ABSTRACT
Introduction:
This study summarizes the clinical data of patients who developed sternotomy
hemorrhage during redo aortic surgery and analyzes the clinical experience
of using hypothermic circulatory arrest.
Methods:
We retrospectively analyzed the medical records of patients who developed
sternotomy hemorrhage during redo aortic surgery from May 2018 to August
2021. General anesthesia with single-lumen tracheal intubation was used.
Femoral artery, vein, and superior vena cava cannulation were used if
cardiopulmonary bypass was required according to the situation, and right
superior vein or apical cannulation was selected for left heart
drainage.
Results:
A total of 11 patients were enrolled in this study, comprising nine males and
two females, with an average age of 44.3±16.7 years. All cases were
successfully completed without cerebrovascular complications or paraplegia.
Two patients died during hospitalization, two patients died during the
follow-up after discharge, and the remaining patients are recovering
well.
Conclusion:
The femoral-femoral bypass with hypothermic circulatory arrest technique is a
safe and reliable method to use in cases of sternotomy hemorrhage during
redo aortic surgery.
Keywords: Sternotomy, Superior Vena Cava, Catheterization, Intratracheal Intubation, Drainage, Patient Discharge.
Carátula del artículo
Hypothermic Circulatory Arrest in Median Sternotomy Hemorrhage During Redo Aortic Surgery
Department of Cardiovascular Surgery, People’s Republic of China
Department of Pharmacy, People’s Republic of China
Jianshi Liu
Department of Cardiovascular Surgery, People’s Republic of China
Kaitao Jian
Department of Cardiovascular Surgery, People’s Republic of China
Wei Liu
Department of Cardiovascular Surgery, People’s Republic of China
Weiyong Sheng shengweiyong1014@163.com
Department of Cardiovascular Surgery, People’s Republic of China
Brazilian Journal of Cardiovascular Surgery, vol. 38, no. 6, e20220164, 2023
Sociedade Brasileira de Cirurgia Cardiovascular
Received: 09 April 2022
Accepted: 16 March 2023
Funding
Funding source: Yijishan Hospital Affiliated to Wannan Medical
College
Contract number: Y21020
Funding statement: The authors received Three New Projects of Yijishan Hospital
Affiliated to Wannan Medical College (Y21020) for the research of this
article.
INTRODUCTION
With advancement of cardiac surgical techniques and increased life expectancy, the
number of patients who may require redo aortic surgery is increasing. Due to
postoperative changes in tissue adhesions, anatomical structures, and cardiac
physiologic functional status, redo aortic surgery remains a great challenge for
cardiovascular surgeons[1,2]. There are few specific reports
about how to deal with aortic hemorrhage quickly and effectively during sternotomy
in redo aortic surgery. This study summarizes clinical data of patients with
sternotomy hemorrhage in redo aortic surgery, as well as the relevant clinical
experience with femoral-femoral bypass and hypothermic circulatory arrest.
METHODS
We selected a total of 11 patients treated at the Department of Cardiovascular
Surgery of Shanghai DeltaHealth Hospital who underwent redo aortic surgery and
developed sternotomy hemorrhage from May 2018 to August 2021 (Table 1). All cases were diagnosed based on clinical
manifestations, electrocardiogram, echocardiography, and preoperative computed
tomography angiography (CTA) (Figure 1), and
femoral arteriovenous ultrasonography ensured the safety of femoral cannulation. The
indications for redo aortic surgery are given in Table 1. This study was conducted in compliance with the tenets of the
Declaration of Helsinki and was approved by the Ethics Committee of Shanghai
DeltaHealth Hospital (SDH (2018) KYLWPJ 001). All patients provided written informed
consent for using their clinical data for scientific presentations or
publications.
Table 1
Patients’ characteristics.
Fig. 1
Preoperative computed tomography angiography tridimensional image
depicting aortic pseudoaneurysm adherent to the sternum.
Surgical Technique
Right femoral vessels were routinely prepared and exposed with a groin incision
for percutaneous access, and heparin sodium (3 mg/kg) was injected into the
central vein for systemic anticoagulation. An arterial cannula was inserted
through the right femoral artery, and a venous drainage tube was inserted
through the right femoral vein to establish cardiopulmonary bypass (CPB).
Preoperative CTA demonstrated that aortic rupture during sternotomy could not be
avoided in some patients (Figure 1); in
these cases, the external transfer machine was directly cooled to 25ºC, and a
median sternotomy was performed. For patients with aortic valve dysfunction
prior to surgery, the apex of the heart was exposed through a left intercostal
incision and a 3-0 PROLENE™ line with a felt suture purse for transapical left
ventricular drainage. In other patients, aortic bleeding during sternotomy was
possible but not inevitable. These patients underwent free femoral arteriovenous
cannulation prior to sternotomy in preparation for possible sternotomy
hemorrhage. In case of arterial hemorrhage during sternotomy in both patient
types, the sternum was clamped with towel forceps on both sides of the sternum
to control the hemorrhage (Figure 2), and
CPB was started quickly. Rapid infusion and cooling were performed, with an ice
cap on the head, and the head in the down position. Based on the size of the
aortic crevasses and the degree of difficulty of the surgical repair, either
moderate hypothermic circulatory arrest (MHCA) or deep hypothermic circulatory
arrest (DHCA) was performed. The aortic rupture was sutured, or the aortic
crevasse was blocked with a balloon catheter. If the hemorrhage could not be
controlled by the abovementioned methods, the aortic root was freed and blocked;
if freeing the aortic root was difficult, distal aortic anastomosis was
performed by DHCA, then the artificial vessel was blocked after anastomosis.
Once hemorrhage was controlled, circulation was restored, and a drainage tube
was placed in the right upper pulmonary vein or at the apex of the heart. For
mitral valve surgery, a superior vena cava cannula was routinely placed. For
patients who required aortic arch replacement during surgery, routine right
innominate artery cannulation was selected for cerebral perfusion.
Intraoperative left common cervical cerebral perfusion was prepared depending on
cerebral oxygenation. The specific surgical procedures performed on the 11 study
patients are described in Table 2.
Table 2
Patients’ surgical methods, blood component transfusions, and
outcomes.
* Sun’s procedure: total aortic arch replacement and frozen elephant
trunk implantation
Fig. 2
Sternum clamped with towel forceps on both sides to control
hemorrhage.
RESULTS
The average interval between the patients’ previous operation and their last
operation was 7.4±6.2 years. Two patients required emergency surgery; the other
patients underwent elective operations. Operations were successfully completed in
all patients. The mean intraoperative hypothermic circulatory arrest time was
8.8±7.1 minutes, and mean rectal temperature was 17.8±1.9ºC. Complications comprised
one case of bleeding reoperation and two cases of postoperative tracheotomy. There
were no postoperative cerebrovascular complications, paraplegia, low cardiac output,
or other complications. Two patients died during hospitalization: one due to sudden
refractory arrhythmia four days after operation, and the other from active rupture
and hemorrhage of the descending thoracic aorta one month after operation. After
discharge, the mean follow-up time was 23.4 months (range: 5-43 months), and there
were two deaths. One patient died of a sudden intracerebral hemorrhage, and the
other died of an infection. Of the remaining seven patients, two required thoracic
endovascular aortic repair surgery at a later stage, and one developed high fever
and Staphylococcus aureus in blood cultures one year after surgery.
In the latter case, anti-infective treatment was administered for six weeks, and no
fever occurred in the past year. All of these seven patients have recovered well up
until the time of this writing (Table 2).
DISCUSSION
For cardiac surgeons, redo aortic surgery is still a great challenge. One study
reports that in 2555 patients who underwent redo cardiac surgery, compared with
patients without injury during sternotomy, patients with injury had a higher early
mortality (6.5% and 18.6%, respectively[1]), reducing the rate of redo aortic surgery. Complications and
mortality associated with redo aortic surgery are urgent problems for cardiac
surgeons.
In our center, all patients undergoing reoperation of the aorta underwent
preoperative CTA to assess the risk of aortic rupture and hemorrhage during
sternotomy, and to prepare relevant surgical plans. Studies have reported the
importance of accurate preoperative assessment[3]. In this study, all patients were prepared for femoral vein
cannulation before surgery, and for patients in which sternotomy hemorrhage could
not be avoided, we used early cooling with CPB and reduced flow, followed by open
sternotomy. It has been shown that preoperative femoral artery cannulation and
sternotomy after femoral arteriovenous diversion can significantly reduce the risks
associated with surgery and benefit patients[4,5].
In cases of hemorrhage during sternotomy in redo aortic surgery, we currently use CPB
for rapid cooling and circulatory arrest; the effect is satisfactory, with no
cerebral complications and no paraplegia. Studies show that it is safe to stop the
circulation for 15 minutes at medium and low temperatures (20.1-28ºC) and for 30
minutes at deep and low temperatures (14.1-20ºC)[6]. Svensson[7] performed a series of examinations on the use of DHCA in 616
patients undergoing aortic surgery and found a stroke rate of 7% and a mean DHCA
time of 31 minutes (range: 7-120 minutes). Statistical analysis showed that DHCA
times > 45 minutes and > 60 minutes were independent predictors of stroke and
early mortality, respectively. Atik[8] summarized femoral arteriovenous diversion and used cooling
with low flow or deep hypothermia to stop circulation during sternotomy, and no
cases of sternotomy hemorrhage were found. For redo aortic surgery in patients with
preoperative aortic valve insufficiency, if there is a risk of rupture after
sternotomy, transapical left ventricular drainage should be performed in advance, so
that the myocardium can be better protected during the process of circulatory
arrest. Wakefield[9] reported a
patient with severe aortic valve insufficiency who underwent redo surgery and
successful left ventricular apical drainage to prevent ventricular dilatation and
dysfunction. Percutaneous intra-neck puncture was successfully used to place a
retroperfusion catheter through the coronary sinus in the hybrid operation room, and
an aortic balloon was placed through one side of the femoral artery for occlusion to
avoid hypothermic circulatory arrest[9]. Mehta[10]
reported patients with retrosternal aortic aneurysm by percutaneous cardioplegic
arrest before repeat sternotomy to avoid hypothermic circulatory arrest. However,
these methods are complicated and require multidisciplinary cooperation, which is
not suitable for most hospitals.
Regional development has been unbalanced in China, and the volume of redo aortic
surgery tends to increase. At present, our center mainly adopts femoral
arteriovenous cannulation, rapid cooling, and hypothermic circulatory arrest for
arterial hemorrhage during sternotomy in redo aortic surgery. The use of MHCA or
DHCA should be determined based on the size of the rupture, difficulty of repair,
and surgical method utilized. If complicated with aortic regurgitation, and
depending on the situation, apical intubation for left ventricular drainage should
be prepared. In the future, hemorrhage during sternotomy in redo aortic surgery
could be avoided with hypothermic circulatory arrest, which is the goal of cardiac
surgeons.
Limitations
This study had some limitations. First, a small number of patients were reported.
Second, this was a retrospective study, and the data were obtained from a single
institution.
CONCLUSION
According to our clinical result of retrospective cases, we believe that the
femoral-femoral bypass with hypothermic circulatory arrest technique is a safe and
reliable method to use in cases of sternotomy hemorrhage during redo aortic
surgery.
Glossary
AAA: Ascending aortic aneurysms
AAR: Ascending aortic repair
AD: Aortic dissection
AI: Aortic insufficiency
AV: Aortic valve
AVR: Aortic valve replacement
BMI: Body mass index
CPB: Cardiopulmonary bypass
CTA: Computed tomography angiography
DHCA: Deep hypothermic circulatory arrest
DM: Female
HCA: Hypothermic circulatory arrest
HF: Heart failure
M: Male
MHCA: Moderate hypothermic circulatory arrest
MI: Mitral insufficiency
MVR: Mitral valve replacement
TEVAR: Thoracic endovascular aortic repair
Authors’ Roles & Responsibilities
IT: Substantial contributions to the conception or design of the work;or the acquisition, analysis, or interpretation of data; drafting the work; agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
CW: Substantial contributions to the conception or design of the work;or the acquisition, analysis, or interpretation of data; drafting the work; agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
JL: Agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
KJ: Agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
WL: Agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
WS: Revising the work critically for important intellectual content;agreement to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved; final approval of the version to be published
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Notes
Notes
Financial support: The authors received Three New Projects of
Yijishan Hospital Affiliated to Wannan Medical College (Y21020) for the research
of this article.
Conflict of interest declaration
No conflict of interest
Author notes
# These authors contributed equally to this work.
This study was carried out at the Department of Cardiovascular Surgery, The
First Affiliated Hospital of Wannan Medical College (Yijishan Hospital of
Wannan Medical College), Wuhu, Anhui, People’s Republic of China.
Correspondence Address: Weiyong Sheng https://orcid.org/0000-0002-3154-0064, Department of
Cardiovascular Surgery, The First Affiliated Hospital of Wannan Medical College
(Yijishan Hospital of Wannan Medical College) No. 2 West Zheshan Road, Wuhu,
Anhui, People’s Republic of China Zip Code: 241001 E-mail:
shengweiyong1014@163.com
