u n i v e r s i t y  o f  c o p e n h a g e n  

Bioenergy Crisis in Coronavirus Diseases?

Dutta, Anirban; Das, Abhijit; Kondziella, Daniel; Stachowiak, Michal K.

Published in:
Brain Sciences

DOI:
10.3390/brainsci10050277

Publication date:
2020

Document version
Publisher's PDF, also known as Version of record

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Citation for published version (APA):
Dutta, A., Das, A., Kondziella, D., & Stachowiak, M. K. (2020). Bioenergy Crisis in Coronavirus Diseases? Brain
Sciences, 10(5), [277]. https://doi.org/10.3390/brainsci10050277

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brain
sciences

Editorial

Bioenergy Crisis in Coronavirus Diseases?

Anirban Dutta 1,* , Abhijit Das 2, Daniel Kondziella 3,4 and Michal K. Stachowiak 5

1 Department of Biomedical Engineering, University at Buffalo, Buffalo, NY 14260, USA
2 Department of Neurology, The Walton Centre NHS Foundation Trust, Liverpool L9 7LJ, UK;

abhijit.neuro@gmail.com
3 Department of Neurology, Rigshospitalet, Copenhagen University Hospital, 2100 Copenhagen, Denmark;

Daniel.Kondziella@regionh.dk
4 Department of Clinical Medicine, Faculty of Health and Medical Sciences, University of Copenhagen,

2200 Copenhagen, Denmark
5 Department of Pathology and Anatomical Sciences, University at Buffalo, Buffalo, NY 14203, USA;

mks4@buffalo.edu
* Correspondence: anirband@buffalo.edu; Tel.: +1-716-645-9161

Received: 30 March 2020; Accepted: 16 April 2020; Published: 2 May 2020
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Coronavirus disease (COVID-19) has been declared as a pandemic by the World Health
Organization (WHO). Typical symptoms reported in COVID-19 are respiratory illness. About 80%
of the infections are not severe (even asymptomatic), whereas out of the hospitalized COVID-19
patients with pneumonia, about 50% developed hypoxemia by day eight while about 17–29%
developed acute respiratory distress syndrome (Wuhan experience) [1]. Recently, neurological
complications are increasingly reported [2], including encephalopathy in an elderly 74-year-old
male [3]. The computed tomography (CT) scan of the head showed no acute abnormalities; however,
the electroencephalogram (EEG) showed bilateral slowing and focal slowing in the left temporal region
with sharply countered waves. This led to the possibility of subclinical seizures due to the presence
of an area of encephalomalacia consistent with the prior history of embolic stroke, and the patient
remained in the intensive care unit (ICU) with poor prognosis. Filatov et al. [3] found that elderly
patients with such chronic conditions and with acute infections are at an increased risk of altered mental
status even though COVID-19 did not cause meningitis or encephalitis in this case study. Nevertheless,
Filatov et al. [3] case study highlighted the need to identify encephalopathy as a presenting sign of
COVID-19, especially in cases with altered mental status including delirium, where severe cases can
lead to long-term cognitive impairments.

Respiratory virus infections trigger inflammatory responses both at the site of infection (in the
upper and lower respiratory tract) as well as systemically. Here, sepsis-associated encephalopathy (SAE)
can be a transient and reversible brain dysfunction in patients with COVID-19, where a subgroup of
critically ill patients can develop septic shock [4]. Anti-tumor necrosis factor (TNF) antibodies have been
found in the blood and diseased tissues of COVID-19 patients [5]. The severity of inflammatory excess
is due to the cascade of cytokine production, the cytokine storm, where TNF can act as an amplifier of
inflammation [5]. Intracranial cytokine storms can result in blood-brain-barrier breakdown without
direct viral invasion [6]. In fact, the endothelium is a principal organ involved in the pathogenesis
of sepsis, leading to multiple organ failure [7]. The clinical spectrum of SAE can include sickness
behavior, delirium, focal deficits, and coma [8]. The EEG features of SAE can include excessive theta
rhythms, predominant delta rhythms, triphasic waves, and burst suppression along with seizures in
up to 15% of patients. The review by Heming et al. [8] highlighted the use of various EEG monitoring
tools in sepsis; however, Heming et al. [8] also found that the EEG monitoring methods remained
ill-defined for sepsis. Heming et al. [8] reported that SAE is associated with neurovascular uncoupling
due to microcirculatory dysfunction and low blood flow. Therefore, we postulate that the use of

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Brain Sci. 2020, 10, 277 2 of 6

EEG monitoring will be more informative in conjunction with functional near-infrared spectroscopy
(NIRS) such that any neurovascular uncoupling can be detected [7] during EEG events. Neurovascular
coupling is important since it adapts local cerebral blood flow to the neural metabolic needs [9] that
maintains the neuroenergetic status of the neurovascular tissue so any neurovascular uncoupling
can lead to an energy crisis in the brain tissue [10]. Here, a majority of the energy in the brain is
generated by the oxidative phosphorylation in the mitochondria where the energy currency, adenosine
triphosphate (ATP), production rate plays a central role in brain bioenergetics [11].

Lee and Huettemann [10] presented a model in which inflammatory signaling changes
the phosphorylation state of the mitochondrial proteins leading to inhibition of the oxidative
phosphorylation. Since oxidative phosphorylation in the mitochondria generates a majority of the ATP so
inhibition of the oxidative phosphorylation can lead to an energy currency crisis. Moreover, hypoxemia
due to severe respiratory failure in respiratory virus infections can further aggravate the energy
crisis. Powerful anti-inflammatory drugs can limit the inflammation but have the risk of increasing
viral replication or bacterial infections [5], which can lead to meningitis/encephalitis [12]. Therefore,
investigation of an adjunct therapy targeting dysfunctional mitochondrial metabolism [13] is proposed,
including photobiomodulation [14], since ATP acts as a purinergic feedback signaling molecule where
low ATP concentrations almost exclusively recruit microglial cells [15]. Purinergic signaling cascade
is also involved with the complex vascular response at the capillaries (pericytes) [16], which can be
partly responsible for the cerebrovascular complications of COVID-19 [7]. We further postulate that
continuous fNIRS–EEG joint monitoring can be a useful bedside multimodal monitoring tool in neuro
ICU [17] to detect transient neurovascular uncoupling. Continuous fNIRS–EEG joint monitoring will
also be essential to monitor the effect of some sedative drugs that can affect neurovascular coupling
and may increase the risk of delirium. However, patients in neuro ICU rarely undergo continuous
brain monitoring along the lines of continuous electrocardiogram (ECG) in the cardiac ICU. Here,
portable platforms with centralized multimodal data acquisition and signal processing have been
found useful [18]. Moreover, some patients can be particularly susceptible to cytokine storms [19],
where continuous brain monitoring can be necessary for triaging. Also, identifying genetic mechanisms
underlying brain susceptibility to cytokine storms [19] will be important as predictors in addition to
quantitative brain monitoring measures. Specifically, genetic insights into the mechanisms of fibroblast
growth factor (FGF) signaling [20]. FGF signaling is increasingly being found essential for metabolic
homeostasis in the tissues [20], where aberrant FGF receptor can enhance the Warburg Effect and
mitochondrial dysfunction [21]. Recent data shows that FGF21 protects against hypoxia stress-induced
injury in the cerebral microvascular endothelial cells [22]. So, FGF signaling can have a protective role
not only in hypoxia-related brain disorders, e.g., encephalopathy, but also in neurodevelopmental
disorders, e.g., schizophrenia [23], due to prenatal immune insult [24]. Without quantitative brain
monitoring of the neuroenergetics and the functional genomics, deeper understanding of the early
neurovascular signs of SAE will remain unfulfilled that is important for triaging and for tailoring
the therapies.

Mitochondrial dysfunction related to microcirculatory dysfunction [8], with an inhibition of
mitochondrial respiratory chain and a decrease of oxygen utilization, remains poorly understood [25].
An increased level of proinflammatory cytokines (such as TNF, interleukins, etc.) can affect various
organs by affecting their mitochondrial energy homeostasis and vascular hyperpermeability where the
initial effects can be found in the skeletal muscles, heart, liver, and lungs. Here, mitochondrial respiration,
which seems to evolve during sepsis [25,26], can be monitored using non-invasive broadband
near-infrared spectroscopy of the cytochrome oxidase redox state [27] in various tissues including
skeletal muscles. Yamane et al. [28] showed in severe influenza the relation between the host metabolic
disorder-cytokine cycle and the influenza virus-cytokine-trypsin cycle in the skeletal muscles, heart, liver,
and lungs (but not in the brain) which were driven by the cytokine storm. Immunomodulatory therapy
has been proposed to improve the outcome in severe influenza [29]; however, its effects in the case of
coronavirus disease are currently being evaluated (https://www.biocentury.com/article/304515) [30].

https://www.biocentury.com/article/304515


Brain Sci. 2020, 10, 277 3 of 6

Nevertheless, human as well as animal studies are expensive and time-consuming so we propose a
Phase-0 paradigm for drug screening and personalized medicine using microglia-containing organoid
models [31,32]. This is crucial since immunomodulation can be a double-edged sword where
some patients can be more susceptible than others [19]. We also propose a mini-brain computer
interface (see Figure 1) [33] that combines electrophysiological recordings (using Open Ephys [34]) and
Vis-near-infrared (NIR) broadband spectroscopy [35] to monitor the neuronal as well as neurometabolic
coupling state in the microglia-containing cerebral-vascular organoids. Figure 1 shows the experimental
setup where a 32-channel 3D microelectrode array (MEA) based electrophysiological (Ephys) recording
was combined with the broadband Vis-NIR spectroscopy of the activity of the mitochondrial Electron
Transport Chain (ETC) complexes. Also, computational anatomy and functional genomics were
performed on the organoids [23] that are proposed to investigate genetic mechanisms underlying brain
susceptibility to cytokine storms [19] and bioenergy crisis.

Brain Sci. 2020, 10, 277 3 of 6 

others [19]. We also propose a mini-brain computer interface (see Figure 1) [33] that combines 
electrophysiological recordings (using Open Ephys [34]) and Vis-near-infrared (NIR) broadband 
spectroscopy [35] to monitor the neuronal as well as neurometabolic coupling state in the microglia-
containing cerebral-vascular organoids. Figure 1 shows the experimental setup where a 32-channel 
3D microelectrode array (MEA) based electrophysiological (Ephys) recording was combined with the 
broadband Vis-NIR spectroscopy of the activity of the mitochondrial Electron Transport Chain (ETC) 
complexes. Also, computational anatomy and functional genomics were performed on the organoids 
[23] that are proposed to investigate genetic mechanisms underlying brain susceptibility to cytokine 
storms [19] and bioenergy crisis.  

In the subsequent human drug studies, broadband near-infrared spectroscopy of the brain [36] 
and the skeletal muscles can monitor the evolution of the systemic inflammatory response [37] to 
tailor the immunomodulation. An inexpensive solution using multi-wavelength continuous-wave 
(CW) NIRS–EEG multimodal monitoring has been developed for bedside continuous monitoring in 
the acute brain injury [38] to measure the neurovascular coupling (neuroenergetics) in the brain. 
Multiple wavelengths can be selected in the near-infrared optical windows [39] for robust CW-NIRS 
of the skeletal muscles and the brain where EEG in the case of the brain can provide additional 
metabolic disorder related features in the patients [40]. Here, the coupling relation of those EEG 
events, including non-convulsive status epilepticus, vis-à-vis multi-wavelength CW-NIRS-measured 
changes in the oxy- and deoxyhemoglobin as well cytochrome oxidase redox state can provide a 
marker of the severity of SAE. Therefore, we postulate that the normalization of dysfunctional EEG 
features as well as the neuroenergetics (from neurovascular and neurometabolic coupling) may be a 
prognostic marker of intact recovery without long-term cognitive impairments in the critically ill 
COVID-19 patients with transient and reversible brain dysfunction due to SAE. Furthermore, we 
highlight the need to investigate continuous bedside monitoring of bioenergetics, including 
mitochondrial ETC complexes, in the skeletal muscles and the brain in sepsis. 

 

Figure 1. Mini-brain computer interface that combines electrophysiological recordings with the Vis-
near-infrared (NIR) broadband spectroscopy to monitor the neuronal, metabolic, as well as 
neurometabolic coupling state in the cerebral vascular organoids (adapted from [33]). 

  

Figure 1. Mini-brain computer interface that combines electrophysiological recordings with the
Vis-near-infrared (NIR) broadband spectroscopy to monitor the neuronal, metabolic, as well as
neurometabolic coupling state in the cerebral vascular organoids (adapted from [33]).

In the subsequent human drug studies, broadband near-infrared spectroscopy of the brain [36]
and the skeletal muscles can monitor the evolution of the systemic inflammatory response [37] to tailor
the immunomodulation. An inexpensive solution using multi-wavelength continuous-wave (CW)
NIRS–EEG multimodal monitoring has been developed for bedside continuous monitoring in the
acute brain injury [38] to measure the neurovascular coupling (neuroenergetics) in the brain. Multiple
wavelengths can be selected in the near-infrared optical windows [39] for robust CW-NIRS of the
skeletal muscles and the brain where EEG in the case of the brain can provide additional metabolic
disorder related features in the patients [40]. Here, the coupling relation of those EEG events, including
non-convulsive status epilepticus, vis-à-vis multi-wavelength CW-NIRS-measured changes in the oxy-
and deoxyhemoglobin as well cytochrome oxidase redox state can provide a marker of the severity
of SAE. Therefore, we postulate that the normalization of dysfunctional EEG features as well as the
neuroenergetics (from neurovascular and neurometabolic coupling) may be a prognostic marker
of intact recovery without long-term cognitive impairments in the critically ill COVID-19 patients
with transient and reversible brain dysfunction due to SAE. Furthermore, we highlight the need to
investigate continuous bedside monitoring of bioenergetics, including mitochondrial ETC complexes,
in the skeletal muscles and the brain in sepsis.



Brain Sci. 2020, 10, 277 4 of 6

Author Contributions: Writing—original draft, A.D. (Anirban Dutta); Methodology, D.K.; Writing—review &
editing, A.D. (Anirban Dutta), A.D. (Abhijit Das), D.K., and M.K.S. All authors have read and agreed to the
published version of the manuscript.

Acknowledgments: The support provided by the Community for Global Health Equity (CGHE) at the University
at Buffalo (UB), Department of Biotechnology (DBT), Government of India, the Bill and Melinda Gates Foundation
& IKP Knowledge Park, India as well as UB NSF I-Corps program is gratefully acknowledged.

Conflicts of Interest: The authors declare no conflict of interest. The funders had no role in the design of the
study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to
publish the results

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(CC BY) license (http://creativecommons.org/licenses/by/4.0/).

http://dx.doi.org/10.1007/s12028-020-00971-x
http://www.ncbi.nlm.nih.gov/pubmed/32333214
http://dx.doi.org/10.1002/jbio.201500192
http://www.ncbi.nlm.nih.gov/pubmed/26556561
http://dx.doi.org/10.1097/WNP.0b013e3182a73db9
http://www.ncbi.nlm.nih.gov/pubmed/24084183
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http://creativecommons.org/licenses/by/4.0/.

	References