Dynamic assessment of multi-organ level dysfunction in patients recovering from COVID-19

Gupta, Ayushman (2024) Dynamic assessment of multi-organ level dysfunction in patients recovering from COVID-19. PhD thesis, University of Nottingham.

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Abstract

Since its emergence, the impact of acute coronavirus disease (COVID-19) on mortality has

been profound. However, in June 2020 there was an emerging picture of prolonged recovery

of people who had survived the acute infection. A huge proportion of individuals experienced

persisting and debilitating symptoms, such as fatigue, after resolution of the acute infection,

with many affected previously devoid of pre-existing medical conditions and disability. This

has resulted in increased time off from or return to work. In an era where the initial project

for this PhD was put on hold due to recruitment of patients that were vulnerable to severe

infection (assessment of cerebrovascular and cardiovascular haemodynamic response to

exercise in patients with COPD), the focus turned to addressing the long term impacts of

COVID-19. Whilst 3 years on there is now an abundant literature on symptoms, the

mechanisms remain poorly understood. In this thesis, a detailed physiological and metabolic

phenotyping was conducted of patients who survived severe acute respiratory syndrome

coronavirus 2 (SARS-CoV-2) related hospitalisation and healthy control volunteers, focussing

on muscle, metabolic, cardiovascular and cerebrovascular properties to elicit mechanisms

that drive symptoms +/- organ impairment.

Patients (n=21) recovering from severe hospitalisation of SARS-CoV-2 infection and without

previous diabetes, cardiovascular or cerebrovascular disease, were recruited 5-7 months after

discharge along with controls (n=10), with similar age, and sex. Validated state-of-the-art

magnetic resonance imaging (MRI) and spectroscopy (MRS) protocols during resting and

supine exercise were used to stress the body and best elucidate cardiovascular and

cerebrovascular pathophysiology as well quantifying skeletal muscle mitochondrial oxidative

capacity. These in-bore exercise procedures were previously optimised and their feasibility

addressed within healthy and different disease populations including volunteers with chronic

obstructive pulmonary disease (COPD). An oral glucose tolerance test (OGTT) in conjunction

with fuel oxidation enabled dynamic assessment of whole body insulin sensitivity, glucose

disposal and fuel utilisation. Resting MRI of the brain, heart and muscle assessed any organ

injury or dysfunction. Additional measures included: venous blood sampling for biomarkers

of muscle, cardiac, liver, metabolic dysfunction and inflammatory markers, dual energy X-ray

absorptiometry, short physical performance battery (SPPB), hand grip strength, intramuscular

electromyography, quadriceps strength and fatigability, step count and participant reported

outcome measures (PROMs). In particular, fatigue severity scale (FSS) was used to quantify

perception of fatigue. To further examine mechanisms contributing to fatigue, a sub-group

analysis between patients with (FSS >36) and without (FSS<36) perception of fatigue was

conducted.

In summary, there was a larger insulin response during the OGTT in patients vs controls

suggestive of a greater degree of insulin resistance. Blood glucose response and carbohydrate

oxidation rate were not different. The insulin resistance was not explained by systemic

inflammatory mediators or whole-body/leg muscle adiposity but reduced step count and

presence of fatty liver were independent factors associated with reduced whole body insulin

sensitivity in patients, possible drivers for peripheral and hepatic insulin resistance. Patients

displayed worse FSS and SPPB scores. Leg muscle volume, strength, force-loss, motor unit

properties and mitochondrial function were comparable. Further, cardiac and cerebral

architecture and function (rest and exercise-based) were not different. In the sub-group

analysis patients with a perceived fatigue exhibited worse SPPB scores, reduced step count

and blunted cerebral blood flow response to supine exercise compared to non-fatigued

patients.

Taken collectively, the multifaceted approach to characterising the long term effects of COVID-19 revealed that individuals without previous morbidity who survived severe COVID 19 were limited in habitual function and exhibited insulin resistance, providing essential information for rehabilitation strategies.

Item Type: Thesis (University of Nottingham only) (PhD)
Supervisors: Bolton, Charlotte
Francis, Susan
Greenhaff, Paul
Keywords: Long term consequences; Severe COVID-19 infection; Metabolic systems
Subjects: W Medicine and related subjects (NLM Classification) > WC Communicable diseases
Faculties/Schools: UK Campuses > Faculty of Medicine and Health Sciences > School of Medicine
Item ID: 76987
Depositing User: Gupta, Ayushman
Date Deposited: 31 Jul 2024 04:40
Last Modified: 31 Jul 2024 04:40
URI: https://eprints.nottingham.ac.uk/id/eprint/76987

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