Keywords
near-death experience - circulatory arrest - hypothermia - aortic surgery
Introduction
Understanding the relationship between mind, consciousness, and the brain is perhaps
one of the greatest challenges for the 21st century neuroscience. Even though the
concept of human consciousness has been investigated by neuroscientists, psychologists,
neurobiologists, and philosophers, its origin remains elusive.[1] The study of near-death experiences (NDE) could provide new prospects in the analysis
of human consciousness and its relationship with the brain.[2] The occurrence of NDE when individuals are unconscious, such as those reported by
cardiac arrest survivors,[3]
[4] raises questions about the real nature of consciousness, and the neurocognitive
process happening upon the approach of death. Circulatory arrest is required to allow
for a bloodless operative field, while hypothermia provides the brain and end-organ
protection by significantly reducing the global metabolic demand.[5]
[6] With a temporary interruption of cerebral and systemic perfusion, aortic surgery
under hypothermic circulatory arrest (HCA) may be the only available model of reversible
clinical death.
Does the circulatory arrest performed during aortic surgery trigger NDE as does spontaneous
cardiac arrest? To date, there is no published data regarding NDE and aortic surgery
under HCA. We present, herein, the results of a prospective study designed to assess
the incidence and characteristics of NDE after thoracic aortic surgery.
Materials and Methods
Study Design
We performed a prospective observational study including consecutive patients who
underwent thoracic aortic surgery, with or without HCA, between July 2018 and September
2019 at our Institution. Patients who underwent aortic surgeries without HCA were
included to create a control group. We obtained ethics committee approval and all
patients gave informed consent.
Surgical Technique
The aortic diseases affecting the patients were degenerative aneurysms or acute Type
A aortic dissection. Surgeries were performed either electively, or on an urgent or
emergent basis. Surgical procedures included aortic hemiarch or total arch replacement,
combined with aortic root or aortic valve replacement when indicated. Operative strategy
was guided by the nature and extent of the aortic disease, and HCA was performed when
an open distal anastomosis was required.
After median sternotomy, cardiopulmonary bypass (CBP) was initiated via the axillary
or the femoral artery, or through direct ascending aorta cannulation.
In case of HCA, systemic cooling was initiated on bypass. After achievement of the
target body temperature, systemic perfusion was discontinued with the patient in the
Trendelenburg position. The patient's head was packed in ice throughout the circulatory
arrest to ensure topical cooling.
Cerebral protection was provided by moderate hypothermia (between 21 and 28°C, as
defined by the current consensus).[7] Adjunctive antegrade cerebral perfusion (ACP) was used when the expected HCA duration
exceeded 30 minutes. ACP was performed through either a bilateral perfusion strategy
(such as by direct cannulation of the brachiocephalic artery and the left common carotid
artery from inside the arch) or a unilateral perfusion strategy (cannulation of the
right axillary artery with cross-clamp of the brachiocephalic artery) with a flow
rate of 10 mL/kg/min. After completion of the aortic repair, the patients were gradually
rewarmed (1°C/5 minutes, with a temperature gradient <10°C) and weaned from CPB.
Anesthesia
A continuous intravenous (IV) lidocaine infusion (1 mg/kg/h) was started prior to
incision after a bolus injection (1.5 mg/kg) and was continued until the end of the
surgery. General anesthesia was induced with IV propofol (2–4 mg/mL) and remifentanil
(2–6 ng/mL), administered with a target-controlled infusion system using the Schnider
and Minto models, respectively.[8] Propofol target-control infusion was used for the maintenance of general anesthesia.
Inhaled anesthetics were not used for maintenance. Low dose IV ketamine (0.10 mg/kg)
was administered to prevent postoperative hyperalgesia. For neuromuscular block, cisatracurium
(0.15 mg/kg) was used. In case of hemodynamic instability prior to induction, general
anesthesia was induced using a combination of etomidate (0.3 mg/kg), sufentanil (0.15
µg/kg), and suxamethonium (1 mg/kg). General anesthesia was induced with etomidate
instead of propofol in seven cases (6.9%).
Monitoring during anesthesia involved continuous electrocardiography, continuous pulse
oximetry, invasive blood pressure monitoring, capnography, and blood gas and electrolyte
measurement at regular intervals. The bispectral index was used to monitor the depth
of anesthesia (target range: 40–60).
If HCA was performed, patients received 1,000 mg of thiopental, 1,000 mg of methylprednisolone,
3,000 mg of sulfate magnesium, and 250 mL of mannitol, prior to the circulatory arrest.
Acid–base balance was managed with the α-stat method. Temperature monitoring was conducted
with esophageal and bladder probes. Near-infrared spectroscopy was used to assess
symmetry of cerebral perfusion. No anesthetic was provided during circulatory arrest.
Emergence from general anesthesia was allowed in the intensive care unit after at
least 3 hours from the end of the surgical procedure, mainly to ensure hemodynamic
stability and the absence of bleeding.
Near-Death Experiences Evaluation
In the absence of hemodynamic instability or cognitive impairment, we performed a
standardized interview of the patients in the surgical ward starting from postoperative
day 4. Information about the study was delivered to the eligible patients only after
the surgery, during the postoperative course. The interviews were conducted by a single
physician. Patients were asked if they remembered the period of unconsciousness, and
what they recalled. They were then given the Greyson NDE scale, a standardized 16-item
multiple choice questionnaire used to discriminate patients who experienced NDE from
those who did not.[9] The scale is divided into questions about cognitive processes, affective processes,
purportedly paranormal elements, and transcendental elements. The Greyson NDE scale
used in the study is indicated in [Table 1]. This translation of the Greyson scale was used in previous studies conducted in
French.[10]
Table 1
The Greyson near-death experience scale
|
1. Did time seem to speed up or slow down?
0 = No
1 = Time seemed to go faster or slower than usual
2 = Everything seemed to be happening at once; or time stopped or lost all meaning
|
|
2. Were your thoughts speeded up?
0 = No
1 = Faster than usual
2 = Incredibly fast
|
|
3. Did scenes from your past come back to you?
0 = No
1 = I remembered many past events
2 = My past flashed before me, out of my control
|
|
4. Did you suddenly seem to understand everything?
0 = No
1 = Everything about myself or others
2 = Everything about the universe
|
|
5. Did you have a feeling of peace or pleasantness?
0 = No
1 = Relief or calmness
2 = Incredible peace or pleasantness
|
|
6. Did you have a feeling of joy?
0 = No
1 = Happiness
2 = Incredible joy
|
|
7. Did you feel a sense of harmony or unity with the universe?
0 = No
1 = I felt no longer in conflict with nature
2 = I felt united or one with the world
|
|
8. Did you see, or feel surrounded by, a brilliant light?
0 = No
1 = An unusually bright light
2 = A light clearly of mystical or other-worldly origin
|
|
9. Were your senses more vivid than usual?
0 = No
1 = More vivid than usual
2 = Incredibly more vivid
|
|
10. Did you seem to be aware of things going on elsewhere, as if by extrasensory perception?
0 = No
1 = Yes, but the facts have not been checked out
2 = Yes, and the facts have been checked out
|
|
11. Did scenes from the future come to you?
0 = No
1 = Scenes from my personal future
2 = Scenes from the world's future
|
|
12. Did you feel separated from your body?
0 = No
1 = I lost awareness of my body
2 = I clearly left my body and existed outside it
|
|
13. Did you seem to enter some other, unearthly world?
0 = No
1 = Some unfamiliar and strange place
2 = A clearly mystical or unearthly realm
|
|
14. Did you seem to encounter a mystical being or presence, or hear an unidentifiable
voice?
0 = No
1 = I heard a voice I could not identify
2 = I encountered a definite being, or a voice clearly of mystical or unearthly origin
|
|
15. Did you see deceased or religious spirits?
0 = No
1 = I sensed their presence
2 = I actually saw them
|
|
16. Did you come to a border or point of no return?
0 = No
1 = I came to a definite conscious decision to “return” to life
2 = I came to a barrier that I was not permitted to cross or was “sent back” against
my will
|
Note: Sum of all 16 items = total near-death experience scale score. A score of 7
or higher is considered as NDE.
Definitions
Patients were divided into two groups: the “HCA group,” including patients who underwent
HCA during the aortic reconstruction and the “control group,” including patients who
underwent thoracic aortic procedures without HCA.
The primary outcome of interest was the incidence of NDE during aortic surgery. The
secondary outcomes were the identification of risk factors for the occurrence of NDE,
the characterization of NDE, and the occurrence of any out-of-body experience. The
main postoperative outcomes, including 30-day mortality, stroke, and neurologic disturbance,
are reported.
An NDE experiencer was defined as a patient who scored 7 or more on the Greyson NDE
scale, according to the current consensus.[9]
[10]
A 30-day mortality was defined as death occurring during the index hospitalization
or within the 30th postoperative day if occurring after discharge. Stroke was defined
as the onset of a new focal or global neurological deficit, or coma, with computed
tomography or magnetic resonance imaging demonstration of a new ischemic/hemorrhagic
lesion during the postoperative course. Temporary neurologic disturbance was defined
as postoperative confusion, delirium, or seizure with normal cerebral imaging. Shock
was defined as persistent hypotension requiring the administration of catecholamines
to keep mean arterial blood pressure above 65 mm Hg
Statistics
Continuous and categorical variables are presented as mean with standard deviation
or median with ranges and frequencies with percentage, respectively. Statistical tests
were not performed in this study.
Results
Patients and Operative Data
A total of 101 patients were consecutively included in this study. The mean age was
63.5 ± 11.9 years and 67 (78.2%) were male. Detailed patients' characteristics are summarized
in [Table 2]. Nine patients had a psychiatric history and 14 had a preoperative neurological
disorder. Twenty-one patients (20.8%) underwent nonelective interventions for aortic
dissection.
Table 2
Preoperative conditions
|
Variables
|
Overall (n = 101)
|
HCA group (n = 67)
|
Control group (n = 34)
|
|
n
|
%
|
n
|
%
|
n
|
%
|
|
Demographic data:
|
|
|
|
|
|
|
|
Age (y)
Mean ± SD
|
63.5 ± 11.9
|
63.7 ± 12.0
|
63.1 ± 11.9
|
|
Male sex
|
67
|
78.2
|
49
|
73
|
30
|
88.2
|
|
Comorbidities:
|
|
|
|
|
|
|
|
Neurologic disorder
|
14
|
13.8
|
7
|
10.4
|
7
|
20.6
|
|
Psychiatric disease
|
9
|
8.9
|
5
|
7.4
|
4
|
11.7
|
|
Aortic pathology:
|
|
|
|
|
|
|
|
Acute Type A dissection
|
21
|
20.8
|
21
|
31.3
|
0
|
0
|
|
Elective surgery (aneurysm)
|
80
|
79.2
|
46
|
68.6
|
34
|
100
|
Abbreviations: HCA, hypothermic circulatory arrest; SD, standard deviation.
Ninety-one patients had hemiarch replacement (90.1%). Total arch replacement was required
in 10 (9.9%) cases.
The average duration of surgery, myocardial ischemia time, and general anesthesia
duration were 302.7 ± 101.6 minutes, 112.1 ± 39.2 minutes, and 14.4 ± 12.1 hours,
respectively.
Thirty-four interventions were performed without HCA. For the 67 aortic procedures
with HCA, the average circulatory arrest duration was 26.9 ± 25.5 minutes, with a
mean body temperature of 23.7 ± 3.8°C. ACP was used in 31.3% (n = 21) of the interventions with HCA (unilateral ACP in 6 and bilateral ACP in 15;
[Table 3]).
Table 3
Operative data
|
Variables
|
Overall (n = 101)
|
HCA group (n = 67)
|
Control group (n = 34)
|
|
n
|
%
|
n
|
%
|
n
|
%
|
|
Aortic procedure:
|
|
|
|
|
|
|
|
Hemiarch replacement
|
91
|
90.1
|
57
|
85.1
|
34
|
100
|
|
Total arch replacement
|
10
|
9.9
|
10
|
14.9
|
0
|
0
|
|
Times:
|
Mean ± SD
|
Mean ± SD
|
Mean ± SD
|
|
Surgical procedure (min)
|
302.7 ± 101.6
|
304.3 ± 88.4
|
299.3 ± 124.9
|
|
Myocardial ischemia (min)
|
112.1 ± 39.2
|
111.5 ± 38.9
|
113.5 ± 40.4
|
|
General anesthesia (h)
|
14.4 ± 12.1
|
15.7 ± 13.7
|
11.9 ± 7.8
|
|
Circulatory arrest details:
|
|
|
|
|
Arrest temperature (°C)
|
ND
|
23.7 ± 3.8
|
ND
|
|
HCA time (min)
|
ND
|
26.9 ± 25.5
|
ND
|
|
Procedures with ACP
n (%)
|
ND
|
21
|
31.3
|
ND
|
Abbreviations: ACP, antegrade cerebral perfusion; HCA, hypothermic circulatory arrest;
ND, no data; SD, standard deviation.
During the postoperative course, 29.7% (n = 30) of the patients received nonbenzodiazepine hypnotics for short-term treatment
of insomnia (either zopiclone 7.5 mg or zolpidem 10 mg), 28.7% (n = 29) of them received benzodiazepines (alprazolam 0.25–0.50 mg or bromazepam 1.5–6 mg).
Both nonbenzodiazepine hypnotics and benzodiazepines were administered in 8.6% of
cases (n = 9).
Postoperative Outcomes
There was no death at 30 days. The postoperative stroke rate was 1.9% (n = 2). Temporary neurologic disturbance was described in 15 (14.8%) patients. Early
reintervention for bleeding was required in 16 (15.8%) cases. The mean intensive care
unit stay was 3.4 days. The postoperative outcomes are summarized in [Table 4].
Table 4
Postoperative outcomes
|
Variables
|
Overall (n = 101)
|
HCA group (n = 67)
|
Control group (n = 34)
|
|
n
|
%
|
n
|
%
|
n
|
%
|
|
30-day mortality
|
0
|
0
|
0
|
|
0
|
0
|
|
Stroke
|
2
|
1.9
|
1
|
1.5
|
1
|
2.9
|
|
Seizure
|
3
|
2.9
|
3
|
4.5
|
0
|
0
|
|
Confusion
|
12
|
11.9
|
9
|
13.4
|
3
|
8.8
|
|
Reintervention for bleeding:
|
16
|
15.8
|
13
|
19.4
|
3
|
8.8
|
|
Shock
|
3
|
2.9
|
1
|
1.5
|
2
|
5.9
|
|
ICU duration (d)
Mean ± SD
|
3.4 ± 2.3
|
3.5 ± 2.2
|
3.3 ± 2.6
|
Abbreviations: HCA, hypothermic circulatory arrest; ICU, intensive care unit; SD,
standard deviation.
Near-Death Experiences Evaluation
The interviews were performed in the surgical ward between postoperative day 4 and
day 9 (5.5 ± 2.3 days; median, 5 days) and lasted 15 minutes, on average. None of
the patients reported any recollection of their period of unconsciousness. There was
no NDE experiencer in the study cohort.
Discussion
NDE are subjective experiences involving the memory of impressions during a particular
state of consciousness, including pleasant feelings, acceleration or slowing of time,
the sight of a tunnel or a light, the sensation of reliving elements of the past,
or seeing deceased relatives.[4]
[11] Ring[12] identified a common framework for NDE through structured interviews of NDE experiencers,
and described five successive stages: feeling of peace and wellbeing, separation of
the body, entering a “tunnel-like” dark area, seeing a bright light, and entering
the light. To identify NDE, Ring first developed the “weighted core experience index,”
which was further refined by Greyson,[9] arguing that the components of Ring's scale lacked specificity.[3] The Greyson NDE scale has demonstrated good reliability and internal consistency
and is commonly used in the literature.[13]
Three major theories have been suggested in an attempt to explain the occurrence of
NDE as follows: (1) the physiological changes that accompany the death process, (2)
an adaptive dissociative mechanism in response to the death threat, or (3) the onset
of a transcendental experience.[3] Several physiological factors have been considered as potential mediators of NDE,
such as cerebral hypoxia, hypercarbia, endorphins, ketamine and N-methyl-D-aspartate
(NMDA) receptors, serotonin signaling pathways, limbal system activation, or anoxic
seizures of the temporal lobe.[14]
[15]
[16] Despite these theoretical approaches, the origin of NDE remains elusive for the
scientific community.
The majority of NDE experiencers are found among cardiac arrest survivors. Prospective
studies among this specific population report an incidence ranging from 6 to 12% of
NDE.[4] Data from animal studies demonstrated an isoelectric electroencephalogram (EEG)
within 10 to 20 seconds from the onset of the cardiac arrest.[17] The description of NDE during circulatory arrest with structured thoughts, feelings,
emotions, and self-awareness, even though there is no indicator of brain activity,
raises many questions about the nature of human consciousness and the relationship
between the brain and consciousness.[18]
Aortic surgery with HCA was thought to be a potential reversible model of “clinical
death,” which could provide insight into the potential process happening upon the
approach of death. During HCA, patients fulfil the criteria of clinical death, with
no brain perfusion, and no spontaneous or artificial ventilation.[19] Indeed, hypothermia reduces tissue oxygen and metabolic demand to the extent that
systemic perfusion may be interrupted for limited periods.[20]
To differentiate the confounding effects of general anesthesia from the consequence
of circulatory arrest, patients who had thoracic aortic surgery both with and without
HCA were included in our study. In the scientific literature, few cases of NDE during
general anesthesia are reported and they may be distinguished from “intraoperative
awareness.”[21] Awareness refers to a recall of real facts that actually happened during anesthesia
and may be related to inadequate narcosis, contrary to NDE, which is about a subjective
experience.
In our cohort, no NDE was reported by the patients. Several factors might explain
this negative result. First of all, the hypnotic agents and analgesics used during
general anesthesia may induce retrograde amnesia, or merely prevent NDE, although
some NDE during anesthesia have previously been described.[21] The potential influence of modified neurotransmitter release and systemic inflammatory
response induced by the CPB, along with the varying degrees of ischemia/reperfusion
during aortic surgery, should also be taken into consideration.[22] The duration of unconsciousness in our study (14.4 hours on average), inherent to
the prolonged general anesthesia, might prevent the patient from remembering NDE events.
Furthermore, the time between awakening from anesthesia and the patient's interviews
might have been too long, though in the study by van Lommel et al,[4] NDE memories did not fade out with time, as most NDE experiencers were able to retell
accurately their experience 2 years later. The number of patients included in our
study might also be too limited to evidence NDE, although the incidence rates reported
among cardiac arrest survivors suggest that such cohort size should be adequate.[3]
The level of hypothermia and the optional use of adjunctive cerebral perfusion during
circulatory arrest might also play a crucial part. Keenan et al[23] monitored EEG during 71 aortic arch replacement with HCA and ACP. They highlighted
an immediate loss of electrocerebral activity after circulatory arrest in 45% of the
patients which was rapidly restored with the establishment of selective cerebral perfusion,
except for two patients. Nonetheless, the core temperature in our study was below
the threshold used in their cohort (27.8 vs. 23.7°C). Indeed, a continuous EEG pattern
before the initiation of circulatory arrest was observed in 66% of the patients, while
34% presented a burst suppression pattern. Stecker and colleagues[24] described the neurophysiologic changes during cooling before circulatory arrest
and found that EEG burst suppression appeared at 24.4 ± 4°C, and electrocerebral silence
at 17.8 ± 4°C. It should be kept in mind that although NDE are supposed to be experienced
“during a period of clinical death with flat EEG,” an isoelectric EEG might not be
a necessary condition for the onset of NDE. Besides, the absence of NDE in our cohort
precludes any analyses about the potential impact of ACP during HCA. EEG was also
not monitored in our study. Furthermore, hypothermia reduces the release of excitatory
neurotransmitters such as glutamate.[25]
Conclusion
No patients reported NDE after thoracic aortic surgery, with or without HCA. Several
confounding factors regarding anesthesia, or NDE evaluation, might have impaired the
chance of NDE recollection. Thus, whether HCA may trigger NDE remains unknown. Nevertheless,
the field of cardiothoracic surgery, with its inherent control over cerebral and systemic
perfusion, might still be considered for a study model to grasp some aspect of the
complex reality of death.
I suspect that many of us have wondered what our patients experience during deep hypothermic
circulatory arrest (DHCA). I have applied this technique thousands of times, all without
any cerebral perfusion (i.e., “straight” DHCA), and I have often contemplated what
the experience may be like from the patient's point of view.
During my training, decades ago, cardiac arrest and resuscitation were quite common
after cardiac surgery. I remember a patient waking up intermittently, and looking
at me and talking to me, as I massaged her heart after reopening her sternotomy. Patients
often did report near-death experiences (NDEs) after cardiopulmonary resuscitation.
But no patient has reported to me an NDE after DHCA.
I am especially interested in this topic, because I myself experienced an NDE. When
I was 20 years old, my classmate and I were driving in two different cars from Yale
University to Vassar College, as we did most weekends. We often made those weekend
trips in the days before the Ivy League schools became coeducational. It was a fall
New England day, and the temperature was in the low 30's (Fahrenheit) --near freezing.
My classmate was driving a 1988 Mustang GT500 Shelby Cobra 428, and I was in my 1967
Corvette Stingray 327. We often drove very fast, essentially racing each other on
public roads. It began to rain. We were on a small, winding, two-lane country road.
There was a narrow bridge just up ahead. My classmate was ahead of me. I saw his car
start to fishtail as he entered onto the bridge. I braked my car, surmising that the
light rain was freezing on the bridge surface. I wanted to slow my speed, to avoid
any issue on the bridge. Instead, my car also fishtailed, and within a moment, it
was completely out of control on the narrow, icy bridge. In fact, it was traveling
directly backwards toward the bridge. I had no control of the car whatsoever. I remember
this event as if it was yesterday. My first thought, in real time, was that this beautiful
fiberglass Corvette would be shattered. Right after that thought, I realized I was
about to die. There was no doubt at all in my mind. In the next few moments, I literally
saw my whole life (all 20 years) flash before my eyes. It seemed that I re-lived every
moment at warp speed. Ultimately, the car did not crash. It stopped on its own, parallel
parking perfectly only inches from the feeble wall of the bridge --without a scratch.
I got out of the car with the help of my classmate. I was shaking. I could not stand.
My knees could not hold me. Eventually, I regained some composure and we continued
our road trip --a bit more slowly.
This memory is absolutely etched in my mind, even now, many decades after its occurrence.
NDE is often ascribed to brain hypoperfusion due to hemodynamic abnormalities. My
experience was devoid of any physical abnormalities. My body was physically fine.
Rather, this was solely an emotional experience, inducing a powerful NDE.
This personal experience, along with my having employed DHCA thousands of times, had
always made me wonder if patients had any NDE-type sensations related to their surgery
under DHCA.
The article by Mauduit and colleagues takes a careful, precise, thorough look at this
issue. They find no evidence of NDE after DHCA.
