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Critical Care

, 23:84 | Cite as

Validity of the relationship between mobility group box-1 protein and poor post–cardiac arrest neurological outcome during renal replacement therapy

  • Patrick M. HonoreEmail author
  • David De Bels
  • Luc Kugener
  • Sebastien Redant
  • Rachid Attou
  • Andrea Gallerani
  • Herbert D. Spapen
Open Access
Letter
  • 117 Downloads

Abbreviations

AKI

Acute kidney injury

CA

Cardiac arrest

(C)RRT

(Continuous) renal replacement therapy

HMGB-1

High-mobility group box-1

I/R

Ischemia/Reperfusion

Recently in Critical Care, Sugita et al. confirmed the previously reported positive association between high HMGB-1 (high-mobility group box-1) levels and a poor neurological outcome in post–cardiac arrest (post-CA) patients [1]. Although we applaud this excellent study, we would like to make some comments. Brain damage after out-of-hospital CA is a leading cause of mortality and long-term neurological disability in survivors. Primary injury is caused by an immediate shutdown of cerebral blood flow. In the hours and days following CA, systemic ischemia/reperfusion (I/R)-induced processes may culminate in secondary neuronal cell death [2]. HMGB-1, a typical damage-associated molecular pattern protein, is crucial in inflammation and is critically involved in thrombosis and also mediates systemic organ I/R. Interestingly, almost half of the patients resuscitated after CA may develop acute kidney injury (AKI). More than 75% of AKI episodes occurred within 3 days after CA and about one third of these patients eventually needed continuous renal replacement therapy (CRRT) [3]. Sugita et al. did not mention the incidence of AKI or need of (C)RRT. However, given the high number of patients in shock (75% of patients with a Glasgow–Pittsburgh Cerebral Performance Categories Scale (CPC) score of 3 to 5 were on vasopressors!), it is reasonable to assume that a substantial number developed AKI or needed (C)RRT or both. With a molecular weight of 30 kDa, HMGB-1 is not eliminated by convective CRRT. However, Yumoto et al. showed that more than 90% of HMGB-1 was cleared from the circulation by highly adsorbent surface-treated polyacrylonitrile and polymethylmethacrylate membranes but that no such removal was observed with the less adsorptive polysulfone membranes [4]. Although polysulfone hemofilters are most commonly used for CRRT in Japan [5], implementing highly adsorbent filters would result in much lower serum HMGB-1 levels in post-CA patients. This not only would challenge the conclusions made by Sugita et al. but also could affect patient outcome since an extensive elimination of HMGB-1 may theoretically subdue the I/R-related post-CA injurious process.

Authors’ response

  • Atsushi Sakurai
  • Kosaku Kinoshita
  • Atsunori Sugita
  • Nobutaka Chiba
  • Junko Yamaguchi
  • Tsukasa Kuwana
  • Nami Sawada
  • Satoshi Hori

Following the revision of our data, we identified 12 of 128 patients to be treated with continuous renal replacement therapy (CRRT), including 7 who had been on haemodialysis therapy prior to the cardiac arrest (CA). Only 5 patients (3.9 %) were treated with CRRT for renal failure in our study.

Whether elimination of HMGB1 could contribute to the amelioration of the neurological deficits in patients with post-cardiac arrest syndrome (PCAS) is a crucial question. HMGB1 clearance from the brain may afford brain protection in PCAS patients. Considering the small molecular weight of HMGB1 and that CA induces the blood–brain barrier breakdown in the early phase of post-resuscitation, it is possible that serum HMGB1 may invade the brain through the broken BBB and promote the inflammatory pathophysiology of the ischemic reperfusion brain injury. Xu et al. reported that the neurological deficits significantly improved in rats resuscitated from CA following the injection of the anti-HMGB1 antibody into their cerebral ventricles [1]. Another study reported that the intravenous injection of an anti-HMGB1 antibody improved the cerebral haemorrhage-induced neurological deficits in rats [2]. Therefore, these findings suggest that the systemic clearance of HMGB1 might also ameliorate post-cardiac arrest brain injury.

As Dr. Honore proposed, using the CRRT for clearance of serum HMGB1 may be a promising candidate method for the treatment of PCAS patients. During the process of brain injury, damage-associated molecular patterns, including HMGB1, are released from the injured neurons and activate inflammation, which results in further neural and glial death during stroke [3]. In the present study, the peaks of serum HMGB1, interleukin-6 and neuron-specific enolase were 0, 24 and 48 h from resuscitation, respectively [4], indicating that a pathologic mechanism similar to stroke may occur in PCAS patients. In contrast HMGB1 was higher in the cerebrospinal fluid of PCAS patients than in their serum at 48 h after resuscitation [5]. These results suggest that, in addition to the primary inflammatory brain injury, HMGB1 may also promote the secondary inflammatory brain injury in PCAS patients. However, when the primary brain damage is severe, decreasing HMGB1 activity in PCAS patients will not be effective. Therefore, both the timing of the treatment and the severity of brain injury should be taken into consideration when investigating HMGB1 clearance treatment therapy for PCAS patients.

Notes

Acknowledgments

None.

Funding

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Availability of data and materials

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Authors’ contributions

PMH and HDS designed the paper. All authors participated in drafting and reviewing. All authors read and approved the final version of the manuscript.

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Not applicable.

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Not applicable.

Competing interests

The authors declare that they have no competing interests.

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References

  1. 1.
    Sugita A, Kinoshita K, Sakurai A, Chiba N, Yamaguchi J, Kuwana T, et al. Systemic impact on secondary brain aggravation due to ischemia/reperfusion injury in post-cardiac arrest syndrome: a prospective observational study using high-mobility group box 1 protein. Crit Care. 2017;21:247.CrossRefGoogle Scholar
  2. 2.
    Sekhon MS, Ainslie PN, Griesdale DE. Clinical pathophysiology of hypoxic ischemic brain injury after cardiac arrest: a “two-hit” model. Crit Care. 2017;21:90.CrossRefGoogle Scholar
  3. 3.
    Tujjar O, Mineo G, Dell’Anna A, Poyatos-Robles B, Donadello K, Scolletta S, et al. Acute kidney injury after cardiac arrest. Crit Care. 2015;19:169.CrossRefGoogle Scholar
  4. 4.
    Yumoto M, Nishida O, Moriyama K, Shimomura Y, Nakamura T, Kuriyama N, et al. In vitro evaluation of high mobility group box 1 protein removal with various membranes for continuous hemofiltration. Ther Apher Dial. 2011;15:385–93.CrossRefGoogle Scholar
  5. 5.
    Yasuda H, Sekine K, Abe T, Suzaki S, Katsumi A, Harada N, et al. Comparison of two polysulfone membranes for continuous renal replacement therapy for sepsis: a prospective cross-over study. Renal Replacement Therapy. 2018;4:6.CrossRefGoogle Scholar

Copyright information

© The Author(s). 2019

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Authors and Affiliations

  • Patrick M. Honore
    • 1
    Email author
  • David De Bels
    • 1
  • Luc Kugener
    • 1
  • Sebastien Redant
    • 1
  • Rachid Attou
    • 1
  • Andrea Gallerani
    • 1
  • Herbert D. Spapen
    • 2
  1. 1.ICU DepartmentCentre Hospitalier Universitaire Brugmann-Brugmann University HospitalBrusselsBelgium
  2. 2.Ageing & Pathology Research GroupVrije Universiteit BrusselBrusselsBelgium

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