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Review

Impact of Pulmonary Comorbidities on COVID-19: Acute and Long-Term Evaluations

by
Gabriela Mara
1,2,
Gheorghe Nini
2 and
Coralia Cotoraci
3,*
1
Multidisciplinary Doctoral School, Vasile Goldis Western University of Arad, 310414 Arad, Romania
2
Pneumology Department, Vasile Goldis Western University of Arad, 310414 Arad, Romania
3
Clinical Hematology Department, Vasile Goldis Western University of Arad, 310025 Arad, Romania
*
Author to whom correspondence should be addressed.
J. Clin. Med. 2025, 14(5), 1446; https://doi.org/10.3390/jcm14051446
Submission received: 4 February 2025 / Revised: 15 February 2025 / Accepted: 18 February 2025 / Published: 21 February 2025
(This article belongs to the Special Issue Novel Insights into COVID-19-Associated Complications and Sequelae)
Versions Notes

Abstract

:
Background/Objectives: Pulmonary comorbidities, such as chronic obstructive pulmonary disease (COPD), asthma, and interstitial lung diseases (ILDs), have emerged as critical factors influencing the severity and outcomes of COVID-19. This review aims to evaluate the interplay between these comorbidities and COVID-19, both during the acute phase and in long-term recovery, focusing on their impact on clinical management and outcomes. Methods: This systematic review examined studies sourced from major medical databases, including PubMed and Scopus, using keywords such as “COVID-19”, “pulmonary comorbidities”, “long COVID”, and “respiratory sequelae”. Peer-reviewed articles published from January 2020 to the present were included, with data extracted to evaluate both the acute and long-term effects of these comorbidities on COVID-19 patients. Results: Patients with COPD demonstrated significantly higher risks of severe COVID-19, including increased hospitalization and mortality. Asthma, while less consistently associated with severe outcomes, showed a variable risk based on disease control. ILDs were strongly correlated with poor outcomes, including higher rates of respiratory failure and mortality. Long-term complications, such as persistent dyspnea, impaired lung function, and structural changes like fibrosis, were prevalent in patients recovering from moderate to severe COVID-19. These complications adversely affected quality of life and increased healthcare dependency. Conclusions: Pulmonary comorbidities amplify both the acute severity and long-term respiratory consequences of COVID-19. Effective management necessitates tailored strategies addressing both phases, integrating rehabilitation and continuous monitoring to mitigate chronic impairments. Future research should prioritize understanding the mechanisms behind these interactions to inform public health interventions and improve patient outcomes.

1. Introduction

In December 2019, a new strain of coronavirus, SARS-CoV-2, was first detected in Wuhan, Hubei Province, China. It was identified as the pathogen responsible for a series of unusual respiratory infections, later named COVID-19. Due to its rapid worldwide transmission and profound effects on healthcare systems, the World Health Organization officially classified it as a pandemic on 11 March 2020 [1]. The COVID-19 pandemic has posed major challenges to global health, emphasizing the importance of understanding how pre-existing medical conditions influence disease outcomes [2]. Among these, pulmonary comorbidities, such as chronic obstructive pulmonary disease (COPD), asthma, and interstitial lung diseases, have been recognized as significant contributors to the severity of COVID-19 infections [2]. Additionally, the long-term respiratory complications linked to COVID-19, often referred to as post-COVID-19 conditions or post-acute sequelae of SARS-CoV-2 infection, present further challenges for both healthcare systems and those impacted by the disease [3].
This review aims to provide a thorough analysis of the connection between pulmonary comorbidities and COVID-19 severity, while also examining the long-term respiratory effects of post-COVID-19 conditions. By evaluating existing research, it seeks to clarify how pre-existing respiratory conditions—such as chronic obstructive pulmonary disease (COPD), asthma, and interstitial lung diseases—impact COVID-19 progression and outcomes. Additionally, it highlights the prevalence and nature of persistent respiratory complications, including functional impairments and structural lung changes, that may develop following acute infection. Ultimately, this review aims to synthesize current knowledge to guide public health strategies, improve clinical management for at-risk populations, and identify key areas for future research to address gaps in understanding and care for those affected by COVID-19 and its long-term consequences.

2. Methods

The methodology for this review was carefully designed to ensure a comprehensive and structured exploration of the impact of pulmonary comorbidities on COVID-19 severity and the long-term respiratory consequences of post-COVID-19 conditions. A systematic search was conducted across major academic and medical databases, including PubMed, Scopus, and Web of Science. The search strategy utilized specific keywords such as “COVID-19”, “pulmonary comorbidities”, “long COVID”, and “respiratory sequelae”. Articles published between January 2020 and the present were considered to ensure that the analysis reflected the most current knowledge.

3. Pulmonary Comorbidities and COVID-19 Severity: Examination of How Chronic Respiratory Diseases Affect Acute COVID-19 Outcomes

Chronic respiratory diseases (CRDs), such as chronic obstructive pulmonary disease (COPD), asthma, and interstitial lung diseases (ILDs), are critical factors influencing the severity and progression of COVID-19 [4]. Patients with pre-existing CRDs often experience more severe clinical outcomes due to the underlying physiological and immune dysfunction associated with these conditions [5]. Understanding these interactions is essential to optimize care and improve prognosis for this vulnerable population.
COPD is one of the most significant pulmonary comorbidities linked to severe COVID-19 [6]. This disease is characterized by chronic inflammation, structural lung damage, and airflow limitation, which reduce the patient’s ability to effectively respond to respiratory infections. Numerous studies have demonstrated that COPD patients with COVID-19 face higher risks of hospitalization, intensive care unit (ICU) admission, mechanical ventilation, and mortality (Table 1).
Asthma, another common CRD, presents a complex relationship with COVID-19 outcomes. While early studies suggested that asthma might not significantly increase the risk of severe disease, more recent data indicate that factors such as airway hyperresponsiveness and chronic inflammation can exacerbate the respiratory distress caused by SARS-CoV-2 [17]. However, well-managed asthma, particularly in patients adhering to maintenance therapy, may not substantially elevate the severity of COVID-19 (Table 2).
ILDs, including idiopathic pulmonary fibrosis (IPF), are also associated with poorer outcomes in COVID-19. ILDs involve chronic inflammation and fibrotic changes in lung tissue, leading to impaired gas exchange and a reduced pulmonary reserve. When infected with SARS-CoV-2, these patients are more likely to experience severe hypoxemia and respiratory failure. Studies have shown that ILD patients with COVID-19 have increased mortality rates compared to those without pre-existing pulmonary fibrosis, highlighting the compounded risks posed by reduced lung capacity and systemic inflammatory responses (Table 3).

4. Post-COVID-19 Pulmonary Sequelae: Long-Term Respiratory Complications and Clinical Manifestations

Post-COVID-19 pulmonary sequelae have emerged as a significant concern, particularly for patients who experienced moderate to severe forms of COVID-19. These long-term complications often manifest as persistent respiratory symptoms, functional impairments, and structural abnormalities in the lungs, with substantial implications for quality of life and healthcare systems worldwide (Table 4).
These long-term complications underscore the importance of ongoing research to better understand post-COVID-19 pulmonary sequelae and develop effective therapies. As the pandemic’s impact continues to evolve, addressing these issues will remain a critical component of healthcare systems globally.

5. Comparative Analysis: Evaluation of the Relative Impact of Pulmonary Comorbidities During the Acute Phase Versus the Chronic Phase of COVID-19

The interplay between pulmonary comorbidities and COVID-19 manifests differently during the acute and chronic phases of the disease, reflecting distinct challenges in clinical management and long-term care. This comparative analysis aims to evaluate how conditions like chronic obstructive pulmonary disease (COPD), asthma, and interstitial lung diseases (ILDs) influence outcomes during these two phases (Table 5).
The burden of COVID-19 in patients with pulmonary comorbidities varies significantly between the acute and chronic phases of the disease. During the acute phase, the focus is on managing severe inflammatory responses, acute hypoxemia, and the high demand for critical care resources. In contrast, the chronic phase is characterized by lingering respiratory complications, prolonged oxygen dependency, and the need for long-term healthcare interventions. The table below compares these key aspects across the two phases (Table 6).

6. Implications for Clinical Management

Managing patients with pulmonary comorbidities who contract COVID-19 requires a tailored approach that addresses the unique challenges of both the acute and chronic phases of the disease. During the acute phase, the primary focus is on mitigating severe complications, such as respiratory failure and thrombotic events, while ensuring optimal control of underlying lung conditions. In the post-acute and chronic phases, attention shifts to long-term recovery, rehabilitation, and the management of persistent symptoms and pulmonary sequelae. The table below outlines key strategies for each phase of clinical management (Table 7).
Oxygen therapy is essential for managing respiratory complications in COVID-19, especially in patients with COPD and idiopathic pulmonary fibrosis. Severe cases often require high-flow nasal oxygen, non-invasive ventilation, or mechanical ventilation [26]. Post COVID-19, long-term oxygen therapy may be needed due to persistent fibrosis and diffusion impairment, improving functional outcomes and reducing hospital readmissions [46]. However, the optimal duration and monitoring continue to be debated.
There have been advancements in AI support clinical management, with a wrapper-based deep learning technique achieving 97.7% accuracy in detecting chest infections, including COVID-19, from X-rays. By combining deep feature extraction, ten optimization algorithms, and a support vector machine, this method enhances diagnostic precision and aids early detection and decision-making for pulmonary comorbidities [47].

7. Conclusions

This review highlights the critical influence of pulmonary comorbidities, such as COPD, asthma, and interstitial lung diseases, on the severity and outcomes of COVID-19. Patients with these conditions are more susceptible to severe complications during the acute phase, including increased hospitalization and mortality rates. Furthermore, the long-term effects, characterized by persistent respiratory symptoms, functional impairments, and structural lung changes, add substantial burden to survivors. The review underscores the necessity for tailored clinical management and ongoing research to better understand and address the complex interplay between COVID-19 and pre-existing pulmonary diseases, aiming to inform future healthcare strategies and improve patient outcomes.

Author Contributions

Conceptualization, G.M. and C.C.; methodology, G.M.; writing—original draft preparation, G.M., G.N. and C.C.; writing—review and editing, G.M. and C.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflicts of interest.

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Table 1. COPD and COVID-19 clinical outcomes analysis.
Table 1. COPD and COVID-19 clinical outcomes analysis.
CountryStudy TypeTotal ParticipantsMain Reported Outcomes/AnalysesReferences
SUALongitudinal Cohort Study157 patientsAssessed the physical and mental health of COPD patients during the COVID-19 pandemic; found low incidence of COVID-19 infection and stable levels of anxiety and depression among participants.
Elevated anxiety (8%) and depressive symptoms (19%) in June 2020 remained stable throughout follow-up.		[7]
SUARetrospective Cohort Study31,526 patientsEvaluated outcomes of COPD patients hospitalized with COVID-19; Mortality was higher in COPD patients (14.02%) compared to those without COPD (8.8%); COPD mortality risk varied by sex and age, being higher in females (OR 1.62, 95% CI 1.36–1.95) but not in males. Increased risk was also noted in patients aged 40–64 (OR 1.42, 95% CI 1.07–1.90) and 65–79 (OR 1.48, 95% CI 1.23–1.78) years.[8]
SUARetrospective Study577 patients, of which 103 were diagnosed with COPD/emphysemaInvestigated the impact of COPD and emphysema on hospitalized COVID-19 patients; concluded that pre-existing COPD and radiographic evidence of emphysema had higher rates of intensive care unit (ICU) admission (35% versus 24.9%) and maximal respiratory support requirements, with more frequent invasive mechanical ventilation (21.4% versus 11.8%), but no significant difference in mortality.[9]
GlobalSystematic Review and Meta-Analysis123 studiesCOPD prevalence in patients hospitalized with COVID-19 varies markedly by region (3.82 to 11.85%); COPD was associated with increased mortality risk 1.863 (95% CI 1.640–2.115).[10]
SpainRetrospective Case–Control Study120 patientsEvaluated the impact of COVID-19 on COPD exacerbations and clinical course; found that COVID-19 led to increased exacerbations and worse clinical outcomes in COPD patients compared to non-COVID-19 periods.[11]
ChinaMulticenter, Retrospective, Observational Study1048 patients of which 50 were diagnosed with COPDPatients with COPD showed a higher risk of developing
bacterial/fungal coinfection (20.0% vs. 5.9%), acute respiratory distress syndrome (ARDS) (20.0% vs. 7.3%), septic shock (14.0% vs. 2.3%), or acute renal failure (12.0% vs. 1.3%); and there was a risk of death (HR: 2.28, 95% CI: 1.15–4.51; p = 0.019).		[12]
DenmarkCohort Study5104 patients, of which 432 were diagnosed with COPD The standardized absolute risk of the combined end-point was 21.2% (95% CI 18.8–23.6).
Low blood eosinophil counts (<0.3 × 109 cells·L−1) were associated with increased risk of severe outcomes among patients with COPD.		[13]
GlobalSystematic Review and Meta-Analysis100 studies (n = 1,229,434 patients)COPD significantly increased the mortality risk (OR 3.79, p < 0.001).[14]
Latin AmericaSystematic Review and Meta-AnalysisMultiple studiesCOPD prevalence in hospitalized COVID-19 patients varies significantly across Latin American countries; post-COVID-19 pulmonary fibrosis remains a major challenge due to limited healthcare resources and access to specialized care.[15]
AfricaObservational StudyMultiple studies and reportsCOVID-19 worsened lung health outcomes in Africa, particularly for patients with pre-existing chronic respiratory diseases (CRDs) such as COPD. Limited access to healthcare, a lack of diagnostic tools (e.g., spirometry), and a redirection of resources to COVID-19 response led to underdiagnosis and undertreatment of these conditions. Additionally, exposure to environmental pollutants, tobacco smoke, and high rates of tuberculosis further increased the severity of COVID-19 in African populations.[16]
Table 2. Asthma and COVID-19 clinical outcomes analysis.
Table 2. Asthma and COVID-19 clinical outcomes analysis.
CountryStudy TypeTotal ParticipantsMain Reported Outcomes/AnalysesReferences
Hong KongRetrospective Cohort Study74,396, of which 1290 were diagnosed asthma patientsThe rates of death and the composite outcome were 15.3% and 17.2%, respectively, and among the non-asthma patients, they were 12.2% and 13.6%, respectively.
Asthma reduced disease severity risk despite incomplete vaccination.		[18]
JapanRetrospective Multivariate Analysis72,582 patients, of which 3731 were diagnosed with asthmaAsthma showed no significant association with an increase in mortality (OR 0.837, 95% CI 0.639–1.080, p  =  0.184) or invasive mechanical ventilation events (OR 1.084, 95% CI 0.878–1.326, p  =  0.440).[19]
UKRetrospective Study35,202,533 adults and 2,996,503 childrenAdults with asthma on medium or high-dose inhaled corticosteroids had a higher risk of COVID-19 death (HRs 1.18 and 1.36).
Hospitalization risk was higher for children with asthma who were prescribed one (2.58) or multiple (3.80) corticosteroid courses pre-pandemic.		[20]
UKMixed Methods Analysis4500 people diagnosed with asthmaAmong asthma patients with COVID-19 (10.5%, n = 471), 56.1% reported long COVID. This group experienced worsened breathing (73.7% vs. 34.8%), increased inhaler use (67.8% vs. 34.8%), and poorer asthma control (59.6% vs. 25.6%) (p < 0.001).[21]
GlobalSystematic Review and Meta-Analysis90 studiesAsthma patients with COVID-19 had a slightly higher hospitalization risk (RR 1.13) but no increased risk for severe disease, ICU admission, ventilation, or death.[17]
GlobalSystematic Review and Meta-Analysis30 (n = 112,420) studiesAsthma was linked to lower risk for all outcomes, but evidence was very uncertain (95% CIs included no difference or increased risk). Hospitalization data showed high heterogeneity. Allergic asthma lowered COVID-19 risk, while COPD increased it.[22]
GlobalSystematic Review and Meta-Analysis100 studies (n = 1,229,434 patients)Asthma had no significant impact on COVID-19 mortality (OR 0.89, p = 0.630). [14]
GlobalSystematic Review and Meta-Analysis123 studiesAsthma prevalence was 4.21 to 12.39%; the relative risk of death for asthma was 0.918 (95% CI 0.767 to 1.098) with no evidence of increased mortality.[10]
DenmarkCohort Study5104 patients, of which 354 were diagnosed with asthmaThe standardized absolute risk of the combined end-point was 18.5% (95% CI 14.3–22.7) in patients with asthma.[13]
Table 3. ILDs and COVID-19 clinical outcomes analysis.
Table 3. ILDs and COVID-19 clinical outcomes analysis.
CountryStudy TypeTotal ParticipantsMain Reported Outcomes/AnalysesReferences
USAMulticenter study311,060 patients, of which 251 patients (0.08%) were diagnosed with IPFIPF patients (mean age 68.3, 56.97% male) had more comorbidities than non-IPF patients. After matching, they had higher 30- and 60-day mortality or ventilation rates, hospitalization, critical care needs, and acute kidney injury.[23]
UKMulticenter study349 ILD patientsMortality in ILD patients with COVID-19 was 49% (79/161). Death risk was higher with FVC < 80% (HR 1.72) and obesity (HR 2.27).[24]
GlobalSystematic review and meta-analysis15 studies with 135,263 patients, of which 1.4% were diagnosed with ILDILD prevalence in COVID-19 patients was 1.4%. ILD was more common in non-survivors (RR 2.728) and increased mortality (RR 2.454) and ICU admission risk (RR 3.064). Mechanical ventilation rates showed no difference.[25]
SpainMulticenter study137 patients diagnosed with ILDIPF patients tended to have ILD worsening (60%, p = 0.12), while other ILD patients showed a trend toward recovery (63.4%, p = 0.124)[26]
JapanMulticenter study937,758, of which 7333 (0.8%) had pre-existing ILDILD prevalence declined across waves (wild-type 1.2%, alpha 0.8%, delta 0.3%), as did 60-day mortality (16.0%, 14.6%, 7.5%). Mortality significantly decreased from alpha to delta (−7.1%, 95% CI −9.3% to −4.9%). ILD was independently linked to higher mortality in all waves (OR ~2.10). [27]
JapanClinical study26 ILD patientsSevere cases (23.1% vs. 42.3%, p = 0.114) and mortality (11.5% vs. 3.8%, p = 0.326) were higher in the ILD group, though not statistically significant.[28]
JapanMulticentric study854 patients with acute exacerbation of ILDHospitalizations increased at 17 hospitals, decreased at 27, and remained unchanged at 88. COVID-19-related exacerbations had worse 30- and 90-day mortality than non-COVID-19 ones.[29]
AustraliaMulticentric study145 COVID-19 patients, with 133 reassessed after 100 days41% had persistent symptoms at 100 days; 63% showed radiological lung abnormalities (GGOs, consolidation, reticulation).
Most patients experienced symptom and lung improvement within 3 months.		[30]
ItalyRetrospective study90 patientsPulmonary fibrosis developed in 23 patients (25.5%), mostly older males (75 ± 15 years), with high rates of smoking (60.8%) and comorbidities, particularly hypertension (47.8%) and diabetes (34.7%).[31]
NorwayProspective cohort study103 participants, including 15 ICU patientsOne in four patients had persistent lung abnormalities and impaired gas exchange 3 months following hospital admission for COVID-19. ICU admission was linked to more CT abnormalities but did not worsen lung function or dyspnoea.[32]
Table 4. Key aspects of post-COVID-19 pulmonary sequelae.
Table 4. Key aspects of post-COVID-19 pulmonary sequelae.
CategoryKey FindingsExamples/DetailsReferences
Persistent SymptomsLong-term respiratory issues reported by patients.- Dyspnea: Common among survivors; linked to impaired gas exchange and reduced lung capacity.
- Chronic Cough: Often due to residual airway inflammation.
- Fatigue: Multifactorial, often coexisting with respiratory impairments.		[33]
Pulmonary FunctionImpairments detected in lung function tests.- Reduced DLCO: Indicates impaired alveolar gas exchange.
- Restrictive Deficits: Reduced lung volumes linked to fibrosis.
- Obstructive Patterns: Rare but observed in pre-existing airway diseases.		[34,35]
Radiological ChangesPersistent abnormalities on imaging studies.- Ground-glass opacities (GGOs): Common and linked to lingering inflammation.
- Pulmonary Fibrosis: Scarring, especially in severe cases.
- Bronchiectasis: Irreversible airway dilation.		[36,37,38]
PathophysiologyUnderlying mechanisms driving sequelae.- Persistent Inflammation: Chronic low-grade inflammation.
- Endothelial Dysfunction: Contributing to impaired gas exchange.
- Immune Dysregulation: Ongoing tissue damage.		[39,40]
Management StrategiesApproaches to mitigate and treat post-COVID-19 pulmonary complications.- Pulmonary Rehabilitation: Exercises and breathing techniques to restore function.
- Pharmacotherapy: Antifibrotic drugs (e.g., nintedanib, pirfenidone).
- Monitoring: Regular imaging and PFTs.		[41]
Clinical OutcomesOverall impact on recovery and quality of life.On recovery and quality of life:
- Reduced physical and functional capacity.
- Prolonged recovery time.
- Increased healthcare utilization for follow-ups and treatments.		[42]
Table 5. Comparative impact of pulmonary comorbidities on acute and chronic phases of COVID-19.
Table 5. Comparative impact of pulmonary comorbidities on acute and chronic phases of COVID-19.
Pulmonary ComorbidityAcute Phase ImpactChronic Phase Impact
COPD- Severity Increase: 1.9× higher mortality risk in hospitalized patients [43].
- Exacerbations: Triggered by inflammation and viral load, leading to worsened airflow limitation.		- Chronic Symptoms: Dyspnea, fatigue, and reduced exercise tolerance persist for months post-recovery.
- Functional Decline: Reduced DLCO and long-term pulmonary impairment [44].
Asthma- Variable Severity: Generally less severe impact compared to COPD, but severe asthma increases hospitalization risk.- Persistent Symptoms: Prolonged respiratory distress in severe cases; overall lower rates of fibrosis than COPD or ILDs.
ILDs- Exacerbations: Acute COVID-19 often triggers exacerbations leading to respiratory failure [36].
- Severe Outcomes: High ICU admission rates due to compromised lung function.		- Fibrosis Progression: Accelerated fibrosis in pre-existing ILD patients, worsening prognosis [37].
- Chronic Symptoms: Persistent dyspnea, fatigue, and reduced lung capacity.
General Observations- Increased Mortality: Across all comorbidities, higher ICU and mechanical ventilation rates.
- Immune Defenses: Baseline impairment leads to greater susceptibility to severe disease.		- Post-COVID-19 Sequelae: Persistent respiratory symptoms, fibrosis development, and reduced functional capacity, varying by baseline pathology severity [45].
Table 6. Disease burden in acute and chronic phases of COVID-19 in patients with pulmonary comorbidities.
Table 6. Disease burden in acute and chronic phases of COVID-19 in patients with pulmonary comorbidities.
AspectAcute PhaseChronic Phase
Inflammatory Burden- Cytokine storm disproportionately impacts pre-existing pulmonary conditions.
- Rapid clinical deterioration due to intense inflammation.		- Lingering inflammation and immune dysregulation.
- Prolonged symptoms and structural lung damage.
Oxygen Dependency- Acute hypoxemia caused by viral pneumonia and ARDS.
- High oxygen demand requiring ICU care.		- Persistent oxygen dependency in cases with pre-existing fibrosis or significant lung scarring.
Healthcare Utilization- Increased hospitalization and ICU admission.
- Need for mechanical ventilation in severe cases.		- Frequent follow-ups and long-term pulmonary rehabilitation.
- Advanced therapies to manage sequelae.
Table 7. Key strategies for managing each phase of clinical care for COVID-19 patients with pulmonary comorbidities.
Table 7. Key strategies for managing each phase of clinical care for COVID-19 patients with pulmonary comorbidities.
PhaseKey StrategiesDetails
Acute Phase ManagementEarly Identification and Risk StratificationIdentify high-risk patients (e.g., those with COPD, asthma, ILDs, advanced age, or smoking history). Monitor oxygen saturation and respiratory function closely.
Optimizing Pre-existing Condition ManagementEnsure adequate control of underlying pulmonary diseases by continuing prescribed therapies like inhaled corticosteroids and bronchodilators to reduce the risk of exacerbations.
Use of Antiviral and Immunomodulatory TherapiesAdminister antivirals (e.g., remdesivir, molnupiravir) and immunomodulatory drugs (e.g., dexamethasone, tocilizumab) to reduce viral replication and inflammation.
Oxygen Therapy and Mechanical VentilationProvide supplemental oxygen or advanced respiratory support (e.g., HFNC, NIV). In severe cases, invasive mechanical ventilation or ECMO may be necessary.
Anticoagulation ManagementUse thromboprophylaxis to mitigate the high risk of thrombosis in COVID-19 patients, especially those with limited mobility and pulmonary comorbidities.
Post-Acute and Chronic Phase ManagementComprehensive Post-COVID-19 EvaluationConduct regular follow-ups with pulmonary function tests (PFTs), chest imaging (e.g., CT scans), and assessments of exercise tolerance to detect and monitor post-COVID-19 sequelae like fibrosis and bronchiectasis.
Management of Long-Term SymptomsAddress persistent symptoms (e.g., dyspnea, fatigue, chronic cough) with targeted interventions. Use short-term corticosteroids for inflammation and antifibrotic therapies (e.g., nintedanib, pirfenidone) for fibrosis.
Pulmonary RehabilitationImplement rehabilitation programs with breathing exercises, graded physical activity, and psychological support to improve lung function and manage post-traumatic stress and anxiety.
Nutritional and Psychological SupportOptimize nutrition to aid recovery in debilitated patients. Provide mental health support for anxiety and depression, especially for those with prolonged illness.
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Mara, G.; Nini, G.; Cotoraci, C. Impact of Pulmonary Comorbidities on COVID-19: Acute and Long-Term Evaluations. J. Clin. Med. 2025, 14, 1446. https://doi.org/10.3390/jcm14051446

AMA Style

Mara G, Nini G, Cotoraci C. Impact of Pulmonary Comorbidities on COVID-19: Acute and Long-Term Evaluations. Journal of Clinical Medicine. 2025; 14(5):1446. https://doi.org/10.3390/jcm14051446

Chicago/Turabian Style

Mara, Gabriela, Gheorghe Nini, and Coralia Cotoraci. 2025. "Impact of Pulmonary Comorbidities on COVID-19: Acute and Long-Term Evaluations" Journal of Clinical Medicine 14, no. 5: 1446. https://doi.org/10.3390/jcm14051446

APA Style

Mara, G., Nini, G., & Cotoraci, C. (2025). Impact of Pulmonary Comorbidities on COVID-19: Acute and Long-Term Evaluations. Journal of Clinical Medicine, 14(5), 1446. https://doi.org/10.3390/jcm14051446

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