Influence of brain death and associated trauma on solid organ histological characteristics

Simas, Rafael; Kogiso, Diogo Haruo; Correia, Cristiano de Jesus; Silva, Luiz Fernando Ferraz da; Silva, Isaac Azevedo; Cruz, José Walber Miranda Costa; Sannomiya, Paulina; Moreira, Luiz Felipe Pinho

doi:10.1590/S0102-86502012000700006

Abstracts

PURPOSE: To evaluate histopathological alterations triggered by brain death and associated trauma on different solid organs in rats. METHODS: Male Wistar rats (n=37) were anesthetized with isoflurane, intubated and mechanically ventilated. A trepanation was performed and a balloon catheter inserted into intracraninal cavity and rapidly inflated with saline to induce brain death. After induction, rats were monitored for 30, 180, and 360 min for hemodynamic parameters and exsanguinated from abdominal aorta. Heart, lung, liver, and kidney were removed and fixed in paraffin to evaluation of histological alterations (H&E). Sham-operated rats were trepanned only and used as control group. RESULTS: Brain dead rats showed a hemodynamic instability with hypertensive episode in the first minute after the induction followed by hypotension for approximately 1 h. Histological analyses showed that brain death induces vascular congestion in heart (p<0.05), and lung (p<0.05); lung alveolar edema (p=0.001), kidney tubular edema (p<0.05); and leukocyte infiltration in liver (p<0.05). CONCLUSIONS: Brain death induces hemodynamic instability associated with vascular changes in solid organs and compromises most severely the lungs. However, brain death associated trauma triggers important pathophysiological alterations in these organs.

Brain Death; Craniocerebral Trauma; Pathology; Rats

OBJETIVO: Avaliar as alterações histopatológicas desencadeadas pela morte encefálica e pelo trauma associado em diferentes órgãos sólidos em ratos. MÉTODOS: Ratos Wistar machos (n=37) foram anestesiados com isoflurano, entubados e mecanicamente ventilados. Foi realizada trepanação e um cateter foi inserido na cavidade intracraniana e insuflado rapidamente para induzir morte encefálica. Após a indução, os ratos foram monitorados por 30, 180 e 360 min para parâmetros hemodinâmicos e exsanguinados pela aorta abdominal. Coração, pulmão, fígado e rim foram removidos e fixados em parafina para avaliação de alterações histológicas (H&E). Ratos falso-operados foram apenas trepanados e usados como grupo controle. RESULTADOS: Ratos com morte encefálica apresentaram instabilidade hemodinâmica com episódio hipertensivo no primeiro minuto após a indução seguido de hipotensão por aproximadamente 1 hora. Análises histológicas demonstraram que a morte encefálica induz congestão vascular no coração (p<0,05) e pulmão (p<0,05); edema alveolar (p=0,001); edema tubular (p<0,05); e infiltrado leucocitário no fígado (p<0,05). CONCLUSÕES: A morte encefálica induz instabilidade hemodinâmica associada com mudanças vasculares em órgãos sólidos e compromete mais severamente os pulmões. Contudo, o trauma associado à morte encefálica desencadeia importantes alterações fisiopatológicas naqueles órgãos.

Morte Encefálica; Traumatismos Craniocerebrais; Patologia; Ratos

6 - ORIGINAL ARTICLE

MODELS, BIOLOGICAL

Influence of brain death and associated trauma on solid organ histological characteristics¹ Correspondence: Rafael Simas Avenida Dr. Arnaldo, 455 01246-903 São Paulo - SP Brasil Tel./Fax: (55 11)3061-7178 biosimas@usp.br

Influência da morte encefálica e do trauma associado nas características histológicas de órgãos sólidos

Rafael Simas^I; Diogo Haruo Kogiso^II; Cristiano de Jesus Correia^III; Luiz Fernando Ferraz da Silva^IV; Isaac Azevedo Silva^V; José Walber Miranda Costa Cruz^VI; Paulina Sannomiya^VII; Luiz Felipe Pinho Moreira^VIII

^IFellow PhD degree, Postgraduate Program on Thoracic and Cardiovascular Surgery, Medicine School, University of Sao Paulo (USP), Brazil. Interpretation of data, and manuscript writing

^IIGraduate student, Medicine School, USP, Sao Paulo-SP, Brazil. Performed histological analyses

^IIIBiologist, Department of Cardiopneumology, InCor, Medicine School, USP, Sao Paulo-SP, Brazil. Performed surgical procedures

^IVMD, Assistant Professor, Department of Pathology, Medicine School, USP, Sao Paulo-SP, Brazil. Performed histological analyses

^VMD, Fellow PhD degree, Postgraduate Program on Thoracic and Cardiovascular Surgery, Medicine School, USP, Sao Paulo-SP, Brazil. Interpretation of data and manuscript writing

^VIPhD, Department of Cardiopneumology, InCor, Medicine School, USP, Sao Paulo-SP, Brazil. Performed surgical support

^VIIPhD, Associated Professor, Department of Cardiopneumology, InCor, Medicine School, USP, Sao Paulo, Brazil. Study concept and design, interpretation of data, manuscript writing and critical revision

^VIIIPhD, Associate Professor, Department of Cardiopneumology, InCor, Medicine School, USP, Sao Paulo-SP, Brazil. Study concept and design, interpretation of data, statistical analyses, manuscript writing and critical revision

^{Correspondence} Correspondence: Rafael Simas Avenida Dr. Arnaldo, 455 01246-903 São Paulo - SP Brasil Tel./Fax: (55 11)3061-7178 biosimas@usp.br

ABSTRACT

PURPOSE: To evaluate histopathological alterations triggered by brain death and associated trauma on different solid organs in rats.

METHODS: Male Wistar rats (n=37) were anesthetized with isoflurane, intubated and mechanically ventilated. A trepanation was performed and a balloon catheter inserted into intracraninal cavity and rapidly inflated with saline to induce brain death. After induction, rats were monitored for 30, 180, and 360 min for hemodynamic parameters and exsanguinated from abdominal aorta. Heart, lung, liver, and kidney were removed and fixed in paraffin to evaluation of histological alterations (H&E). Sham-operated rats were trepanned only and used as control group.

RESULTS: Brain dead rats showed a hemodynamic instability with hypertensive episode in the first minute after the induction followed by hypotension for approximately 1 h. Histological analyses showed that brain death induces vascular congestion in heart (p<0.05), and lung (p<0.05); lung alveolar edema (p=0.001), kidney tubular edema (p<0.05); and leukocyte infiltration in liver (p<0.05).

CONCLUSIONS: Brain death induces hemodynamic instability associated with vascular changes in solid organs and compromises most severely the lungs. However, brain death associated trauma triggers important pathophysiological alterations in these organs.

Key words: Brain Death. Craniocerebral Trauma. Pathology. Rats.

RESUMO

OBJETIVO: Avaliar as alterações histopatológicas desencadeadas pela morte encefálica e pelo trauma associado em diferentes órgãos sólidos em ratos.

MÉTODOS: Ratos Wistar machos (n=37) foram anestesiados com isoflurano, entubados e mecanicamente ventilados. Foi realizada trepanação e um cateter foi inserido na cavidade intracraniana e insuflado rapidamente para induzir morte encefálica. Após a indução, os ratos foram monitorados por 30, 180 e 360 min para parâmetros hemodinâmicos e exsanguinados pela aorta abdominal. Coração, pulmão, fígado e rim foram removidos e fixados em parafina para avaliação de alterações histológicas (H&E). Ratos falso-operados foram apenas trepanados e usados como grupo controle.

RESULTADOS: Ratos com morte encefálica apresentaram instabilidade hemodinâmica com episódio hipertensivo no primeiro minuto após a indução seguido de hipotensão por aproximadamente 1 hora. Análises histológicas demonstraram que a morte encefálica induz congestão vascular no coração (p<0,05) e pulmão (p<0,05); edema alveolar (p=0,001); edema tubular (p<0,05); e infiltrado leucocitário no fígado (p<0,05).

CONCLUSÕES: A morte encefálica induz instabilidade hemodinâmica associada com mudanças vasculares em órgãos sólidos e compromete mais severamente os pulmões. Contudo, o trauma associado à morte encefálica desencadeia importantes alterações fisiopatológicas naqueles órgãos.

Descritores: Morte Encefálica. Traumatismos Craniocerebrais. Patologia. Ratos.

Introduction

Brain death (BD) means cessation of all metabolic pathways in central nervous system, but paradoxically, since it installs, a lot of events are triggered on the whole organism and many pathophysiological changes may be seen in different organs¹. As BD patients are the most important source of allografts for transplantation and the scarcity of donors is an increasing problem in the whole world², understanding these alterations will contribute to improving management, optimizing outcomes and providing organs that, without treatment, would be unsuitable for transplantation.

The pathophysiological changes that occur during and after BD include hemodynamic, hormonal and inflammatory events. Moreover, vasoconstriction triggered by catecholamine storm leads to peripheral ischemia impairing the organs perfusion. However, many factors associated with BD which occur before it, such as multi-trauma, hemorrhage and hypoxia can trigger different pathophysiological responses in the organs^3-5.

The present study aims to differentiate the features triggered by BD itself on the principal solid organs commonly used for transplantation in a rodent model, comparing them with sham-operated animals submitted to the same time points of observation.

Methods

Male Wistar rats weighing 250-350g (n=37) were used and randomized into 6 groups: sham-operated rats monitored for 30 (SH30, n=7), 180 (SH180, n=6), and 360 min (SH360, n=5); brain-dead rats monitored for 30 (BD30, n=7), 180 (BD180, n=7), and 360 min (BD360, n=5). The animals were maintained at 23ºC ± 2ºC under a cycle of 12 h light/12h darkness and allowed access to food and water ad libitum before the experimental procedure. The experimental protocols were approved by the Animal Subject Committee of the Heart Institute (InCor) of the São Paulo University Medical School.

Rats were anesthetized in a chamber with 5% isoflurane, intubated and ventilated with a rodent ventilator (Harvard Apparatus, model 683, USA) with tidal volume of 10 mL/kg, and frequency of 70 breaths/min. The animals were maintained with continuous inhalation of 2% isoflurane. The carotid artery was cannulated for continuous blood pressure monitoring and blood sampling. The jugular vein was cannulated for infusion of saline solution.

Brain death model

Brain death was induced by rapid inflation of a catheter Fogarty-4F (Baxter Health Care Co., USA) with 500 µL of saline solution, through a drilled parietal burr hole. BD was confirmed by maximal pupil dilatation, apnea, absence of reflex, and drop of mean arterial pressure (MAP). After BD induction the anesthesia was stopped. Sham-operated animals were trepanned only, with no catheter insertion, and the anesthesia was maintained throughout the experiment. BD rats received an infusion of saline solution (2mL/h) trough the jugular vein to minimize dehydration.

Histopathological analyses

After 30, 180, or 360 min, animals were exsanguinated from the abdominal aorta, and heart, lung, liver and kidneys were removed, fixed in formalin, and paraffin embedded. Samples were cut into 4µm sections, and stained with hematoxylin and eosin (H&E). The following features were evaluated: vascular congestion, leukocyte infiltration, edema, and alveolar collapse. Analyses were performed by two researchers and the score used to measure the intensity of tissue alterations was 0, 1, 2, 3 (absent, slight, moderate, and intense, respectively).

Statistical analyses

All data are presented as median and upper/lower limits. The overall group differences were compared using a multivariate general linear model with group and time as the factors with a post hoc Bonferroni test. A p-value of less than 0.05 was considered to be significant. All statistical analyses were performed using SPSS for Windows, version 17.0 (SPSS, Chicago, IL, USA).

Results

Hemodynamic parameters

All rats submitted to BD induction showed an immediate increase of the mean arterial blood pressure (MAP) in the first minute after catheter inflation, followed by a decrease in that parameter below baseline for approximately 1h (Figure 1). In sham-operated rats no differences were observed in the MAP. There were no significant differences in heart rate between groups. Moreover, no differences were observed in the arterial blood gases, electrolytes, lactate and hematocrit values in among groups (data not shown).

Histopathological evaluation

All histological parameters evaluated are presented in Table 1. BD rats presented higher level of myocardial vascular congestion at 30, 180, and 360 min compared with sham-operated rats. However, no more significant alterations were observed in this organ after BD induction (Figure 2).

Thumbnail

The score used to measure the intensity of tissue alterations was 0=absente; 1=slight; 2=moderate; 3=intense. Values are presented as median and upper/lower limits for 5-7 rats/group.

In the lungs, vascular congestion was observed from the first 30 min in all groups. This observation was more expressive in BD rats compared with sham-operated rats (Figure 2). Although it was observed a slight to moderate leukocyte infiltration in BD rats, this feature was not statistically different when compared with sham-operated animals (Table 1). Alveolar edema was documented only in BD rats at different time points of observation. Nevertheless, BD rats demonstrated a wide variation in the assessment of alveolar collapse, resulting in no difference when compared with sham groups (Table 1).

Animals submitted to BD show a moderate, but persistent, leukocyte infiltration in the liver, while sham-operated rats did not show this feature (Table 1). Interestingly, intracellular edema and vascular congestion were observed in BD and sham rats with no differences among groups (Figure 2).

In the kidney, BD rats presented more expressive tubular edema than sham-operated rats (Table 1). Kidneys from BD rats presented moderate vascular congestion, whereas sham-operated animals showed slight to moderate levels of this parameter, resulting in no statistical difference among groups (Figure 2).

Discussion

Many studies have been performed to evaluate the role of BD in graft outcomes. However, it remains unclear what is the role of BD-associated trauma in the organs suitable to transplantation. Data presented herein indicate that BD induces a hypertensive episode with MAP values rising twice compared with baseline. We also observed that vascular alterations were a common issue presented in all experimental groups. However, premature and more pronounced histological alterations were observed in BD rats when compared to sham-operated rats, including heart and lung vascular congestion, lung alveolar edema, kidney tubular edema, and liver leukocyte infiltration.

Recently, our group described alterations in the mesenteric perfusion of BD rats associated with higher expression of intercellular adhesion molecule (ICAM)-1, and augmentation of leukocyte migration. These findings suggest that the hypoperfusion triggered by BD, as well as leukocyte infiltration, can impair the viability of remote organs. However, the BD-associated trauma was responsible for increases in serum cytokine levels and neutrophil/lymphocyte ratio which suggest activation of the immunologic system, while these parameters were not significantly influenced by BD itself⁶.

Our findings indicate that histological alterations in the heart, although not so pronounced, seem to be associated with BD induction, as documented by a slight, but significant difference on vascular congestion. In a similar model, but using rabbits, Yeh et al.⁷ found many histological manifestations in the heart, including cytoplasmic clearing, loss of myofibrillar striations and contraction banding. In a model of gradual onset of brain death in rats, Wilhelm et al.⁸ found no morphological alterations in hearts after 6h. Comparing those both publications to our findings, some degree of discrepancies may have occurred due to methodological differences and species particularities.

Brain death leads to damage in the lung function through hemodynamic, inflammatory, and neurohumoral mechanisms⁹. Pulmonary dysfunctions may be associated with other events not related to BD such as aspiration, pneumonia, contusion, and ventilator-induced injury. However, it is known that BD induces a neurogenic pulmonary edema, which can occur immediately after neurological insult³. In this study, BD rats showed an important alveolar edema, which was observed from 30 min after BD induction, while sham operated animals did not present edema up to three hours of mechanical ventilation. In a different model to evaluate edema, Rostron et al.¹⁰ found differences in the lung wet/dry weight ratio two and five hours after BD induction versus sham operated rats. On the other hand, leukocyte infiltration was similar in both conditions at different time points as demonstrated in the present study. Sham-operated rats also presented slight but persistent vascular congestion after 3 hours, although lower than that observed in BD rats. These features indicate that the trauma and the artificial conditions in which patients and animals were maintained can also compromise the lungs, worsening the quality of the organ.

Although kidney and liver transplantation may be performed from living donors, the large patient queues waiting for organ transplantation lead to acceptance of organs from BD donors¹¹. In our study, the liver of BD rats showed higher leukocyte infiltration compared with sham-operated rats. The augmentation of leukocyte migration is in accordance with van der Hoven et al.¹². In that study, rats submitted to BD and observed after one and six hours present an increase in adhesion molecules expression, such as VCAM-1 and ICAM-1, and leukocyte migration to the perivascular tissue. Interestingly, our data additionally showed slight to moderate vascular congestion and intracellular edema in sham-operated rats, indicating that the surgical procedures also induced impairment of the hepatic circulation and cellular damage.

In another study on kidney histology, van der Hoven et al.¹³ found similar results to those observed previously on liver, suggesting that BD induces a progressive immune activation with higher expression of adhesion molecules and influx of leukocytes to perivascular tissue in the kidney. However, in the present study there were no differences in kidney leukocyte migration under BD induction in comparison to sham-operated rats. Nevertheless, moderate tubular edema was observed only in the kidneys of BD groups. Interestingly, BD associated trauma induced an important vascular congestion, similarly to BD itself, also indicating that the associated trauma induces damage on the kidneys.

Conclusions

The brain death leads to hemodynamic instability and vascular changes in all solid organs. The lungs are most severely compromised under this situation due to the development of significant alveolar edema. On the other hand, brain death associated trauma seems to be also responsible for triggering important pathophysiological changes in solid organs.

Conflict of interest: none

Financial source: Sao Paulo Research Foundation (FAPESP)

National Council of Scientific and Technology Development (CNPq)

1 Research performed at Laboratory of Cardiovascular Surgery and Physiopathology of Circulation (LIM-11), Heart Institute (InCor). Part of PhD thesis, Postgraduate Program on Thoracic and Cardiovascular Surgery, Medicine School, University of Sao Paulo (USP), Brazil. Tutor: Luiz Felipe Pinho Moreira.

1) Mascia L, Mastromauro I, Viberti S, Vincenzi M, Zanello M. Management to optimize organ procurement in brain dead donors. Minerva Anestesiol. 2009;75(3):125-33.
2) Salim A, Martin M, Brown C, Rhee P, Demetriades D, Belzberg H. The effect of a protocol of aggressive donor management: Implications for the national organ donor shortage. J Trauma. 2006;61(2):429-33.
3) Bugge JF. Brain death and its implications for management of the potential organ donor. Acta Anaesthesiol Scand. 2009;53(10):1239-50.
4) Domínguez-Roldán JM, García-Alfaro C, Jimenéz-González PI, Hernández-Hazañas F, Gascón Castillo ML, Egea Guerrero JJ. Brain death: repercussion on the organs and tissues. Med Intensiva. 2009;33(9):434-41.
5) Barklin, A. Systemic inflammation in the brain-dead organ donor. Acta Anaesthesiol Scand. 2009;53(4):425-35.
6) Simas R, Sannomiya P, Cruz JW, Correia Cde J, Zanoni FL, Kase M, Menegat L, Silva IA, Moreira LF. Paradoxical effects of brain death and associated trauma on rat mesenteric microcirculation: an intravital microscopic study. Clinics. 2012;67(1):69-75.
7) Yeh T Jr, Wechsler AS, Graham L, Loesser KE, Sica DA, Wolfe L, Jakoi ER. Central sympathetic blockade ameliorates brain death-induced cardiotoxicity and associated changes in myocardial gene expression. J Thorac Cardiovasc Surg. 2002;124(6):1087-98.
8) Wilhelm MJ, Pratschke J, Beato F, Taal M, Kusaka M, Hancock WW, Tilney NL. Activation of the heart by donor brain death accelerates acute rejection after transplantation. Circulation. 2000;102(19):2426-33.
9) Faropoulos K, Apostolakis E. Brain death and its influence on the lungs of the donor: how is it prevented? Transplant Proc. 2009;41(10):4114-9.
10) Rostron AJ, Avlonitis VS, Cork DM, Grenade DS, Kirby JA, Dark JH. Hemodynamic resuscitation with arginine vasopressin reduces lung injury after brain death in the transplant donor. Transplantation. 2008;85(4):597-606.
11) Bos EM, Leuvenink HG, van Goor H, Ploeg RJ. Kidney grafts from brain dead donors: Inferior quality or opportunity for improvement? Kidney Int. 2007;72(7):797-805.
12) van Der Hoeven JA, Ter Horst GJ, Molema G, de Vos P, Girbes AR, Postema F, Freund RL, Wiersema J, van Schilfgaarde R, Ploeg RJ. Effects of brain death and hemodynamic status on function and immunologic activation of the potential donor liver in the rat. Ann Surg. 2000;232(6):804-13.
13) van der Hoeven JA, Molema G, Ter Horst GJ, Freund RL, Wiersema J, van Schilfgaarde R, Leuvenink HG, Ploeg RJ. Relationship between duration of brain death and hemodynamic (in)stability on progressive dysfunction and increased immunologic activation of donor kidneys. Kidney Int. 2003;64(5):1874-82.

Correspondence:

Rafael Simas

Avenida Dr. Arnaldo, 455

01246-903 São Paulo - SP Brasil

Tel./Fax: (55 11)3061-7178

biosimas@usp.br

Publication Dates

Publication in this collection
27 June 2012
Date of issue
July 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1) Mascia L, Mastromauro I, Viberti S, Vincenzi M, Zanello M. Management to optimize organ procurement in brain dead donors. Minerva Anestesiol. 2009;75(3):125-33.

[2] 2) Salim A, Martin M, Brown C, Rhee P, Demetriades D, Belzberg H. The effect of a protocol of aggressive donor management: Implications for the national organ donor shortage. J Trauma. 2006;61(2):429-33.

[3] 3) Bugge JF. Brain death and its implications for management of the potential organ donor. Acta Anaesthesiol Scand. 2009;53(10):1239-50.

[4] 4) Domínguez-Roldán JM, García-Alfaro C, Jimenéz-González PI, Hernández-Hazañas F, Gascón Castillo ML, Egea Guerrero JJ. Brain death: repercussion on the organs and tissues. Med Intensiva. 2009;33(9):434-41.

[5] 5) Barklin, A. Systemic inflammation in the brain-dead organ donor. Acta Anaesthesiol Scand. 2009;53(4):425-35.

[6] 6) Simas R, Sannomiya P, Cruz JW, Correia Cde J, Zanoni FL, Kase M, Menegat L, Silva IA, Moreira LF. Paradoxical effects of brain death and associated trauma on rat mesenteric microcirculation: an intravital microscopic study. Clinics. 2012;67(1):69-75.

[7] 7) Yeh T Jr, Wechsler AS, Graham L, Loesser KE, Sica DA, Wolfe L, Jakoi ER. Central sympathetic blockade ameliorates brain death-induced cardiotoxicity and associated changes in myocardial gene expression. J Thorac Cardiovasc Surg. 2002;124(6):1087-98.

[8] 8) Wilhelm MJ, Pratschke J, Beato F, Taal M, Kusaka M, Hancock WW, Tilney NL. Activation of the heart by donor brain death accelerates acute rejection after transplantation. Circulation. 2000;102(19):2426-33.

[9] 9) Faropoulos K, Apostolakis E. Brain death and its influence on the lungs of the donor: how is it prevented? Transplant Proc. 2009;41(10):4114-9.

[10] 10) Rostron AJ, Avlonitis VS, Cork DM, Grenade DS, Kirby JA, Dark JH. Hemodynamic resuscitation with arginine vasopressin reduces lung injury after brain death in the transplant donor. Transplantation. 2008;85(4):597-606.

[11] 11) Bos EM, Leuvenink HG, van Goor H, Ploeg RJ. Kidney grafts from brain dead donors: Inferior quality or opportunity for improvement? Kidney Int. 2007;72(7):797-805.

[12] 12) van Der Hoeven JA, Ter Horst GJ, Molema G, de Vos P, Girbes AR, Postema F, Freund RL, Wiersema J, van Schilfgaarde R, Ploeg RJ. Effects of brain death and hemodynamic status on function and immunologic activation of the potential donor liver in the rat. Ann Surg. 2000;232(6):804-13.

[13] 13) van der Hoeven JA, Molema G, Ter Horst GJ, Freund RL, Wiersema J, van Schilfgaarde R, Leuvenink HG, Ploeg RJ. Relationship between duration of brain death and hemodynamic (in)stability on progressive dysfunction and increased immunologic activation of donor kidneys. Kidney Int. 2003;64(5):1874-82.