Daily systemic energy expenditure in the acute phase of aneurysmal subarachnoid hemorrhage


ARTICLE

Daily systemic energy expenditure in the acute phase of aneurysmal
subarachnoid hemorrhage

Christoffer Nyberga, Elisabeth Ronne Engstr€oma, Lars Hillereda and Torbj€orn Karlssonb

aDepartment of Neuroscience, Section of Neurosurgery, Uppsala University, Uppsala, Sweden; bDepartment of Surgical Sciences, Section of
Anesthesiology and Intensive Care, Uppsala University, Uppsala, Sweden

ABSTRACT
Background: Patients with subarachnoid hemorrhage often have impaired consciousness and cannot
regulate nutritional intakes themselves. Previous studies have demonstrated elevated energy expend-
iture in the acute phase, but it is not known whether the energy demand is constant during the first
week after onset of the disease. In this study, we performed daily measurements of energy expend-
iture with indirect calorimetry during the first 7 days after aneurysmal subarachnoid hemorrhage in
mechanically ventilated patients.
Methods: Metabolic measurements were performed daily with indirect calorimetry in 26 patients with
aneurysmal subarachnoid hemorrhage. All patients were intubated and mechanically ventilated. The
measured value was compared to the predicted values from the Harris–Benedict equation and the
Penn State University 1998 equation. Urinary nitrogen excretion was measured daily.
Results: There was a significant increase in energy expenditure during days 2–3 compared to days
5–6. The Harris–Benedict equation underestimated metabolic demand. The Penn State 1998 equation
was closer to the measured values, but still underestimated caloric need. Urinary nitrogen excretion
increased throughout the first week from initially low values.
Conclusions: There is a dynamic course in energy expenditure in patients with aneurysmal subarach-
noid hemorrhage, with increasing metabolic demand during the first week of the disease. Indirect cal-
orimetry could be used more often to help provide an adequate amount of energy.

ARTICLE HISTORY
Received 11 January 2019
Revised 14 August 2019
Accepted 20 August 2019

KEYWORDS
Energy expenditure; indirect
calorimetry; subarach-
noid hemorrhage

Introduction

Spontaneous subarachnoid hemorrhage (SAH) is a potentially
life-threatening condition that activates a stress response.
This in turn triggers numerous events that prepares the body
to meet the challenges of severe illness, including activation
of the hypothalamic-pituitary-adrenal axis and of the sympa-
thetic nervous system (1,2). The stress response also may
influence the patient’s metabolic demand.

Apart from the initial impact at the time of onset of dis-
ease, there are several severe complications (e.g. vasospasm,
rebleeding, hydrocephalus, and infections) that may affect
energy expenditure (EE) in the acute phase. In critically ill
patients, who cannot regulate nutritional intake themselves,
nutritional treatment is especially important. It has previously
been shown that the nutritional balance may have impact
on the outcome after stroke (3,4). Underfeeding as well as
overfeeding may affect outcome.

Predictive equations to estimate the nutritional need have
been developed and refined since the early 1900s. The ori-
ginal equation by Harris and Benedict (H-B) from 1919 is still
being used to calculate the basal metabolic rate (5). Several
attempts have been made to make more accurate predictive
equations, taking into account different factors that may

influence energy balance. A patient with severe illness, sed-
ation, and a need for mechanical ventilation presents an even
more complex challenge. Numerous ways to predict EE in this
heterogeneous group have been suggested. The equation
from Penn State 1998 (PSU-98) (6) has previously been shown
to correlate with measurements by indirect calorimetry (IC)
for patients with severe traumatic brain injury (7). In this
equation, H-B is combined with body temperature and
respiratory minute volume to compensate for increased
metabolism caused by the systemic inflammatory response.

IC is currently considered to be the most precise and
widely available method for measuring EE in critically ill
patients (8). However, the equipment is expensive, and in
most centers IC is not routinely used. Measurements with IC
on patients with hemorrhagic stroke have been reported. In
most of these studies, single short measurements have been
performed once or twice during the acute stage of the dis-
ease (9–14). In patients with SAH, measured EE has generally
then been elevated compared to the energy demand pre-
dicted by equations.

The aim of this study was to investigate EE during the
first week in patients with aneurysmal SAH. We carried out
daily measurements with indirect calorimetry during the first

CONTACT Christoffer Nyberg christoffer.nyberg@neuro.uu.se Department of Neurosurgery, Uppsala University Hospital, 751 85 Uppsala, Sweden
� 2019 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use,
distribution, and reproduction in any medium, provided the original work is properly cited.

UPSALA JOURNAL OF MEDICAL SCIENCES
2019, VOL. 124, NO. 4, 254–259
https://doi.org/10.1080/03009734.2019.1659888

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week after onset of SAH to investigate if EE had a dynamic
course. Daily urinary nitrogen excretion was measured to
estimate protein catabolism. We also performed comparisons
between measured and calculated EE using predict-
ive equations.

Materials and methods

Patients and SAH management

Patients were included from October 2010 until July 2014.
Mechanically ventilated patients with spontaneous SAH were
considered for inclusion. Twenty-six patients were included
with at least two measurements using indirect calorimetry
during the first week after SAH. The patients were managed
according to the Department of Neurosurgery’s protocols for
SAH (15). Briefly, this includes early diagnosis and treatment
of aneurysm. Patients with impaired consciousness were intu-
bated and normo-ventilated. A ventricular catheter was
placed for drainage of cerebrospinal fluid and monitoring of
intracranial pressure. Sedation in mechanically ventilated
patients was obtained, mainly with propofol and bolus doses
of morphine. Enteral nutrition was administered through a
gastro-enteral tube. Intravenous nutrition was only used in
selected cases. Nimodipine was administered for three
weeks. Symptoms of delayed cerebral ischemia were consid-
ered to be due to vasospasm when other causes of deterior-
ation were ruled out. Vasospasm treatment was then given
with increase in blood volume and blood pressure and in
selected cases intra-arterial administration of nimodipine.
Secondary insults putting further strain on the brain’s supply
and use of energy and oxygen were systematically detected
and treated if present (16). The Uppsala University Regional
Ethical Review Board for clinical research granted eth-
ical permission.

Predictive equations

Calculations of the metabolic rate (R; kcal/day) were done for
each patient with the Harris–Benedict equation, the Penn
State 1998 equation, and by using 25 kcal per kilogram body
weight.

H-B men: R ¼ 66:473 þ ð13:7516 � WÞ
þ ð5:0033 � LÞ � ð6:755 � AÞ (1)

H-B women: R ¼ 655:0955 þ ð9:5634 � WÞ
þ ð1:8496 � LÞ�ð4:6756 � AÞ (2)

Penn State 1998: R ¼ ð1:1 � Harris–BenedictÞ
þ ð140 � TmaxÞ þ ð32 � _VEÞ–5:340

(3)

where W is weight in kg, L is height in cm, A is age in years,
Tmax is maximum temperature in

�C in the past 24 hours, and
V_E is minute volume in L/min.

Metabolic measurements

The energy expenditure was determined by measurements
with the indirect calorimeter Quark RMR (COSMED, Rome,
Italy). Before each measurement, the equipment was cali-
brated according to instructions from the manufacturer. The
measurements lasted for approximately 4.5 hours. Records
without V_O2 and V_CO2 values were removed. In order to
exclude invalid measurements, values were removed that
deviated more than two standard deviations from the mean.
From the resulting data, daily energy expenditure was calcu-
lated by taking the median from all collected data points.

Measurements were started as soon as possible after
admission, typically on the day after admission, and contin-
ued daily throughout the first week after SAH, or until the
patient was no longer mechanically ventilated or had respira-
tory problems requiring >50% FiO2. On some occasions,
patients were unavailable for measurements because of
time-consuming examinations or surgical procedures.

In order to compare metabolic measurements between
patients, the ratio of the measured value to H-B was calcu-
lated. Ratios of the measured values were also calculated to
the PSU-98 estimates of EE, and to body weight. To be able
to compare early and late measurements despite the fact
that some patients were missing measurements, the mean of
days 2–3 and the mean of days 5–6 were calculated for
all patients.

Urine was collected for 24 hours repeatedly and analyzed
for urea by the routine method used in the hospital chemis-
try department. From this value, daily urinary nitrogen excre-
tion was calculated.

Statistics

Statistical analyses were performed with R (R Foundation for
Statistical Computing, Vienna, Austria). Changes in EE and
nitrogen excretion over the entire time period were eval-
uated with the Skillings–Mack test. Wilcoxon matched pairs
test was used to compare early and late measurements in
days 2–3 and days 5–6. Values of P < 0.05 were considered
statistically significant.

Results

The mean age of the included patients was 59 years (range
41–81). Eighteen patients were of female gender. World
Federation of Neurosurgical Societies SAH grade (17) at
admission was I in 1 patient, II in 5 patients, III in 1 patient,
IV in 15 patients, and V in 4 patients. All patients were diag-
nosed as having a ruptured aneurysm. The aneurysms were
located in the anterior circulation in 21 patients, and in the
posterior circulation in 5 patients. The aneurysms were
treated with endovascular methods in 22 patients and with
open surgery in 4 patients. Fourteen patients were conscious
at discharge from the neurosurgical unit, 9 patients were
unconscious, and 3 patients died before discharge.

In total, 118 IC measurements were performed during the
first week after onset of SAH. The measured values increased

UPSALA JOURNAL OF MEDICAL SCIENCES 255



in the later part of the first week (Figure 1). When comparing
days 2–3 with days 5–6, the difference was statistically sig-
nificant (P ¼ 0.017).

Measured values versus predictive equations

For each patient and IC measurement, the ratio of IC to the
expected value was calculated using the H-B equation
(Figure 2) and the PSU-98 equation (Figure 3).

The ratio of IC to the H-B equation increased during the
first week after SAH, peaking at day 6 when the measured
value was about 60% higher than expected. There was a dif-
ference between days 2–3 and days 5–6, P ¼ 0.020. The ratio
of measured IC to the PSU-98 equation also increased in a
similar manner. The variations were, however, smaller than
with the H-B equation. On the day with the peak value,
day 6, the measured value was less than 20% higher
than expected.

Figure 1. Daily EE measured with indirect calorimetry. Significance testing over time with the Skillings–Mack test, P ¼ 0.030. Median with 25%–75% interquartile
range and minimum–maximum values.

Figure 2. EE measured with indirect calorimetry related to the Harris–Benedict equation. Significance testing over time with the Skillings–Mack test, P ¼ 0.030.
Median with 25%–75% interquartile range.

256 C. NYBERG ET AL.



The EE as measured with IC was also calculated to kg of
body weight (Figure 4). EE was close to 25 kcal/kg in the first
measurements and increased to more than 30 kcal/kg on
day 6.

Urinary nitrogen excretion

From initially low values on the second and third day after
SAH, there was a distinct increase throughout the first week
(Figure 5).

Discussion

Many patients with acute aneurysmal hemorrhage have
impaired consciousness and cannot regulate their nutritional
intake. Ensuring these patients an adequate caloric intake
may be one factor affecting the outcome. To better under-
stand their caloric requirements, we performed a study with
repeated measurements using IC during the first week after
SAH. To our knowledge, this is the first study with this high
number of patients and daily repeated measurements with
IC during the first 7 days after SAH.

Figure 3. EE measured with indirect calorimetry related to the Penn State 1998 equation. Significance testing over time with the Skillings–Mack test, P ¼ 0.12.
Median with 25%–75% interquartile range.

Figure 4. EE measured with indirect calorimetry related to body weight. Significance testing over time with the Skillings–Mack test, P ¼ 0.041. Median with
25%–75% interquartile range.

UPSALA JOURNAL OF MEDICAL SCIENCES 257



One difficulty when comparing EE between and within
patients is the fact that the basal metabolism varies with
multiple factors such as age, body weight, height, gender,
and systemic inflammatory state. In order to be able to com-
pare measured EE in this group of patients, we used the
ratio of measured EE to the H-B equation. The predicted EE
with the H-B equation is constant during the first week, since
it is based on constant or slowly changing factors. This
means that the calculated ratio can be used not only to
compare EE within patients during the first week after SAH,
but also between patients. This calculation can also be used
to compare EE measured with IC to the expected value from
the H-B equation. From our results, it seems clear that the H-
B equation underestimates the metabolic demand in this
patient group. Since the H-B equation was developed for
prediction of the basal metabolic rate in healthy individuals,
it is not surprising that the equation does not apply without
modification on patients with severe illness.

We performed the same type of calculation with another
predictive method, the PSU-98 equation. This is one of the
equations developed to predict caloric need in an intensive
care unit (ICU) setting. It is based on the H-B equation, but
also includes information about respiration and body tem-
perature to compensate for the increased metabolism caused
by the systemic inflammatory response. Our results indicate
that the PSU-98 equation may underestimate EE in patients
with SAH, although the difference between predicted and
calculated EE is smaller than when the H-B equation is used.
Also, the increase in EE that we found during the course of
the disease was accounted for by the PSU-98 equation since
no significant difference was found. This suggests that the
PSU-98 equation is a better alternative than the H-B equation
for this patient group. The variation between patients is still

substantial, and the perfect predictive equation for SAH
patients is yet to be found.

One way of deciding how much energy to provide to a
patient in intensive care is to estimate 25 kcal per kg body
weight (18). This calculation is most likely widely used
because of its simplicity. With the patients in this study,
using the 25 kcal/kg equation underestimates EE, especially
in the later part of the first week. On day 6, measured EE
was above 30 kcal/kg.

Urinary nitrogen excretion can be used as an indicator of
protein turnover. Our measurements showed low nitrogen
excretion the first days after onset of disease. Thereafter,
there seemed to be a linear increase in nitrogen excretion. A
similar pattern has been demonstrated in plasma measure-
ments in previous studies (19). One possible interpretation is
a shift in protein metabolism towards catabolism. Whether
the possible catabolic state is only due to the disease itself is
unclear. The increase in EE during the acute phase after SAH
is almost parallel to nitrogen excretion, raising the suspicion
that the proteolytic state could be enhanced by underfeed-
ing. In this study, we did not collect detailed information
about nitrogen intake. This means we cannot rule out high
protein intake as a factor influencing nitrogen excretion, but
the measurements of EE or nitrogen excretion did not influ-
ence the type of nutrition or energy provided to the
patients. One factor possibly contributing to the low values
the first day is the fact that enteral nutrition in our unit is
not provided the first day after onset of disease, thereby
causing low protein metabolism.

Measured EE increased gradually during the first 6 days,
and there was a significant difference in EE between days
2–3 compared to days 5–6, in line with recent investigations
(14). An increase in metabolic demand could be expected

Figure 5. Daily nitrogen excretion in urine. Significance testing over time with the Skillings–Mack test, P < 0.001. Median with 25%–75% interquartile range.

258 C. NYBERG ET AL.



after an intracranial aneurysm rupture and the subsequent
triggering of a stress response. The findings in this study
suggest that EE has a dynamic course after SAH, and it is dif-
ficult to rely on a predictive equation to determine nutri-
tional requirements. In order to provide an adequate amount
of energy to SAH patients, it would be beneficial to routinely
use IC. Our results illustrate that a single measurement with
IC is only valid on the day of the measurement and cannot
be used universally during the first week after SAH.

There are some limitations of our study. The metabolic
measurements with IC was only performed on mechanically
ventilated patients, meaning that mostly poor-grade patients
were included. Furthermore, the limited number of patients
in the study made it impossible to compare between differ-
ent groups of patients based on treatment modality, compli-
cations, and outcome.

We conclude that energy expenditure in mechanically
ventilated patients with aneurysmal SAH increases gradually
during the first week after SAH. Prediction of metabolic
demand with equations is often unreliable. In this study, the
PSU-98 equation performed best of those tested but, on the
whole, underestimated EE. These results suggest that IC
could be beneficial in patients with SAH and mechanical
ventilation.

Acknowledgements

We would like to thank the staff in the neurointensive care unit for help-
ing with the measurements.

Disclosure statement

No potential conflict of interest was reported by the authors.

Notes on contributors

Christoffer Nyberg is a neurosurgeon and neurointerventionist at
Uppsala University Hospital.

Elisabeth Ronne-Engstr€om is an adjunct professor of Neurosurgery at
Uppsala University Hospital.

Lars Hillered is a professor of Neurosurgery at Uppsala
University Hospital.

Torbj€orn Karlsson is an associate professor of Anesthestesiology and
Intensive Care at Uppsala University Hospital.

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UPSALA JOURNAL OF MEDICAL SCIENCES 259


	Abstract
	Introduction
	Materials and methods
	Patients and SAH management
	Predictive equations
	Metabolic measurements
	Statistics

	Results
	Measured values versus predictive equations
	Urinary nitrogen excretion

	Discussion
	Acknowledgements
	Disclosure statement
	Notes on contributors
	References