DOI: 10.14814/phy2.15521

| Accepted: 3 November 2022

ORIGINAL ARTICLE

Steady-­state chemoreflex drive captures ventilatory
acclimatization during incremental ascent to high altitude:
Effect of acetazolamide
Valerie C. Cates1 | Christina D. Bruce1 | Anthony L. Marullo1,2 | Rodion Isakovich1
Gurkarn Saran1 | Jack K. Leacy1,2 | Ken D. O′Halloran2 | Thomas D. Brutsaert3 |
Mingma T. Sherpa4 | Trevor A. Day1
1

Department of Biology, Faculty of
Science and Technology, Mount Royal
University, Calgary, Alberta, Canada

2

Department of Physiology. School of
Medicine, University Cork College,
Cork, Ireland

3

Department of Exercise Science,
Syracuse University, Syracuse,
New York, USA

4

Kunde Hospital, Khunde, Nepal

Correspondence
Trevor A. Day, Department of Biology,
Faculty of Science and Technology,
Mount Royal University, 4825 Mount
Royal Gate SW, Calgary, AB, T3E 6K6,
Canada.
Email: tday@mtroyal.ca
Funding information
Alberta Government Student
Temporary Employment Program;
Alberta Innovates Health Solutions
Summer Studentships; Natural Sciences
and Engineering Research Council
(NSERC) Undergraduate Student
Research Assistantships; NSERC
Discovery Grant Program, Grant/
Award Number: PGPIN-­2016-­04915;
University College Cork

|

Abstract
Ventilatory acclimatization (VA) is important to maintain adequate oxygenation with ascent to high altitude (HA). Transient hypoxic ventilatory response
tests lack feasibility and fail to capture the integrated steady-­state responses to
chronic hypoxic exposure in HA fieldwork. We recently characterized a novel
index of steady-­state respiratory chemoreflex drive (SSCD), accounting for integrated contributions from central and peripheral respiratory chemoreceptors
during steady-­state breathing at prevailing chemostimuli. Acetazolamide is often
utilized during ascent for prevention or treatment of altitude-­related illnesses,
eliciting metabolic acidosis and stimulating respiratory chemoreceptors. To determine if SSCD reflects VA during ascent to HA, we characterized SSCD in 25
lowlanders during incremental ascent to 4240 m over 7 days. We subsequently
compared two separate subgroups: no acetazolamide (NAz; n = 14) and those
taking an oral prophylactic dose of acetazolamide (Az; 125 mg BID; n = 11). At
1130/1400 m (day zero) and 4240 m (day seven), steady-­state measurements of
resting ventilation (V̇I; L/min), pressure of end-­tidal (PET)CO2 (Torr), and peripheral oxygen saturation (SpO2; %) were measured. A stimulus index (SI; PETCO2/
SpO2) was calculated, and SSCD was calculated by indexing V̇I against SI. We
found that (a) both V̇I and SSCD increased with ascent to 4240 m (day seven; V̇I:
+39%, p < 0.0001, Hedges' g = 1.52; SSCD: +56.%, p < 0.0001, Hedges' g = 1.65),
(b) and these responses were larger in the Az versus NAz subgroup (V̇I: p = 0.02,
Hedges' g = 1.04; SSCD: p = 0.02, Hedges' g = 1.05). The SSCD metric may have
utility in assessing VA during prolonged stays at altitude, providing a feasible
alternative to transient chemoreflex tests.

Valerie C. Cates and Christina D. Bruce denotes equal contributions to first-­authorship
This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided
the original work is properly cited.
© 2022 The Authors. Physiological Reports published by Wiley Periodicals LLC on behalf of The Physiological Society and the American Physiological Society.
Physiological Reports. 2022;10:e15521.		
https://doi.org/10.14814/phy2.15521

wileyonlinelibrary.com/journal/phy2

| 1 of 17

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Received: 25 October 2022

|   

CATES et al.

KEYWORDS

acetazolamide, acid–­base, carbonic anhydrase inhibitor, high altitude, hypoxic ventilatory
response, novel methodology, renal compensation, respiratory chemoreflexes, steady-­state
chemoreflex drive, ventilatory acclimatization

1

|

I N T RO DU CT ION

Ventilatory acclimatization (VA) to high altitude (HA),
arguably one of the most important responses to HA ascent (Ainslie et al., 2013; West, 2006), is mediated through
changes in both peripheral and central chemoreceptor
sensitization and/or central integration (Moya et al., 2020;
Robbins, 2007). In response to chronic HA exposure, the
sensitivity of the peripheral chemoreflex is augmented
driving (a) increases in the magnitude of the hypoxic ventilatory response (HVR; Howard & Robbins, 1995; Sato
et al., 1992; Teppema & Dahan, 2010; White et al., 1987),
state breathing
and subsequently (b) increases steady-­
while hypoxic (Duffin & Mahamed, 2003; Eger et al., 1968;
Michel & Milledge, 1963). The central chemoreflex is also
augmented during chronic exposure to hypoxia (Fan
et al., 2010), in part due to the renally mediated elimination of bicarbonate ions (HCO3−) and associated reduced
buffering capacity in the central compartment, as the kidneys compensate for the sustained respiratory alkalosis
(Krapf et al., 1991; Mathew et al., 1983; Pitts et al., 1948;
Schoene et al., 1990; Severinghaus et al., 1963). This renal
elimination of HCO3− in the context of chronic hypobaric hypoxia increases the relative stimulation of central
chemoreceptors via [H+] for a given CO2 challenge (e.g.,
Ainslie et al., 2013; Fan et al., 2010). Thus, these respiratory and acid–­base perspectives are relevant to the integrative understanding of the chemoreflex control of
breathing and VA to HA.
There are a number of methods used to assess
HVR magnitude in a laboratory context (Teppema &
Dahan, 2010), including rebreathing (e.g., Duffin, 2011),
dynamic end-­tidal forcing (e.g., Steinback & Poulin, 2007),
and transient gas-­perturbation tests (e.g., Pfoh et al., 2016).
Unfortunately, consensus has not yet been reached regarding standard accepted methodology (e.g., Powell, 2006),
and differential methods and/or contexts complicate the
comparison between methods at sea level and/or between
sea level versus HA (e.g., Pfoh et al., 2016, 2017; Steinback
& Poulin, 2007; Teppema & Dahan, 2010). Despite the importance of assessing VA with ascent, transient laboratory
tests of the central or peripheral chemoreflexes in humans
lack portability and feasibility in HA fieldwork. In addition, HVR testing in the context of HA raises technical
and theoretical challenges, where (a) participants are already hypoxemic, raising safety concerns, (b) participants

are hypocapnic at baseline compared to sea level, affecting both central and peripheral chemoreflex activation or
sensitivity, and (c) acid–­base status may be altered, with
renal compensation (i.e., HCO3− elimination) occurring
at variable magnitudes and rates with ascent profiles (c.f.,
Bird, Leacy, et al., 2021; Zouboules et al., 2018). Most importantly, ventilatory responses to transient hypoxic gas
challenges do not reflect the steady-­state ventilatory strategy employed while at rest in sustained hypobaric hypoxic
contexts. There is a need for alternative, integrative, and
portable methods to assess chemoreflex drive in the context of VA during HA ascent.
We recently proposed and characterized a novel index
of steady-­state chemoreflex drive (SSCD) as an alternative method to assessing VA during ascent to HA (Bruce
et al., 2018; Leacy et al., 2021; Pfoh et al., 2017; see methods
for details). The SSCD metric characterizes the ventilatory
strategy employed in relation to prevailing chemostimuli
in the steady-­state. First, a “stimulus index” (SI) is calculated (PETCO2/SpO2), given ventilation is known to be linearly and directly proportional to changes in PETCO2 (e.g.,
Duffin, 2011; Nielsen & Smith, 1952) and linearly and
inversely proportional to changes in SpO2 (e.g., Rebuck
& Campbell, 1974). Second, ventilation is then indexed
against the SI to calculate SSCD. We previously introduced
the rationale and potential utility of the SSCD metric relative to more commonly utilized transient peak response
HVR tests, in particular when assessing VA during incremental ascent to HA (Bruce et al., 2018; Pfoh et al., 2017).
Preliminary data in a small cohort of trekkers demonstrated that the SSCD increased with incremental ascent
to 5160 m, capturing VA in lowlanders (Bruce et al., 2018).
We also recently found that ascent-­descent hysteresis in
SSCD (to quantify VA magnitude) was associated with
lower maximum acute mountain sickness (AMS) scores
during incremental ascent to and descent from 5160 m
(Leacy et al., 2021). However, the SSCD metric has not
been characterized and compared between those taking a
prophylactic dose of acetazolamide and those that were
acetazolamide-­free.
Oral acetazolamide administration is commonly
used to aid in VA, thus preventing or treating altitude-­
related illnesses, including AMS (e.g., Luks et al., 2019;
Swenson, 2016). AMS occurs in 10%–­
25% of unacclimatized individuals ascending to >2500 m and ~70% of
those who ascend to >4500 m (Karinen et al., 2008; Vardy

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et al., 2006). Acetazolamide, a carbonic anhydrase inhibitor, elicits metabolic acidosis via actions in the renal tubules, leaving a portion of normally filtered HCO3− to be
excreted in the urine, and concomitant retention of H+ in
blood and body fluids (Swenson, 2014). Acetazolamide-­
induced metabolic acidosis aids in VA by stimulating both
central and peripheral respiratory chemoreceptors, and
thus increasing ventilation and subsequent oxygenation
(Swenson, 2016).
Aside from oral acetazolamide administration to
treat AMS at altitude (250 mg BID; 29), lower doses are
routinely administered prophylactically to prevent AMS
(e.g., 125 mg BID), particularly during rapid ascent and/or
higher ascent profiles (Kayser et al., 2012; Luks et al., 2019;
van Patot et al., 2008). Despite this, the lowest recommended acetazolamide dose that limits side effects and
prevents AMS has been inconsistent, ranging from 750 mg/
day (Dumont et al., 2000) to the current recommended
250 mg/day (Gao et al., 2021; Kayser et al., 2012; Low
et al., 2012; Luks et al., 2019; Nieto Estrada et al., 2017).
However, more recent reports indicate that an even lower
dose of 62.5 mg BID can be as effective as the standard
125 mg BID (Lipman et al., 2020; McIntosh et al., 2019).
It has yet to be determined if SSCD captures VA in
a large group of trekkers during incremental ascent to
4240 m, and the potential superimposed effects of a prophylactic oral acetazolamide dose (125 mg BID) have not
been characterized. Therefore, we sought to characterize
VA via ventilation, the SSCD metric, and self-­reported
AMS scores, and compare an acetazolamide-­free group
(no acetazolamide; NAz) to one taking an oral prophylactic dose of acetazolamide (Az; 125 mg BID) during incremental ascent to HA (4240 m over 7 days) in the Nepal
Himalaya. We hypothesized that (a) ventilation and SSCD
would increase with incremental ascent to altitude, tracking VA, and that (b) prophylactic oral acetazolamide administration would elicit larger increases in ventilation
and SSCD and (c) the Az group would report lower AMS
symptoms than the NAz group following 7 days of incremental ascent to 4240 m.

2
2.1

|

M ET H ODS AN D MAT E R IALS

| Participant recruitment

The current study took place in the context of several research expeditions to high altitude in the Nepal Himalaya.
Participants were recruited via verbal communication,
and each provided verbal and written, informed consent to
undergo repeated measurements before and during ascent
prior to voluntary participation in the study. Participants
were all non-­smokers and had no self-­reported history

   

| 3 of 17

of neurological, cardiovascular, respiratory, or metabolic
illnesses, or taking any related medications, aside from
hormonal birth control (see section below regarding dosage of acetazolamide). Due to their participation in organized and/or guided expeditions with pre-­determined
dates, ovarian cycle in female participants could not be a
criterion for inclusion/exclusion in this study, nor was it
tracked or controlled for. Furthermore, assessing potential sex differences were not planned a priori. However,
previous reports have demonstrated that cycling ovarian
hormones do not affect central or peripheral chemoreflex
magnitude (e.g., Macnutt et al., 2012). All participants abstained from alcohol and exercise for at least 12 h prior to
measurements, which were all obtained on rest days (i.e.,
no trekking) following one night at the measurement altitude. At no time was any participant included in the NAz
group taking acetazolamide or corticosteroids for the prevention or treatment of altitude-­related illnesses.
For transparency, there is some overlap of data with
previous publications from our group. Specifically, ancillary cardiorespiratory measures of some participants
were included in a number of recent publications: (Bird,
Kalker, et al., 2021) assessing central sleep apnea with
ascent; (Bruce et al., 2018) initially characterizing SSCD
with incremental ascent; (Holmström et al., 2021) assessing splenic function with ascent; (Lafave et al., 2019) assessing cerebral blood flow with ascent; (Leacy et al., 2021)
assessing cardiorespiratory hysteresis with ascent and
descent.; (Zouboules et al., 2018) assessing arterial acid–­
base variables with ascent. However, the characterization
of ventilation and SSCD to assess VA and AMS with incremental ascent in a large cohort of trekkers to 4240 m
with (a) a calibrated pneumotachometer to measure ventilation, (b) corrected PETCO2 to known PaCO2 values
during incremental ascent (see Section 2), (c) comparison
between subgroups with and without prophylactic oral acetazolamide and (d) assessing its potential relationship of
SSCD to self-­reported AMS scores, are all novel aspects reported within this comprehensive methodological characterization. Here, we assess the SSCD metric with potential
utility in tracking VA with incremental ascent to 4240 m in
a large group of trekkers and assess the effect of a prophylactic dose of oral acetazolamide during ascent. Further,
here we also outline a number of methodological considerations for its utility and future application.

2.2
2.2.1

| Experimental protocols
| Ascent profile

Participants were recruited from three large research expeditions to HA, where separate groups of participants

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CATES et al.

|   

CATES et al.

completed an identical ascent profile from 1400 m to
4240 m over 6 days, with final measures made on a rest
day following sleeping at 4240 m on day seven. Due to
logistical constraints associated with large expeditions
and participant recruitment, baseline measures were either performed in Calgary (1130 m) or 2–­3 days after arrival in Kathmandu (1400 m). All participants then flew
together as a group from 1400 m to 2840 m (Lukla airport) for the first trekking day to 2840 m (Monju). They
arrived at 3440 m (Namche) on day two and spent a full
rest day there, free of hiking or elevation gain (day three).
They then ascended to either 3820 m (Deboche) or 3860 m
(Tengboche) on day four and stayed for a rest day (day
five). Finally, they ascended to 4240 m (Pheriche) on day
six and stayed for a rest day (day seven), where the subsequent measures for this study took place.
The atmospheric pressure (PATM) at each altitude was
not measured directly but rather calculated using a standard equation.
−mgh

PAltitude = P0 e kT ,

(1)

where P0 = 101,325 Pa (sea level pressure), m = 4.81 × 10−26 kg
(mass of one air molecule), g = 9.81 m s−2 (acceleration
due to gravity), h = altitude, k = Boltzmann's constant
(1.3806 × 10−23 m2 kg s−2 K−1), and T = 288.16 K (standard
temperature at sea level). PAltitude was then converted from
Pa to mmHg (mmHg = Pa × 0.00750062) and reported in
Tables 1 and 2 to illustrate the relative reduction in PATM and
PIO2 with ascent.

2.2.2

| Acetazolamide use

Following an assessment of VA with ascent in the complete group (n = 25), we subsequently compared two
subgroups based on known acetazolamide status. All
expedition participants independently obtained a personal supply of acetazolamide via a prescription from
their physician prior to the departure for the expeditions,
as per accepted guidelines (e.g., Luks et al., 2019). For
the expeditions where participants were not taking oral
prophylactic acetazolamide (NAz), it was available for
treatment of AMS symptoms under the guidance of the
organization team, as needed. The NAz group did not
take prophylactic acetazolamide nor corticosteroids for
treatment of AMS at any time during the incremental
ascent to 4240 m. For the expedition where participants
were taking acetazolamide (Az), participants were self-­
administering an oral prophylactic dose (125 mg BID)
during ascent. The Az group began taking acetazolamide on day one of ascent from 1400 to 2840 m (flight
to Lukla airport and first trekking day), and continued

self-­administration twice daily (morning and night) as
per instructions from the expedition organizers during trekking at altitude (e.g., Basnyat et al., 2003; Luks
et al., 2019; van Patot et al., 2008).
This observational retrospective evaluation between
NAz and Az groups was not planned a priori. Rather, the
unique opportunity to assess the potential effects of a self-­
administered oral prophylactic dose of acetazolamide on
VA arose post hoc, given that data collection occurred
across a number of HA research expeditions, where one
group was taking oral acetazolamide as a part of the safety
precautions of the expedition, and another group was
not. Given that (a) this was not a drug intervention study
(i.e., clinical trial) and the acetazolamide was obtained by
each participant individually in advance via prescription
from their own personal physicians and (b) the drug use
took place outside of Canada (Nepal), Health Canada approval was not required, as it is outside the scope of Part
C, Division 5 of the Food and Drug Regulations, and thus
a Clinical Trial Application was not required to be submitted for review (Health Canada, personal communication).

2.2.3

| Daily ancillary measurements

Resting ancillary physiological measurements were taken
every morning between 06:00 and 08:00 local time following one night at each altitude: 1130/1400 m (day zero) and
4240 m (day seven) to characterize steady-­state physiological responses to incremental ascent to altitude (Table 1).
All ancillary physiological measures were obtained at rest
in a seated position following >2-­min rest with eyes closed
and white noise played through headphones to limit distraction. Brachial arterial blood pressure was measured
via an automated blood pressure monitor (model BP786n;
Omron). Mean arterial pressure (MAP) was calculated as
a weighted mean (1/3 systolic +2/3 diastolic). Hemoglobin
concentration [Hb] was obtained via finger capillary blood
sample using sterile lancets (AccuChek, Softclix) with
standard practice and universal precautions, measured
via hemoglobinometer (Hemocue Hemoglobin System,
Hb201+ with microcuvettes). Oxygen content (CaO2) was
subsequently calculated as 1.36 × [Hb] × SpO2/100, where
1.36 is the binding capacity of oxygen to hemoglobin
(Hüfner's constant), [Hb] is hemoglobin concentration (g/
dl) and SpO2 is peripheral arterial oxygen saturation (%;
see below). Given we did not have PaO2, CaO2 was estimated without it (using only [Hb] and SpO2), given the
negligible contribution of PaO2 when [Hb] is normal or
high.
For consistency in comparison, all baseline PETCO2
values were obtained at 1400 m for SSCD calculations.
Mainstream PETCO2 (mmHg; atmospheric pressure

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| 5 of 17

T A B L E 1 Resting ancillary and cardiorespiratory variables before and after incremental ascent to high altitude, comparing low and
high altitude. Values are reported for the combined participant group (n = 25) and each subgroup, both the no acetazolamide group (NAz;
n = 14) and acetazolamide groups (Az; n = 11). PATM, atmospheric pressure (calculated; see Section 2); PIO2, pressure of inspired oxygen
([PATM-­47] × 0.21); HR, heart rate; MAP, mean arterial pressure; [Hb], hemoglobin concentration; CaO2, oxygen content; PETCO2, pressure of
end-­tidal CO2 (corrected, see Section 2); SpO2, peripheral arterial oxygen saturation; V̇I, minute ventilation; SSCD, steady-­state chemoreflex
drive (V̇I/SI); see Section 2). MAP, PETCO2, urine pH, and AMS scores from morning ancillary measures (06:00–­08:00), after one night's
sleep after arrival at each altitude (1400 and 4240 m). All other measures from LabChart data during rest day at each altitude (09:00–­17:00).
Statistical tests utilized were two-­tailed paired t-­tests comparing 1130/1400 m and 4240 m for each variable, with p-­values listed for each test.
For AMS scores, non-­parametric Wilcoxon signed-­ranks tests were utilized. Asterisk (*) indicates a significant difference from 1130/1400 m
(p < 0.05). Values are reported as mean ± standard deviation, except for AMS scores, which are reported as median (range)
Variable/location

1130/1400 m (Day 0)

4.240 m (Day 7)

p-­value

PATM (mmHg)

665/644

460

N/A

PIO2 (mmHg)

130/125

87

N/A

Group

All (n = 25)

−1

HR (min )

76.2 ± 10.1

75.5 ± 14.9

p = 0.77

MAP (mmHg)

93.1 ± 9.7

99.5 ± 8.7*

p < 0.0001

[Hb] (g/L)

139.2 ± 12.6

149.5 ± 12.5*

p = 0.004

CaO2 (ml/dl)

18.2 ± 1.7

17.7 ± 1.5

p = 0.12

PETCO2 (mmHg)

32.0 ± 4.2

26.0 ± 2.6*

p < 0.0001

SpO2 (%)

96.5 ± 1.3

87.0 ± 2.5*

p < 0.0001

SI (a.u.)

0.33 ± 0.04

0.30 ± 0.03*

0.0006

V̇I (L/min)

11.1 ± 2.4

15.5 ± 3.3*

p < 0.0001

SSCD (a.u.)

33.9 ± 7.7

52.9 ± 14.5*

p < 0.0001

AMS Score

0 (0–­1)

0 (0–­2)*

p < 0.05

Group

No Acetazolamide Group (n = 14)
75.6 ± 11.6

73.4 ± 15.0

p = 0.4

97.4 ± 7.8

103.0 ± 7.2*

p = 0.003

HR (min−1)
MAP (mmHg)
[Hb] (g/L)

140.0 ± 14.6

148.8 ± 14.6

p = 0.1

CaO2 (ml/dl)

18.3 ± 2.0

17.4 ± 1.8

p = 0.15

PETCO2 (mmHg)

33.0 ± 5.1

27.0 ± 2.9*

p = 0.0007

SpO2 (%)

96.2 ± 1.1

86.4 ± 2.2

p < 0.0001

SI (a.u.)

0.34 ± 0.05

0.31 ± 0.03

p = 0.05

V̇I (L/min)

11.0 ± 3.0

14.3 ± 3.2

p < 0.0001

SSCD (a.u.)

32.3 ± 9.3

46.7 ± 13.0

p < 0.0001

Urine pH

5.99 ± 0.5

5.82 ± 0.2

p = 0.2

AMS Score

0 (0–­1)

0 (0–­2)

n not sufficient

Group

Acetazolamide Group (n = 11)

HR (min−1)

77.0 ± 8.3

78.2 ± 15.0

p = 0.8

MAP (mmHg)

87.6 ± 9.3

95.0 ± 8.7*

p = 0.01

[Hb] (g/L)

138.3 ± 10.8

150.3 ± 10.6*

p = 0.02

CaO2 (ml/dl)

18.2 ± 1.4

17.9 ± 1.2

p = 0.56

PETCO2 (mmHg)

30.7 ± 2.2

24.7 ± 1.5*

p < 0.0001

SpO2 (%)

96.9 ± 1.1

87.7 ± 2.8*

p < 0.0001

SI (a.u.)

0.32 ± 0.02

0.28 ± 0.02*

p = 0.0005

V̇I (L/min)

11.3 ± 1.4

16.9 ± 2.9*

p = 0.0001

SSCD (a.u.)

35.8 ± 4.8

60.7 ± 12.9*

p = 0.0001

Urine pH

6.06 ± 0.7

6.68 ± 0.5*

p = 0.04

AMS Score

0 (0–­1)

1 (0–­1)

n not sufficient

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CATES et al.

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CATES et al.

T A B L E 2 Resting ancillary and cardiorespiratory variables following incremental ascent to altitude at 4240 m. Values are reported
for the combined participant group (n = 34) and each subgroup, both the no acetazolamide (NAz; n = 22) and acetazolamide groups (Az;
n = 12). PATM, atmospheric pressure (calculated; see Section 2); PIO2, pressure of inspired oxygen ([PATM-­47] × 0.21); HR, heart rate; MAP,
mean arterial pressure; [Hb], hemoglobin concentration; CaO2, oxygen content; PETCO2, pressure of end-­tidal CO2 (corrected, see Section 2);
SpO2, peripheral arterial oxygen saturation; V̇I, minute ventilation; SSCD, steady-­state chemoreflex drive (V̇I/SI); see Section 2). MAP,
PETCO2, urine pH, and AMS scores from morning ancillary measures (06:00–­08:00), after one night‘s sleep after arrival at 4240 m. All other
measures from LabChart data during rest day at each altitude (09:00–­17:00). Statistical tests utilized were two-­tailed paired t-­tests comparing
NAz and Az groups at 4240 m for each variable, with p-­values listed for each test. For AMS scores, a non-­parametric Mann–­Whitney U test
was utilized. Asterisk (*) indicates a significant difference from NAz (p < 0.05). Values are reported as mean ± standard deviation, except for
AMS scores, which are reported as median (range)
Variable/location

4.240 m (Day 7)

p-­value (NAz vs. Az)

PATM (mmHg)

460

N/A

PIO2 (mmHg)

87

N/A

Group

All (n = 34)

NAz (n = 22)

Az (n = 12)

HR (min )

75.9 ± 14.6

75.3 ± 14.7

76.8 ± 15.1

p = 0.78

MAP (mmHg)

98.0 ± 8.9

100.2 ± 8.1

93.8 ± 9.2*

p = 0.04

[Hb] (g/L)

148.4 ± 11.8

147.6 ± 12.7

149.8 ± 10.2

p = 0.62

CaO2 (ml/dl)

17.4 ± 1.5

17.2 ± 1.7

17.8 ± 1.2

p = 0.31

PETCO2 (mmHg)

26.1 ± 2.5

26.9 v2.6

24.7 ± 1.4*

p = 0.009

−1

SpO2 (%)

86.4 ± 2.7

85.9 ± 2.7

87.4 ± 2.8

p = 0.12

SI (a.u.)

0.30 ± 0.03

0.31 ± 0.03

0.28 ± 0.02*

p = 0.006

V̇I (L/min)

14.7 ± 3.3

13.6 ± 2.9

16.7 ± 2.9*

p = 0.005

SSCD (a.u.)

49.5 ± 14.1

43.9 ± 11.7

59.6 ± 12.8*

p = 0.001

Urine pH

6.27 ± 0.57

6.03 ± 0.48

6.70 ± 0.45*

p = 0.0004

AMS Score

0 (0–­2)

0 (0–­2)

1 (0–­2)

p = 0.43

adjusted) was measured using a portable capnograph
(EMMA, Masimo) and a personal mouthpiece and nose
clip, obtained from a running average after steady-­state
was achieved. The portable capnograph utilized for
PETCO2 measures is rated for accuracy to an atmospheric
pressure equivalent to approximately PATM of ~525 mmHg
(~3200 m; https://bit.ly/3zqWQeJ). In a previous study,
we noted that (a) PETCO2 using this model of capnograph
underestimated PaCO2 with ascent and (b) the underestimation of PaCO2 by PETCO2 was exaggerated with ascent to 5160 m following an identical ascent profile (i.e.,
values diverged with ascent; see Zouboules et al., 2018);
Correction model is published in (Isakovich et al., n.d.).
Specifically, the following values were added to PETCO2
values obtained from the portable capnograph, within-­
individual: 1400 m, +0.405 mmHg; 4240 m, +4.665 mmHg
(see Isakovich et al., n.d.).
Morning urine pH measurements were obtained on all
participants and are utilized here post hoc to confirm acetazolamide status on measurement days (i.e., day zero at
1130/1400 m, and day seven at 4240 m). Participants provided a sample of their first-­morning urination into a new,
clean 110 ml sample container with a screw cap that could
be secured immediately following collection and analyzed within 5–­30 min. Urine pH was measured aerobically using a pH meter and biological probe (B10P; VWR;

sympHony), calibrated daily using standard pH buffers
(3 and 7), and automatically temperature corrected.
reported AMS scores were obtained
Lastly, self-­
using the updated Lake Louise Questionnaire (Roach
et al., 2018). Unlike ventilation and SpO2 data (described
below), individual PETCO2, HR, MAP, [Hb], and AMS
scores were documented by hand.

2.2.4

| Measurement of resting ventilation

Minute ventilation was measured with participants in a
seated position in a dark, quiet laboratory (Calgary, 1130
m) or lodge bedroom (Kathmandu at 1400 m or Pheriche
at 4240 m) between the hours of 10:00 and 17:00 on rest
days following one night sleep at the respective altitude.
Participants kept their eyes closed throughout the testing protocol and wore ear plugs to minimize distraction.
Participants were instrumented with a personal mouthpiece, nose clip and bacteriological filter, proximal to
the flow head. Following instrumentation, we collected
10-­
min of baseline data for each participant, using a
16-­
channel PowerLab system (Powerlab/16SP ML880;
AD Instruments; ADI) and analyzed offline using commercially available software (LabChart Pro software 8.0).
Respiratory flow was measured via pneumotachometer

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6 of 17

(800 L flow head and spirometer amplifier; Hans Rudolph
and ADI ML141; calibrated with a 3 L syringe daily). The
dead space associated with the mouthpiece, bacteriological filter, and flow head was the same between experimental conditions between expeditions. Instantaneous
minute ventilation (V̇I, L/min) was calculated as the product of breath-­by-­breath inspired volume (VTI; calculated
from the integral of the flow signal) and respiratory rate
(RR, min−1; calculated by 60/period of the flow signal).
Continuous measures of SpO2 were obtained by pulse oximeter (ADI ML320) placed on the right middle finger.
ADI LabChart data were digitally archived for later offline analysis, and measures were derived from a representative 2-­minute steady-­state average (sampled each second;
~120 samples) near the end of each 10-­min baseline period,
analyzed by the same team member for consistency (T.L.M).
Given the known effects of mouthpiece and nose clip use
on eliciting relative hyperventilation in some participants
at rest (e.g., Askanazi et al., 1980; Sackner et al., 1980;
Scott, 1993; Weissman et al., 1984), we only included participants in the final analysis that increased minute ventilation between 1130/1400 m (day 0) and 4240 m (day 7) for
delta responses with ascent, representing the expected ventilatory acclimatization with ascent over 7 days, given that
all participants were hypocapnic with ascent, as expected.
For transparency, although we initially recruited 36 participants at low altitude, two declined to have measures obtained at 4240 m, and nine participants were excluded in the
before-­after ascent comparison due to relative hyperventilation during baseline at 1130/1400 m (see Section 4), for a
final participant pool of n = 25, with subgroups of n = 14
in the NAz subgroup and n = 11 in the Az subgroup. These
participants were pooled to assess the large group change in
SSCD (see below), as well as compared between them (i.e.,
NAz vs. Az) with ascent. However, we included all available
participants for an absolute comparison at 4240 m between
NAz (n = 22) and Az (n = 12) groups to confirm our findings.
Note that baseline V̇I and SpO2 for the Az group
(n = 11) and half of the NAz group (n = 7), values were
obtained at 1130 m (PIO2 ~ 130 mmHg), with these data
from the remaining participants in the NAz group (n = 7)
obtained at 1400 m (PIO2 ~ 125 mmHg). There were no
statistical differences in V̇I (p = 0.24) and SpO2 (p = 0.42)
between participants at the two baseline locations (1130 m
vs. 1400 m), and thus data were pooled to represent pre-­
ascent baseline in the larger group.

2.2.5 | Steady-­state chemoreflex drive
during ascent
Minute ventilation, PETCO2, and SpO2 measurements were
performed on rest days in Calgary (1130 m) or Kathmandu

   

| 7 of 17

(1400 m; day zero), and again in Pheriche (4240 m) to assess
the magnitude of SSCD following incremental ascent. In
order to calculate the SSCD, a stimulus index (SI; PETCO2/
SpO2) was first calculated, whereby ventilation is known to
be linearly and directly proportional to changes in PETCO2
(e.g., Duffin, 2011; Nielsen & Smith, 1952) and linearly and
inversely proportional to changes in SpO2 (e.g., Rebuck &
Campbell, 1974). Ventilation was then indexed to the SI to
calculate SSCD (see Bruce et al., 2018; Leacy et al., 2021;
Pfoh et al., 2017) to assess the integrative contributions of
chemostimuli to ventilation in the steady-­state.
Stimulus Index (SI) = PET CO2 ∕SpO2 (a. u. )
SSCD = V̇ I ∕SI (a. u. ).

2.2.6

(2)

| Statistical analysis

Table 1 presents cardiorespiratory and ancillary data during ascent as mean ± standard deviation (SD) in the combined group of participants (n = 25), and for separate
subgroups (NAz [n = 14] vs. Az [n = 11]). Self-­reported AMS
scores within groups with ascent were assessed using non-­
parametric Wilcoxon signed-­rank tests (i.e., paired; Table 1).
To compare variables between 1130/1400 m (day zero)
and 4240 m (day seven) in the combined group (n = 25),
as well as within separate NAz (n = 14) and Az (n = 11)
groups with ascent, we performed two-­tailed, paired t-­
tests (Table 1; Figures 1a,b and 2a,b).
In addition, to compare the within-­individual change
(delta) in V̇I and SSCD between NAz and Az groups,
we performed two-­tailed, paired t-­tests on the absolute
within-­individual change (Figure 3a,b).
For direct comparison between NAz (n = 14) and Az
(n = 11) groups at 4240 m, we compared the absolute difference in V̇I and SSCD between NAz and Az groups using
two-­tailed, unpaired t-­tests (Figure 3c,d). In addition, as a
further comparison of absolute values at 4240 m between
groups (i.e., not only those compared before and after ascent in Figures 1–­3), a larger group of available participants (n = 34) was compared between NAz (n = 22) and
Az (n = 12) at 4240 m using two-­tailed, unpaired t-­tests
(Figure 3e,f).
Lastly, the relationship between self-­
reported AMS
scores with ascent to 4240 m was assessed using a
Spearman Rho (rs) correlation. In addition, potential differences in AMS scores between NAz and Az subgroups
at 4240 m were assessed using non-­
parametric Mann–­
Whitney U tests (i.e., unpaired).
The effect size of ventilatory and SSCD responses with
ascent was assessed via Hedges' g tests (Figures 1–­3).
Statistical tests were performed using GraphPad Prism
(v9.1.2). In all cases, statistical significance was assumed at
p < 0.05.

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CATES et al.

|   

CATES et al.

F I G U R E 1 Ventilatory acclimatization with ascent to 4240 m over 7 days in the combined participant group (n = 25). (a) Minute
ventilation (V̇I) prior to (1130/1400 m and following ascent to 4240 m. (b) Steady-­state chemoreflex drive (SSCD) prior to and following
ascent to 4240 m. Individual participants (gray circles) are connected for within-­individual comparisons. Gray dash and error bars represent
mean (values reported on graph) and standard deviation. Individual p-­values are reported on each graph, where p < 0.05 denotes statistical
difference from baseline (1130/1400 m). ES, effect size calculated via Hedges' g.

F I G U R E 2 Ventilatory acclimatization before and after ascent to 4240 m over 7 days without and with prophylactic oral acetazolamide.
(a) Minute ventilation (V̇I) prior to (1130/1400 m) and following ascent to 4240 m in the no acetazolamide (NAz) group (n = 14). (b) Steady-­
state chemoreflex drive (SSCD) prior to and following ascent to 4240 m in the NAz group (n = 14). (c) Minute ventilation (V̇I) prior to and
following ascent to 4240 m in the acetazolamide (Az) group (n = 11). (d) SSCD prior to and following ascent to 4240 m in the Az group
(n = 11). White circles, individual participants in the NAz group (panels a and b). Black circles, individual participants in the Az group
(panels c and d). Individual participants are connected for within-­individual comparisons.

3
3.1

|

R E S U LTS

| Participant demographics

All participants included in the final analysis followed an
identical ascent profile (see Section 2), specifically ascending from 1400 to 4240 m over 6 days, with measures made
in day seven at 4240 m.
To characterize responses during ascent, only participants that demonstrated an increase in ventilation with
identical ascent profiles from 1400 to 4240 m were included

in the analysis (n = 25; 15 females; age 24.9 ± 6.9 years,
BMI 23.8 ± 3.1 kg/m2). A total of 14 (7 females; age
24.1 ± 6.6 years; BMI 23.8 ± 2.5 kg/m2) and 11 participants
(8 females; age 25.9 ± 7.5 years; BMI of 23.9 ± 3.8 kg/m2)
were included in the NAz and Az groups, respectively.
To confirm the effect of oral Az between subgroups
only at 4240 m (i.e., not comparing deltas from baseline
at low altitude), a total of 34 participants were included
in the analysis (23 females; age 24.1 ± 6.1 years, BMI
23.7 ± 3.1 kg/m2). Specifically, a total of 22 participants
(14 females; age 23.1 ± 5.4 years; BMI 23.6 ± 2.8 kg/m2)

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8 of 17

   

| 9 of 17

F I G U R E 3 Comparison of participants with and without oral acetazolamide in metrics of ventilatory acclimatization following
ascent to 4240 m over 7 days. (a) Comparison of delta V̇I (4240–­1400 m) between no acetazolamide (NAz; n = 14) and acetazolamide (Az;
n = 11) subgroups with ascent. (b) Comparison of delta SSCD between NAz and Az subgroups with ascent. (c) Comparison of absolute
minute ventilation (V̇I) following ascent to 4240 m in the NAz; versus Az subgroups. (d) Comparison of absolute steady-­state chemoreflex
drive (SSCD) following ascent to 4240 m in the versus Az subgroups. These participants in a–­c are from those that were compared with
1130/1400 m (i.e., before and after ascent; n = 25; see Figures 1 and 2). (e) Comparison of absolute minute ventilation (V̇I) following
ascent to 4240 m in the no acetazolamide (NAz; n = 22) versus acetazolamide (Az; n = 12) groups. (d) Comparison of absolute steady-­state
chemoreflex drive (SSCD) following ascent to 4240 m in the no acetazolamide (NAz; n = 22) versus acetazolamide (Az; n = 12) groups. In
(e and f), these values are from every available participant measurement made at 4240 m (n = 34). White circles, individual participants in
the NAz group. Black circles, individual participants in the Az group. Dash and error bars represent mean and standard deviation (values
reported on graph). Individual p-­values and effect sizes (ES) are reported on each graph, where p < 0.05 denotes a statistical difference
between NAz and Az groups. ES, effect size calculated via Hedges' g.

and 12 participants (9 females; age 26.0 ± 7.1 years; BMI
of 23.8 ± 3.7 kg/m2) were included in the NAz and Az
groups, respectively.

3.2

| Ancillary variables

Cardiorespiratory and ancillary variables with ascent
from 1130/1400 m to 4240 m over 7 days in the total group
(n = 25), and subsequently for each of the NAz (n = 14)

and Az (n = 11) subgroups are reported in Table 1. Note
that baseline data prior to ascent in both the NAz and Az
groups were acetazolamide-­
free. As expected, PETCO2
and SpO2 decreased with ascent, whereas V̇I and SSCD
increased with ascent in both groups. Aerobic urine pH
was unchanged with ascent in the NAz group, but was significantly more alkaline in the Az group, confirming that
the participants were self-­administering acetazolamide,
which elicited an expected renal effect. Lastly, although
self-­reported AMS scores increased with ascent in both

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CATES et al.

|   

CATES et al.

NAz and Az groups, there was no statistical difference between NAz and Az groups in at 4240 m on day seven following 6 days of ascent.

differences between self-­reported AMS scores at 4240 m
between NAz (n = 22) and Az (n = 12) groups at 4240 m
(p = 0.43).

3.3 | Ventilation and steady-­state
chemoreflex drive (SSCD) during ascent
to altitude

4

In the combined participant group with ascent, V̇I increased significantly with ascent (~39%, p < 0.0001,
Hedges' g = 1.52; Figure 1a). Similarly, SSCD increased
significantly with ascent (~56%, p < 0.0001, Hedges'
g = 1.65; Figure 1b).
When assessing the NAz and Az groups separately,
V̇I increased significantly with ascent in the NAz group
(~31%, p < 0.0001, Hedges' g = 1.08; Figure 2a) and Az
group (~50%, p < 0.0001, Hedges' g = 2.47; Figure 2c).
Similarly, SSCD increased significantly with ascent in the
NAz group (~45%, p < 0.0001, Hedges' g = 1.28; Figure 2b)
and the Az group (~70%, p < 0.0001, Hedges' g = 2.57, respectively; Figure 2d).
When comparing delta V̇I (4240–­1400 m) between NAz
and Az subgroups with ascent, the Az group increased
more than the NAz group (p = 0.02, Hedges' g = 1.04;
Figure 3a). Similarly, when comparing delta SSCD between NAz and Az subgroups with ascent, the Az group
increased more than the NAz group (p = 0.02, Hedges'
g = 1.05; Figure 3b).
When comparing absolute values at 4240 m in participants included in Figure 2 (n = 25) between NAz (n = 14)
and Az (n = 11) subgroups, V̇I was larger in the Az group
versus NAz group (p = 0.04, Hedges' g = 0.86; Figure 3c).
Similarly, SSCD was larger in the Az group versus NAz
group (p = 0.01, Hedges' g = 1.08; Figure 3d).
Lastly, when comparing absolute values at 4240 m
in all recruited participants (n = 34; i.e., not only those
reported in Figures 1–­3) between NAz (n = 22) and Az
(n = 12) subgroups, V̇I was larger in the Az group versus
NAz group (p = 0.005, Hedges' g = 1.0). Similarly, SSCD
was larger in the Az group versus NAz group (p = 0.001,
Hedges' g = 1.3). This additional comparison in a larger
group of available participants confirms the responses
noted in Figure 3a–­d.

3.4

| Relationship with AMS scores

Self-­
reported AMS scores were significantly higher
at 4240 m (p < 0.05) compared to 1400 m (n = 25).
However, there was no relationship between SSCD and
self-­reported AMS scores at 4240 m in the large group
(n = 34; rs = 0.11, p = 0.52). In addition, there were no

|

DISC USSION

We aimed to characterize VA through a novel index of
SSCD during incremental ascent to HA in a large cohort
of lowlanders ascending to 4240 m over 7 days, and subsequently assess the superimposed effects of oral acetazolamide by comparing two separate subgroups, one not
taking acetazolamide (NAz) and one taking an oral prophylactic dose of acetazolamide (Az; 125 mg BID) as a part
of the expedition organization. The principal findings of
our methodological study include: (a) ascent to HA over
7 days elicited an increase in V̇I and SSCD following ascent to 4240 m, suggesting that the SSCD metric captures
VA with ascent, and (b) the Az subgroup had significantly
higher V̇I and SSCD than the NAz, both in delta responses from low altitude and absolute values at 4240 m.
However, there was no relationship between SSCD and
self-­reported AMS scores following ascent to 4240 m, nor
were there differences between NAz and Az subgroups
in AMS symptom severity, likely due to the low reported
scores with incremental ascent. These results suggest that
although VA was apparent following a 7-­day time-­course
with incremental ascent, an oral 125 mg BID prophylactic
oral dose of acetazolamide can play an important role in
augmenting VA during incremental ascent to 4240 m.

4.1 | Testing respiratory chemoreflexes
at altitude
The chemoreflex control of breathing is mediated through
two separate but converging feedback loops (Duffin &
Mahamed, 2003). The central respiratory chemoreceptors
respond to an accumulation or reduction of metabolically
derived CO2 and/or [H+] within chemosensitive brainstem neurons and glia, eliciting a central chemoreflex
(Duffin, 2010; Guyenet et al., 2010; Nattie & Li, 2012; Pfoh
et al., 2016). The peripheral respiratory chemoreceptors
are stimulated by low PO2 (hypoxemia), eliciting a corresponding increase in ventilation (i.e., HVR; Duffin, 2011;
Teppema & Dahan, 2010), which contributes to the maintenance of blood-­gas homeostasis, improving oxygenation
in the context of acute or chronic hypoxia. Interestingly,
the acute HVR is polyphasic, where a reduction in ventilation (hypoxic ventilatory decline; HVD) shortly follows the transient peak response in ventilation (Powell
et al., 1998; Sato et al., 1994; Steinback & Poulin, 2007),
and hyperventilation-­
induced hypocapnia persists (i.e.,

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10 of 17

poikilocapnic hypoxia), further blunting the HVR (e.g.,
Steinback & Poulin, 2007), and reducing central chemoreceptor stimulation. If the hypoxic challenge is sustained
(i.e., HA), the HVR is increased in magnitude through carotid body plasticity (e.g., Robbins, 2007; Sato et al., 1992),
and the sustained hypocapnia ultimately leads to renally
mediated metabolic compensatory mechanisms (Ainslie
et al., 2013; Krapf et al., 1991; Zouboules et al., 2018), with
the metabolic acidosis likely stimulating both central and
peripheral chemoreceptors at rest. Thus, as both central
and peripheral chemoreflex magnitude are increased
with sustained exposure to hypoxia, assessing respiratory chemoreflexes and VA is of interest in HA fieldwork
settings (Bruce et al., 2018; Dempsey et al., 2014; Leacy
et al., 2021; Sato et al., 1992; Smith et al., 2017). Usually,
the peripheral chemoreflex is the target of interest via testing the transient HVR test (e.g., Teppema & Dahan, 2010),
despite the simultaneous alterations in and contributions
from the central chemoreflex to ventilation with sustained
exposure to HA.

4.2 | Laboratory HVR test utility
and caveats
Many methodological perspectives exist on how best to assess the HVR (e.g., Duffin, 2011; Pfoh et al., 2016, 2017;
Powell et al., 1998; Teppema & Dahan, 2010) including
rebreathing, steady-­state and transient hypoxic tests to
elicit a peripheral chemoreflex. Rebreathing or steady-­
state hypoxic tests involve exposing a participant to various fractions of inspired oxygen using chambers, small
rebreathing bags or large Douglas bags pre-­filled with
mixed gasses, or dynamic end-­tidal forcing systems, over
several minutes (Teppema & Dahan, 2010). Alternatively,
transient hypoxic tests expose participants to short bouts
of hypoxia (i.e., one or more breaths) via administration of 100% N2 (e.g., Milloy et al., 2022; Pfoh et al., 2016;
Teppema & Dahan, 2010). In both cases, the HVR is often
quantified by the initial peak in ventilation following the
acute hypoxic stimulus. Although the HVR can readily be
tested in laboratory contexts, these transient HVR tests
lack feasibility in HA fieldwork contexts for a number
of reasons including: (a) limited equipment portability,
(b) the risk associated with acute hypoxia in participants
who are already chronically hypoxic, (c) the effects of a
hypoxic ventilatory decline and hypocapnia that occur
with both acute (i.e., steady-­state tests) and chronic (i.e.,
HA) hypoxic exposure, and (d) the inability to isolate
peripheral and/or central chemoreflexes during the protocol due to a lack of stimulus specificity and/or interactions between chemoreceptor compartments (e.g., Wilson
& Teppema, 2016). Lastly, HVR tested via differential

   

| 11 of 17

methods have been shown to be poorly or not correlated
in magnitude within individuals (Pfoh et al., 2016, 2017).
For example, we recently tested the effects of a number
of transient and steady-­state HVR tests in unacclimatized
participants in a laboratory setting, and found that the
within-­individual magnitude was not correlated between
tests, nor was the magnitude related to oxygenation while
breathing steady-­state hypoxia (FIO2 0.13–­0.14), suggesting that specific tests of the HVR are not capturing the
ventilatory strategy utilized to protect blood gases in
steady-­state hypoxia (Pfoh et al., 2016, 2017). These matters of feasibility, consistency, and utility have driven the
development of a portable method and associated metric
that can be applied consistently in laboratory and fieldwork contexts, to capture the integrated ventilatory response to prevailing chemostimuli in the steady-­state.

4.3 | Steady-­state chemoreflex
drive (SSCD) with ascent: Effect of
acetazolamide
In an attempt to address the many caveats associated with
HVR tests, particularly with ascent to HA, we previously
developed and characterized a novel index of steady-­state
chemoreflex drive, which assesses the relationship of
steady-­state ventilation at prevailing chemostimuli (i.e.,
CO2 and O2), acting on both central and peripheral chemoreceptors. We found that the SSCD did not change from
breathing ambient air to breathing 20-­min of steady-­state
hypoxia (FIO2 0.13–­0.14; Pfoh et al., 2017), likely due to
the antagonistic effects of hypoxia and concomitant hypocapnia (e.g., poikilocapnic hypoxia; e.g., Steinback &
Poulin, 2007). However, we previously showed that (a)
SSCD increased in a small group of lowlanders following
10 days of incremental ascent to 5160 m (Bruce et al., 2018),
(b) increases with rapid ascent and residence at 3800 m
(Bird, Leacy, et al., 2021) and (c) SSCD hysteresis with incremental ascent to and descent from 5160 m quantifies
VA, the magnitude of which has inverse effects on AMS severity (Leacy et al., 2021). Here, we advance on these characterizations by assessing the effects of incremental ascent
on ventilation and SSCD in a large group of participants
over 7 days, and subsequently comparing separate groups
with and without an oral prophylactic dose of acetazolamide. We propose that the SSCD method overcomes many
of the caveats associated with peak response HVR tests and
captures the integrated central and peripheral chemoreflex
drive in the steady-­state, with utility in assessing VA during fieldwork at HA. In the present study, we established
that SSCD is augmented with 7 days of incremental ascent
to 4240 m (i.e., it captures VA), which is further augmented
when superimposed with oral acetazolamide.

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CATES et al.

|   

4.4 | Acute mountain sickness with
ascent: Effect of acetazolamide
Many experimental studies and reviews have assessed
the efficacy of a prophylactic oral dose of acetazolamide
in preventing and/or reducing AMS symptoms (Basnyat
et al., 2003; Gao et al., 2021; Kayser et al., 2012; Lipman
et al., 2020; Low et al., 2012; McIntosh et al., 2019; Nieto
Estrada et al., 2017; van Patot et al., 2008) with mixed
results. There are several limitations with drawing conclusions from these studies, in part due to the subjective
nature of AMS reporting, the site of recruitment (e.g., low
vs. high altitude), and different ascent profiles (e.g., rapid
vs. incremental ascent). The prophylactic oral Az dose did
not reduce self-­reported AMS symptoms following 7 days
of incremental ascent, likely due to the incremental nature of our ascent model, and the relatively low reported
scores. This is in contrast to a previous study (Burtscher
et al., 2014), where a prophylactic dose of acetazolamide
prior to ascent improved AMS scores immediately following rapid ascent to 3480 m compared to placebo, suggesting that ascent profile (i.e., rapid vs. incremental),
duration of stay and absolute altitude may affect the potential utility of prophylactic acetazolamide. Additionally,
the recommended lowest prophylactic dose is varied (e.g.,
Luks et al., 2019 vs. Dumont et al., 2000), with the potential to be reduced further (e.g., McIntosh et al., 2019).
dependent side effects, inAcetazolamide elicits dose-­
cluding polyuria, paraesthesia, fatigue, and dysgeusia
(Schmickl et al., 2020), and thus there is a desire to find
the lowest prophylactic dose that minimizes both drug
side effects and reported AMS symptoms. Although it has
been well-­established that a prophylactic dose is superior
to placebo in limiting AMS symptoms (Gao et al., 2021;
Kayser et al., 2012; Low et al., 2012), the findings in the
present study suggest no difference in AMS scores between NAz and Az groups using identical incremental ascent profiles, which was contrary to our initial hypothesis.
The similarity in AMS scores between our NAz and Az
groups with ascent may be attributed in part to the fact
that (a) the two groups were different groups across different expeditions (i.e., not randomized or within-­individual
comparisons) and/or (b) both groups had a low risk for
developing AMS given the slow, incremental ascent profile we utilized (e.g., Imray, 2012; Kayser et al., 2012; Luks
et al., 2019).
Participants in the Az group were instructed to self-­
administer a prophylactic dose of acetazolamide starting
on day one of ascent (125 mg BID; 250 mg/day) as a part
of the safety precautions of the expedition organization.
We subsequently confirmed that these participants were
taking acetazolamide by assessing urine pH measures, in
comparison with the NAz group. The urine pH in the NAz

CATES et al.

group was unaffected with ascent, despite incremental hypocapnia, likely due to the aerobic nature of these urine
measurements compared to other studies that used anaerobic samples (e.g., Galdston, 1955; Ge et al., 2006; Gledhill
et al., 1975). However, urine pH became more alkaline in
the Az group, confirming increased HCO3− excretion and/
or H+ retention (i.e., metabolic acidosis) in response to oral
acetazolamide (e.g., Galdston, 1955; Leaf & Goldfarb, 2007).
We conclude that both V̇I and SSCD responses are augmented with incremental ascent to 4240 m, suggesting beneficial effects of low-­dose oral acetazolamide, even during
low-­risk incremental ascent models, at least to ~4000 m.
We anticipate that larger doses (e.g., AMS treatment doses;
500 mg/day or larger; e.g., Basnyat & Murdoch, 2003; Luks
et al., 2019) would further stimulate V̇I and SSCD with ascent, but this remains to be systematically tested.

4.5

| Methodological considerations

Our study is in agreement with previous work from our
group assessing SSCD with ascent (Berthelsen et al., 2022;
Bird, Kalker, et al., 2021; Bird, Leacy, et al., 2021; Bruce
et al., 2018; Leacy et al., 2021). In the present study, we
clearly demonstrate that SSCD captures VA with incremental ascent to 4240 m over 7 days in a large group of
lowlanders. In addition, we found that the use of prophylactic oral acetazolamide augmented VA, quantified
via the SSCD index. This is the most comprehensive assessment of the SSCD metric in participants ascending to
4240 m, as a method to characterize VA, with a prophylactic oral dose of Az augmenting this response.
Although the SSCD metric holds promise as a potential tool to integrate into field studies assessing respiratory
control with ascent to altitude, our methodological study
has a number of limitations worthy of consideration. First,
although we initially recruited 36 participants for this
methodological study, a reduced number were included in
the final analysis. Specifically, two opted out of measures
at 4240 m due to symptoms of altitude-­
related illness.
Additionally, nine were excluded post hoc due to relative
hyperventilation at low altitude, whereby their ventilation
was higher at 1130/1400 m (day zero) compared to 4240 m,
which is physiologically incongruent with exposure to
sustained hypobaric hypoxia and the hyperventilation-­
induced hypocapnia that was apparent in all participants
with ascent. Although we utilized a calibrated pneumotachometer and analyzed a representative mean bin (2-­min),
this hyperventilation effect may have been due in part to
the known stimulatory effects of a mouthpiece and nose
clip on eliciting relative hyperventilation in some participants (e.g., Askanazi et al., 1980; Maxwell et al., 1985;
Sackner et al., 1980; Scott, 1993; Weissman et al., 1984),

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12 of 17

combined with participant inexperience with respiratory
instrumentation combined. Second, as we outline in the
methods, the portable capnograph we utilized for PETCO2
measures has a validated atmospheric pressure range up
to ~3200 m. Thus, measures of PETCO2 above this altitude
may depart incrementally from accuracy with further ascent (see Isakovich et al., n.d.). Indeed, we showed that
using this model of capnograph with incremental ascent,
the PETCO2-­PaCO2 difference is exaggerated with ascent
to 5160 m (Isakovich et al., n.d.; Zouboules et al., 2018).
With the assumption that the PETCO2-­PaCO2 difference (~1–­2 mm Hg; Robbins et al., 1990) is unchanged
while breathing ambient air at rest with ascent (e.g., Ito
et al., 2008), we corrected for the exaggerated underestimation of our PETCO2 values with ascent using a linear
regression model from a large sample of within-­individual
PaCO2 and PETCO2 values obtained during an identical
ascent profile (Zouboules et al., 2018); see Methods and
(Isakovich et al., n.d.). These issues with measures of ventilation and PETCO2 (i.e., capnography) underscore the
importance of utilizing measurement devices that can
be both portable and accurate in HA fieldwork contexts
when aiming to assess chemoreflex function and VA.
An additional consideration is that our SSCD index
only takes into account the prevailing CO2, but rapid ascent to HA also imposes an acid–­base dysregulation (e.g.,
respiratory alkalosis), potentially affecting chemoreflex
drive independent of CO2 (e.g., Fan et al., 2010; Forster
et al., 1975; Powell, 2007). However, a previous study from
our group showed that arterial pH was fully compensated
following one night's sleep at 4240 m following incremental ascent (Zouboules et al., 2018), suggesting that renal
compensation was likely complete in our NAz group, leaving the only relevant acid–­base variable the metabolic acidosis imposed by the oral acetazolamide administration
in the Az subgroup. However, caution should be employed
under conditions of more rapid and/or higher ascent profiles, given that above a threshold altitude, it appears that
participants are unable to fully compensate from an acid–­
base perspective (c.f., Forster et al., 1975; Steele et al., 2022
at 4300 m vs. Bird, Leacy, et al., 2021 at 3800 m), and thus
all tests of respiratory chemoreflex function may be subject
to this caveat. Regardless, in conjunction with the slower
ascent profile to 4240 m over 7 days, it is unlikely that participants in either group experienced acid–­base dysregulation from an altitude-­mediated hypocapnia/respiratory
alkalosis perspective. Accordingly, any acid–­base-­related
respiratory stimulation likely resulted from the prophylactic dose of acetazolamide in the Az subgroup, explaining
the increases in ventilation and SSCD at 4240 m in the Az
subgroup compared to the NAz subgroup.
Lastly, in developing the SSCD index, our aim was to assess chemoreflex drive in the steady-­state, without utilizing

   

| 13 of 17

complex and confounded transient gas tests that lack feasibility in high-­altitude fieldwork contexts. However, one
potential critique of the SSCD metric is that it indexes ventilation against a chemostimuli term, where the stimulus
index (PETCO2/SpO2) assumes a 1/1 contribution of these
chemostimuli to ventilatory drive. Laboratory studies in
humans and reduced animal model preparations suggest
that contributions from CO2 and O2 acting on central and
peripheral chemoreceptors change depending upon the activation state and responsiveness of chemoreceptors. For
example, the acute HVR test captures peripheral chemoreflex sensitivity, but in the poikilocapnic condition, which is
most relevant in the context in HA ascent, the ventilatory
response to hypoxia reduces CO2, blunting both peripheral
and central chemoreceptor contributions to subsequent
ventilatory drive. Accordingly, in acute poikilocapnic hypoxia, ventilation after 20-­min of hypoxia is not statistically
higher than baseline (Steinback & Poulin, 2007). With VA,
the peripheral chemoreflex increases its sensitivity to hypoxia at the prevailing CO2 (Duffin & Mahamed, 2003;
Loeschcke & Gertz, 1958; Teppema & Dahan, 2010).
However, with ascent, participants are chronically hypocapnic, and variability in renally mediated bicarbonate
elimination renders acid–­base conditions different from
baseline at sea level (e.g., Bird, Leacy, et al., 2021; Zouboules
et al., 2018). Thus, in low versus high altitude contexts, the
challenges of (a) differential background CO2/[H+] and
brain and blood buffering capacity (e.g., HCO3−), (b) the
known CO2-­O2 chemostimuli interaction at the carotid
body (e.g., Lahiri & DeLaney, 1975) and (c) the potential
for central-­
peripheral chemoreceptor interaction (e.g.,
Wilson & Teppema, 2016) make the issue of assessing
relative chemostimuli and contributions of chemoreceptor compartments in humans with acclimatization to HA
nearly impossible. These methodological caveats represent
the complexity that we aimed to overcome in the development of the SSCD. We suggest that the considerations of
separating contributions from chemostimuli and chemoreceptor compartments are less important in the integrated
system when the feedback loops are intact and participants
are breathing ambient air in the steady-­state. Assessing
the steady-­state ventilatory strategy employed in response
to prevailing chemostimuli is likely more representative
and important to assess than quantifying a single transient peak response to a transient gas challenge (e.g., Bruce
et al., 2018; Steinback & Poulin, 2007).

5

|

CONC LUSIONS

This study is the first to characterize a novel index of
steady-­state chemoreflex drive (SSCD) in the context of
incremental ascent to high altitude (HA) in two groups

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CATES et al.

|   

of trekkers: one acetazolamide-­free (NAz) and one taking an oral prophylactic dose (125 mg BID) of acetazolamide (Az) during ascent. We conclude that the SSCD
metric captures VA during incremental HA ascent, with
the associated measures being simple, safe, portable, and
feasible in HA fieldwork contexts. Specifically, ventilation and SSCD were larger following incremental ascent,
suggesting SSCD captures VA over a time course of 7 days
following incremental ascent to 4240 m, representing the
steady-­
state ventilatory strategy utilized by individuals
chronically exposed to hypobaric hypoxia. Additionally,
our data demonstrate that VA magnitude is augmented in
a group taking a prophylactic dose of oral Az compared
to NAz during incremental ascent. However, self-­reported
AMS scores were not related to the degree of VA assessed
via increases in resting ventilation or SSCD, likely due to
the low AMS scores associated with incremental ascent.
We suggest that the SSCD index holds promise as a simple, portable, and reliable tool reflecting an integrated
assessment of prevailing central and peripheral chemoreflex drive associated with exposure to HA. We encourage
other research groups to employ the SSCD metric for studies related to chemoreflex control of breathing to further
characterize its utility across a variety of ascent profiles
(incremental vs. rapid ascent and residence), duration
and with/without prophylactic or treatment doses of
acetazolamide.
AUTHOR CONTRIBUTIONS
Conception and design of the work: KDO, TDB, MTS,
TAD; Acquisition, analysis, or interpretation of data for
the work: All co-­authors; Drafting the work or revising
it critically for important intellectual content: All co-­
authors. In addition, all co-­authors, approved the final
version of the manuscript, agree 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, all persons designated as authors qualify for authorship, and all those who
qualify for authorship are listed.
ACKNOWLEDGMENTS
The authors gratefully acknowledge the time and effort
of our research participants, and Nima Sherpa (Glory of
Nepal Tours and Travel) and his guide team for organizing the logistics of the Nepal expeditions. We also thank
ADInstruments for their support of these research expeditions. Although not qualifying for authorship, a large team
of students and colleagues assisted with collecting ancillary measures with ascent, and we wish to acknowledge
them here for their help (alphabetic by last name): Jordan
Bird, Kennedy Borle, Rachelle Brandt, Dr. David Burns,
Jason Chan, Garrick Chan, Alexandra Chiew, Emily de

CATES et al.

Frietas, Brittney Herrington, Dr. Pontus Holmström,
Tegan Jones, Dr. Anne Kalker, Lauren Lavoie, Andrea
Linares, Leah Mann, Carli Mann, Cassandra Nysten,
Joel Peltonen, Jamie Pfoh, Zahrah Rampuri, Alexander
Rimke, Rupinder Sandhu, Jan Elaine Soriano, Scott
Thrall, Dr. Kartika Tjandra, Emily Vanden Berg, Shaelynn
Zouboules.
FUNDING INFORMATION
Financial support for this work was provided by (a)
Alberta Government Student Temporary Employment
Program, (b) Alberta Innovates Health Solutions Summer
Studentships, (c) Natural Sciences and Engineering
Research Council (NSERC) Undergraduate Student
Research Assistantships, (d) and NSERC Discovery Grant
Program (TAD; PGPIN-­2016-­04915). JKL is funded by
the Department of Physiology, University College Cork,
Ireland.
CONFLICT OF INTEREST
None declared.
ETHICS STATEMENT
This study abided by the Canadian Government Tri-­
Council policy on research ethics with human participants (TCPS2) and the Declaration of Helsinki, except for
registration in a database. Ethical approval was received
in advance through Mount Royal University Human
Research Ethics Board (Protocols 2015-­26b and 100012)
and was harmonized with the Nepal Health Research
Council (Protocols 96–­2015 and 109–­2017).
ORCID
Trevor A. Day

https://orcid.org/0000-0001-7102-4235

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How to cite this article: Cates, V. C., Bruce, C.
D., Marullo, A. L., Isakovich, R., Saran, G., Leacy, J.
K., O′Halloran, K. D., Brutsaert, T. D., Sherpa, M.
T., & Day, T. A. (2022). Steady-state chemoreflex
drive captures ventilatory acclimatization during
incremental ascent to high altitude: Effect of
acetazolamide. Physiological Reports, 10, e15521.
https://doi.org/10.14814/​phy2.15521

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