Your search keyword '"Amorim, Maria"' showing total 5 results

1. Pre-existing IgG antibodies to HCoVs NL63 and OC43 Spike increased during the pandemic and after COVID-19 vaccination

Author

Hasan, Zahra, Masood, Kiran Iqbal, Veldhoen, Marc, Qaiser, Shama, Alenquer, Marta, Akhtar, Mishgan, Balouch, Sadaf, Iqbal, Junaid, Wassan, Yaqub, Hussain, Shahneel, Feroz, Khalid, Muhammad, Sajid, Habib, Atif, Kanji, Akbar, Khan, Erum, Mian, Afsar Ali, Hussain, Rabia, Amorim, Maria Joao, and Bhutta, Zulfiqar A.

Published

2025

2. Enhanced filtration membranes with graphene oxide and tannic acid for textile industry wastewater dye removal.

Author

Paixão, Rebecca Manesco, da Silva, Luiz Henrique Biscaia Ribeiro, Vieira, Marcelo Fernandes, de Amorim, Maria Teresa Pessoa, Bergamasco, Rosângela, and Vieira, Angélica Marquetotti Salcedo

Subjects

COLOR removal (Sewage purification), MEMBRANE separation, CONTACT angle, TEXTILE cleaning & dyeing industry, GRAPHENE oxide, POLYETHERSULFONE, TANNINS

Abstract

A novel modification technique employing a layer-by-layer (LbL) self-assembly method, integrated with a pressure-assisted filtration system, was developed for enhancing a commercial polyethersulfone (PES) microfiltration (MF) membrane. This modification involved the incorporation of tannic acid (TA) in conjunction with graphene oxide (GO) nanosheets. The effectiveness of the LbL method was confirmed through comprehensive characterization analyses, including ATR-FTIR, SEM, water contact angle (WCA), and mean pore size measurements, comparing the modified membrane with the original commercial one. Sixteen variations of PES MF membranes were superficially modified using a three-factorial design, with the deposited amount of TA and GO as key factors. The influence of these factors on the morphology and performance of the membranes was systematically investigated, focusing on parameters such as pure water permeability (PWP), blue corazol (BC) dye removal efficiency, and flux recovery rate (FRR). The membranes produced with the maximum amount of GO (0.1 mg, 0.55 wt%) and TA as the inner and outer layers demonstrated remarkable FRR and significant BC removal, exceeding 80%. Notably, there was no significant difference observed when using either 0.2 (1.11 wt%) or 0.4 mg (2.22 wt%) in the first layer, as indicated by the Tukey mean test. Furthermore, the modified membrane designated as MF/TA0.4GO0.1TA0.4 was evaluated in the filtration of a simulated dye bath wastewater, exhibiting a BC removal efficiency of 49.20% and a salt removal efficiency of 27.74%. In conclusion, the novel PES MF membrane modification proposed in this study effectively enhances the key properties of pressure-driven separation processes. [ABSTRACT FROM AUTHOR]

Published

2025

3. Deciphering respiratory viral infections by harnessing organ-on-chip technology to explore the gut-lung axis.

Author

Koceva H, Amiratashani M, Akbarimoghaddam P, Hoffmann B, Zhurgenbayeva G, Gresnigt MS, Marcelino VR, Eggeling C, Figge MT, Amorim MJ, and Mosig AS

Subjects

Humans, Lab-On-A-Chip Devices, SARS-CoV-2 physiology, COVID-19 virology, Animals, Microbiota, Gastrointestinal Microbiome, Lung virology, Lung microbiology, Respiratory Tract Infections virology, Respiratory Tract Infections microbiology

Abstract

The lung microbiome has recently gained attention for potentially affecting respiratory viral infections, including influenza A virus, respiratory syncytial virus (RSV) and SARS-CoV-2. We will discuss the complexities of the lung microenvironment in the context of viral infections and the use of organ-on-chip (OoC) models in replicating the respiratory tract milieu to aid in understanding the role of temporary microbial colonization. Leveraging the innovative capabilities of OoC, particularly through integrating gut and lung models, opens new avenues to understand the mechanisms linking inter-organ crosstalk and respiratory infections. We will discuss technical aspects of OoC lung models, ranging from the selection of cell substrates for extracellular matrix mimicry, mechanical strain, breathing mechanisms and air-liquid interface to the integration of immune cells and use of microscopy tools for algorithm-based image analysis and systems biology to study viral infection in vitro . OoC offers exciting new options to study viral infections across host species and to investigate human cellular physiology at a personalized level. This review bridges the gap between complex biological phenomena and the technical prowess of OoC models, providing a comprehensive roadmap for researchers in the field.

Published

2025

4. Fluorescence Loss After Photoactivation (FLAPh): A Pulse-Chase Cellular Assay for Understanding Kinetics and Dynamics of Viral Inclusions.

Author

Etibor TA, Paixão T, and Amorim MJ

Subjects

Humans, Kinetics, Animals, Fluorescence Recovery After Photobleaching methods, Dogs, Influenza A virus metabolism, Influenza A virus physiology, Inclusion Bodies, Viral metabolism, Virus Replication

Abstract

Influenza A virus (IAV) relies on host cellular machinery for replication. Upon infection, the eight genomic segments, independently packed as viral ribonucleoproteins (vRNPs), are released into the cytosol before nuclear import for viral replication. After nucleocytoplasmic transport, the resulting progeny vRNPs reach the cytosol, accumulating in highly mobile and dynamic viral inclusions that display liquid properties. Being sites postulated to support IAV genome assembly, the biophysical properties of IAV inclusions may be critical for function. In agreement, imposing liquid-to-solid transitions was demonstrated to impact viral replication negatively. Therefore, screening for host factors or compounds able to alter the material properties may provide the molecular basis for how influenza genomic complex forms as well as identify novel antivirals. Conventional techniques employed to investigate biomolecular condensates' material properties include fluorescence correlation spectroscopy, raster image correlation spectroscopy, single molecule or microrheology particle tracking, and Fluorescence Recovery After Photobleaching (FRAP). These approaches allow measuring molecular dynamics in systems that do not move very much. However, the analysis of highly mobile intracellular condensates, such as IAV inclusions, poses significant challenges as these structures not only constantly move within the cell but also exchange material, fusing, and dividing, rendering the quantitation of internal rearrangements and diffusion coefficients of molecules within condensates inaccurate. As an alternative, we opted for measuring the kinetics and the exchange of material between IAV inclusions using the Fluorescence Loss After Photoactivation (FLAPh) technique. It involves pulse photoactivation of individual or pools of viral inclusions in the cell, and chasing over time in photoactivated and non-photoactivated regions. This approach is suitable for quantifying the movement and spatial distribution of components within inclusions over time, enabling the determination of both the distance and speed from a specific cellular location. As a result, this method allows the quantification of decay profiles, half-lives, decay constant rate, and mobile and immobile fractions in viral inclusions. It, therefore, enables high throughput screenings for compounds or host factors that affect this dynamism and indirectly allows assessing the material properties of IAV inclusions., (© 2025. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2025

5. Understanding Influenza.

Author

Hutchinson EC, Amorim MJ, and Yamauchi Y

Subjects

Humans, Animals, Influenza A virus physiology, Virus Replication, Orthomyxoviridae physiology, Orthomyxoviridae pathogenicity, Influenza, Human virology, Influenza, Human epidemiology

Abstract

Influenza, a serious illness of humans and domesticated animals, has been studied intensively for many years. It therefore provides an example of how much we can learn from detailed studies of an infectious disease, and of how even the most intensive scientific research leaves further questions to answer. This introduction is written for researchers who have become interested in one of these unanswered questions, but who may not have previously worked on influenza. To investigate these questions, researchers must not only have a firm grasp of relevant methods and protocols; they must also be familiar with the basic details of our current understanding of influenza. This chapter briefly covers the burden of disease that has driven influenza research, summarizes how our thinking about influenza has evolved over time, and sets out key features of influenza viruses by discussing how we classify them and what we currently understand of their replication. It does not aim to be comprehensive, as any researcher will read deeply into the specific areas that have grasped their interest. Instead, it aims to provide a general summary of how we came to think about influenza in the way we do now, in the hope that the reader's own research will help us to understand it better., (© 2025. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2025