An adequate analgesic regimen allows patients to be mechanically ventilated with a lower level of sedation for the shortest time possible, which allows for quicker ventilatory weaning and extubation, which are the primary goals in this setting. The ESP block is a regional analgesic technique with a moderate level of difficulty, which can be used in patients with altered hemostasis and inadequate pain control and which allows them to be quickly and successfully weaned from the ventilator. This may be particularly important in patients who have experienced trauma and those who have undergone surgery, since this technique may decrease the duration of mechanical ventilation and eventually reduce mortality. We think that these aspects are particularly interesting and deserve further study [15].

Nevertheless, we strongly believe that an individualized risk-benefit assessment should be performed for every patient and that more studies are needed to support our hypothesis.

Notes

Conflicts of Interest

No potential conflict of interest relevant to this article was reported.

Author Contributions

João Galacho (Conceptualization; Data curation; Formal analysis; Methodology; Validation; Visualization; Writing – original draft; Writing – review & editing)

Mariano Veiga (Conceptualization; Data curation; Formal analysis; Supervision; Validation; Visualization; Writing – original draft; Writing – review & editing)

Lucindo Ormonde (Supervision)

References

1. Forero M, Adhikary SD, Lopez H, Tsui C, Chin KJ. The erector spinae plane block: a novel analgesic technique in thoracic neuropathic pain. Reg Anesth Pain Med 2016;41:621–7.

2. Forero M, Rajarathinam M, Adhikary S, Chin KJ. Continuous erector spinae plane block for rescue analgesia in thoracotomy after epidural failure: a case report. A A Case Rep 2017;8:254–6.

3. Ueshima H, Otake H. Erector spinae plane block for pain management of wide post-herpetic neuralgia. J Clin Anesth 2018;51:37.

4. Hamilton DL, Manickam B. Erector spinae plane block for pain relief in rib fractures. Br J Anaesth 2017;118:474–5.

5. Bang S, Chung K, Chung J, Yoo S, Baek S, Lee SM. The erector spinae plane block for effective analgesia after lung lobectomy: three cases report. Medicine (Baltimore) 2019;98e16262.

6. Vidal E, Giménez H, Forero M, Fajardo M. Erector spinae plane block: a cadaver study to determine its mechanism of action. Rev Esp Anestesiol Reanim 2018;65:514–9.

7. Horlocker TT, Vandermeuelen E, Kopp SL, Gogarten W, Leffert LR, Benzon HT. Regional anesthesia in the patient receiving antithrombotic or thrombolytic therapy: American society of regional anesthesia and pain medicine evidence-based guidelines (fourth edition). Reg Anesth Pain Med 2018;43:263–309.

8. Ivanusic J, Konishi Y, Barrington MJ. A cadaveric study investigating the mechanism of action of erector spinae blockade. Reg Anesth Pain Med 2018;43:567–71.

9. Chin KJ, Malhas L, Perlas A. The erector spinae plane block provides visceral abdominal analgesia in bariatric surgery: a report of 3 cases. Reg Anesth Pain Med 2017;42:372–6.

10. Kang R, Chin KJ, Gwak MS, Kim GS, Choi SJ, Kim JM, et al. Bilateral single-injection erector spinae plane block versus intrathecal morphine for postoperative analgesia in living donor laparoscopic hepatectomy: a randomized non-inferiority trial. Reg Anesth Pain Med 2019;Advance Access published on Oct 23, 2019. doi: 10.1136/rapm-2019-100902.

11. Veiga M, Costa D, Brazão I. Erector spinae plane block for radical mastectomy: a new indication? Rev Esp Anestesiol Reanim 2018;65:112–5.

12. Krishna SN, Chauhan S, Bhoi D, Kaushal B, Hasija S, Sangdup T, et al. Bilateral erector spinae plane block for acute post-surgical pain in adult cardiac surgical patients: a randomized controlled trial. J Cardiothorac Vasc Anesth 2019;33:368–75.

13. Nagaraja PS, Ragavendran S, Singh NG, Asai O, Bhavya G, Manjunath N, et al. Comparison of continuous thoracic epidural analgesia with bilateral erector spinae plane block for perioperative pain management in cardiac surgery. Ann Card Anaesth 2018;21:323–7.

14. Sullivan TR, Kanda P, Gagne S, Costache I. Harlequin syndrome associated with erector spinae plane block. Anesthesiology 2019;131:665.

15. Shehabi Y, Bellomo R, Kadiman S, Ti LK, Howe B, Reade MC, et al. Sedation intensity in the first 48 hours of mechanical ventilation and 180-day mortality: a multinational prospective longitudinal cohort study. Crit Care Med 2018;46:850–9.

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Table 1.

Description of the Five Clinical Cases

Case no.	Diagnosis / Procedure	Maximum NPS (0–10)		Initial analgesic regimen	Opioid in equivalent morphine daily dose		Altered hemostasis			Level of ESP block	Single-shot vs continuous technique	Local anesthethic regimen	Complications
Case no.	Diagnosis / Procedure	Before ESP block	After ESP block	Initial analgesic regimen	Before	After ESP block	INR > 1.5	aPTT >1.5	Platelet count ≤ 80000/μl	Level of ESP block	Single-shot vs continuous technique	Local anesthethic regimen	Complications
1	Acute necrohemorragic pancreatitis with multiorganic disfunction	N/A	3	Paracetamol (3 g/day)	245 mg	24 mg	Yes (2.52)	Yes (1.55x)	Yes (18000/μl)	T7	Single-shot	0.5% ropivacaíne	No
				Ketamine – Ketamine (0.15 mg/kg/h)								20 ml, bilaterally
				Fentanyl (2.5 μg/kg/h)
2	Right lower limb amputation	10	3	Paracetamol (3 g/day)	300 mg	44 mg	Yes (1.8 - 2.24)	No	No (85,000/μl)	T10	Continuous	0.375% ropivacaíne	No
	(below knee)			Metamizol (4 g/day)								20 ml every 6 h
				Ketamine (0.3 mg/kg/h)
				Gabapentin (1400 mg/day)
				Morphine (300 mg/day)
3	Open splenectomy and left nephrectomy	10	2	Paracetamol (4 g/day)	140 mg	0mg	No	No	Yes (5,000/μl)	T7	Continuous	0.2% ropivacaíne	No
				Ketamine (0.5 mg/kg/h)								20 ml every 4 h
				Morphine (140 mg/day)
4	Open endoluminal aortic thrombectomy	7	2	Paracetamol (4 g/day)	288 mg	0 mg	Therapeutic anticoagulation		Yes (80,000/μl)	T6	Continuous	0.2% ropivacaíne	No
				Ketamine (0.2 mg/kg/h)								20 ml every 4 h
				Fentanyl (3 ug/kg/h)
5	Left thoracotomy	9	1	Paracetamol (4 g/day)	252 mg	0 mg	No	No	Yes (43,000/μl)	T5	Continuous	0.2% ropivacaíne	No
				Ketamine (0.3 mg/kg/h)								20 ml every 4 h
				Fentanyl (3 μg/kg/h)

Values are presented as number (%). ESP: erector spinae plane, INR: international normalized ratio, aPTT: activated partial thromboplastin time, 1.5X: 1.5 times the normal value, N/A: not applicable.