Viral DNA genomes in sera of farrowing sows with or without stillbirths

A study was conducted to investigate the serum virome of sows with and without stillbirths after farrowing. Sera from sows with at least one stillbirth or with normal litters were collected immediately after farrowing. Viral DNA was extracted from serum pools and submitted to high throughput sequencing. No differences in the proportion of virus-related reads were found in both groups (p > 0.05). A variety of viral DNA genomes were identified, mostly representative of three viral families: Anelloviridae, Circoviridae and Smacoviridae. Besides, a number of novel unclassified circular Rep-encoding single stranded DNA (CRESS DNA) viruses were also identified. These findings suggest that the presence of such viral genomes in sows’ sera bears no correlation with stillbirths’ occurrence; it seems likely that these constitute part of the normal serum microbiome of sows at farrowing

Viability of mesenchymal stem cells of adipose tissue from human liposuction

Introduction: Lipografting is an alternative with important applicability for breast reconstruction and/or corrections of asymmetries resulting from cancer treatment. This technique consists of autologous fat transfer, whose stroma contains stem cells derived from adipose tissue that can differentiate itself throughout the mesodermal lineage. For adipose tissue preparation, Coleman-based centrifugation of syringe-aspirated material at 3000 revolutions per minute (rpm) for 3 minutes. However, studies question whether lower centrifugation speeds could be less harmful to cell viability. Methods: An experimental study was conducted to evaluate the adipose cells of six patients; from 60mL of liposuction of each one. The sample collected was fractionated into four tubes and submitted to different protocols, decanting and centrifugation at speeds 500, 1000, and 3000rpm for 3 minutes. Afterward, the samples were processed with collagenase IA for 30 min, submitted to cell culture for 24 hours, and a cell viability analysis. The results were tabulated and analyzed by the ANOVA test using the Graphpad Prism 6.0® and SAS®. Results: Cell viability was higher in the cell sample centrifuged at 3000rpm and lower in the decanted sample. Giemsa staining indicated maintenance of cell morphology on the samples. Conclusion: Centrifuged cells at a speed of 3000rpm showed higher cell viability. Centrifugation was effective in compacting tissue and eliminating unwanted waste (blood and residual oil)

Proceedings of the 3rd Biennial Conference of the Society for Implementation Research Collaboration (SIRC) 2015: advancing efficient methodologies through community partnerships and team science

It is well documented that the majority of adults, children and families in need of evidence-based behavioral health interventionsi do not receive them [1, 2] and that few robust empirically supported methods for implementing evidence-based practices (EBPs) exist. The Society for Implementation Research Collaboration (SIRC) represents a burgeoning effort to advance the innovation and rigor of implementation research and is uniquely focused on bringing together researchers and stakeholders committed to evaluating the implementation of complex evidence-based behavioral health interventions. Through its diverse activities and membership, SIRC aims to foster the promise of implementation research to better serve the behavioral health needs of the population by identifying rigorous, relevant, and efficient strategies that successfully transfer scientific evidence to clinical knowledge for use in real world settings [3]. SIRC began as a National Institute of Mental Health (NIMH)-funded conference series in 2010 (previously titled the “Seattle Implementation Research Conference”; $150,000 USD for 3 conferences in 2011, 2013, and 2015) with the recognition that there were multiple researchers and stakeholdersi working in parallel on innovative implementation science projects in behavioral health, but that formal channels for communicating and collaborating with one another were relatively unavailable. There was a significant need for a forum within which implementation researchers and stakeholders could learn from one another, refine approaches to science and practice, and develop an implementation research agenda using common measures, methods, and research principles to improve both the frequency and quality with which behavioral health treatment implementation is evaluated. SIRC’s membership growth is a testament to this identified need with more than 1000 members from 2011 to the present.ii SIRC’s primary objectives are to: (1) foster communication and collaboration across diverse groups, including implementation researchers, intermediariesi, as well as community stakeholders (SIRC uses the term “EBP champions” for these groups) – and to do so across multiple career levels (e.g., students, early career faculty, established investigators); and (2) enhance and disseminate rigorous measures and methodologies for implementing EBPs and evaluating EBP implementation efforts. These objectives are well aligned with Glasgow and colleagues’ [4] five core tenets deemed critical for advancing implementation science: collaboration, efficiency and speed, rigor and relevance, improved capacity, and cumulative knowledge. SIRC advances these objectives and tenets through in-person conferences, which bring together multidisciplinary implementation researchers and those implementing evidence-based behavioral health interventions in the community to share their work and create professional connections and collaborations

Extracorporeal Membrane Oxygenation for Severe Acute Respiratory Distress Syndrome associated with COVID-19: An Emulated Target Trial Analysis.

RATIONALE: Whether COVID patients may benefit from extracorporeal membrane oxygenation (ECMO) compared with conventional invasive mechanical ventilation (IMV) remains unknown. OBJECTIVES: To estimate the effect of ECMO on 90-Day mortality vs IMV only Methods: Among 4,244 critically ill adult patients with COVID-19 included in a multicenter cohort study, we emulated a target trial comparing the treatment strategies of initiating ECMO vs. no ECMO within 7 days of IMV in patients with severe acute respiratory distress syndrome (PaO2/FiO2 <80 or PaCO2 ≥60 mmHg). We controlled for confounding using a multivariable Cox model based on predefined variables. MAIN RESULTS: 1,235 patients met the full eligibility criteria for the emulated trial, among whom 164 patients initiated ECMO. The ECMO strategy had a higher survival probability at Day-7 from the onset of eligibility criteria (87% vs 83%, risk difference: 4%, 95% CI 0;9%) which decreased during follow-up (survival at Day-90: 63% vs 65%, risk difference: -2%, 95% CI -10;5%). However, ECMO was associated with higher survival when performed in high-volume ECMO centers or in regions where a specific ECMO network organization was set up to handle high demand, and when initiated within the first 4 days of MV and in profoundly hypoxemic patients. CONCLUSIONS: In an emulated trial based on a nationwide COVID-19 cohort, we found differential survival over time of an ECMO compared with a no-ECMO strategy. However, ECMO was consistently associated with better outcomes when performed in high-volume centers and in regions with ECMO capacities specifically organized to handle high demand. This article is open access and distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivatives License 4.0 (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Genetic characterization of influenza viruses recovered from pigs in Rio Grande do Sul

O vírus influenza A (IAV) é um agente zoonótico de grande relevância tanto para saúde humana como animal. A influenza suína teve seu primeiro reconhecimento clínico em 1918, em suínos do Meio Oeste dos EUA, coincidindo com a pandemia de influenza em humanos. Desde então, o IAV permanece como um importante patógeno para a indústria suinícola em todo o mundo. A grande variabilidade genética destes vírus é causada por dois principais mecanismos genéticos: mutações pontuais e recombinações genéticas. A influenza é endêmica em muitos países e a emergências de recombinantes tem desafiado o controle e o diagnóstico desta enfermidade. No Brasil, a infecção pelo IAV em suínos (swIAV) não está bem caracterizada; poucos relatos evidenciam a prevalência deste agente antes do ano de 2009, especialmente no Estado do Rio Grande do Sul, que alberga um dos maiores rebanhos de suínos do Brasil. Em vista disso, este trabalho teve como objetivo investigar ocorrência de swIAV em alguns rebanhos suínos comerciais do Estado do Rio Grande do Sul, Brasil, no período de 2013-2014, e determinar os tipos e subtipos de vírus circulantes naquelas propriedades. O primeiro capítulo deste estudo reporta os aspectos clínicos, patológicos e virológicos da ocorrência de influenza suína e co-infecções identificadas em seis propriedades suinícolas selecionadas na região do Vale do Taquari. Neste estudo foram analisados suabes nasais coletados de 66 animais e 6 amostras de tecido pulmonar de suínos com sinais de infecção respiratória. A detecção viral foi feita através de uma PCR de triagem e confirmada através do isolamento viral em células MDCK. A identificação dos subtipos virais foi feita através de uma PCR em Tempo Real (rRT-PCR) para o subtipo A(H1N1)pdm09 ou através de uma PCR multiplex (RT-PCR) para outros subtipos de swIAV. A detecção de agentes bacterianos foi realizada apenas nas amostras de tecido pulmonar, através da pesquisa de genomas bacterianos por PCR. O subtipo A(H1N1)pdm09 foi identificado em 4/6 granjas e o subtipo H1N2 em 2/6 granjas. Além disso, agentes envolvidos no complexo respiratório dos suínos foram identificados em todas as granjas; Pasteurella multocida foi identificada em 5/6 granjas e Mycoplasma hyopneumoniae em 3/6 granjas. Actinobacillus pleuropneumoniae (1/6), Haemophilus parasuis (1/6) e PCV2 (1/6) também foram detectados. O segundo capítulo deste estudo teve como objetivo o sequenciamento do genoma completo de um novo recombinante H1N2 de origem humana, detectado em suínos. O genoma completo foi gerado através de uma RT-PCR. Os produtos foram purificados e submetidos ao sequenciamento utilizando a plataforma MiSeq (illumina). A análise filogenética revelou que as sequencias dos genes HA e NA correspondem a genes de IAV de origem humana, enquanto que as sequencias dos genes que codificam as proteínas internas do vírus (PB1, PB2, PA, NP, M e NS) correspondem a genes de amostras do vírus A(H1N1)pdm09. O terceiro capítulo reporta o sequenciamento completo dos genomas de 8 amostras de vírus influenza identificados nas populações de suínos amostradas. Foram identificados dois subtipos virais de origem humana (H1N2 e H3N2), além do vírus A(H1N1)pdm09. Os subtipos de origem humana possuem os genes HA e NA similares a vírus sazonais de humanos e os genes internos são estreitamente relacionados com o vírus A(H1N1)pdm09.Influenza A virus (IAV) is a zoonotic agent of great relevance to human and animal health. Swine influenza was first recognized clinically in pigs in the Midwestern U.S., in 1918, coinciding with the human influenza pandemic. Since that time swine influenza has remained of importance to the swine industry throughout the world. The great genetic variability of influenza viruses is caused by two main genetic mechanisms: point mutations (antigenic drift) and gene reassortment (antigenic shift). Influenza is endemic in pigs in many countries and the emergence of new viruses has been challenging its control and diagnostics. Influenza virus (swIAV) infection in Brazilian swine population is not well characterized, and little evidence existed of swIAV circulation before 2009, especially in Rio Grande do Sul State, which hosts one of the largest swine populations in Brazil. Thus, this study aimed to investigate the occurrence of IAV in commercial swine herds in the state of Rio Grande do Sul, Brazil, between 2013-2014 and to know the types and subtypes of swine influenza viruses that are circulating in these herd. The first chapter of this study reports the clinical, pathological and virological aspects of the occurrence of swine influenza and related co-infections in six pig properties of the Taquari Valley region. In this study were analyzed nasal swabs collected from 66 animals and six lung tissue samples from pigs showing clinical signs of respiratory disease. IAV detection was performed by PCR screening and confirmed by virus isolation in MDCK cells and hemagglutination (HA). Influenza A subtyping was performed by real-time reverse transcription PCR (rRT-PCR) to detect the 2009 H1N1pandemic A(H1N1)pdm09; other swIAV subtypes were identifieded by multiplex RT-PCR. Bacterial infections were identified through detection of bacterial genomes by PCR, only in lung samples. Influenza A was detected by screening PCR in 46/66 swab samples and from 5/6 lungs. Virus was recovered from pigs of the six herds. Subtype A(H1N1)pdm09 was detected in 4/6 herds and H1N2 in the other 2/6 herds. In lung tissues, further agents involved in porcine respiratory disease complex were detected in all cases; Pasteurella multocida was identified in 5/6 samples and Mycoplasma hyopneumoniae in 3/6. Actinobacillus pleuropneumoniae (1/6), Haemophilus parasuis (1/6) and PCV2 (1/6) were also detected. The aim of the second chapter was to sequence the whole-genome of a novel human-like H1N2 swine influenza virus. Wholegenome sequences were generated by RT-PCR. Amplicons were purified followed by sequencing in the MiSeq sequencing platform (Illumina). Phylogenetic analyses revealed that the HA and NA genes clustered with influenza viruses of human lineage, whereas the internal genes (PB1, PB2, PA, NP, M and NS) clustered with the A(H1N1)pdm09. The third chapter reports the genetic sequencing of the full genomes of eight swine influenza viruses circulating in the sampled pig population. Two swine human-like subtypes (H1N2 and H3N2) and the A(H1N1)pdm09 virus were identified. The human-like subtypes have the HA and NA genes similar to the human seasonal strains and the internal genes are closely related to the virus A(H1N1)pdm09

Genetic characterization of influenza viruses recovered from pigs in Rio Grande do Sul

O vírus influenza A (IAV) é um agente zoonótico de grande relevância tanto para saúde humana como animal. A influenza suína teve seu primeiro reconhecimento clínico em 1918, em suínos do Meio Oeste dos EUA, coincidindo com a pandemia de influenza em humanos. Desde então, o IAV permanece como um importante patógeno para a indústria suinícola em todo o mundo. A grande variabilidade genética destes vírus é causada por dois principais mecanismos genéticos: mutações pontuais e recombinações genéticas. A influenza é endêmica em muitos países e a emergências de recombinantes tem desafiado o controle e o diagnóstico desta enfermidade. No Brasil, a infecção pelo IAV em suínos (swIAV) não está bem caracterizada; poucos relatos evidenciam a prevalência deste agente antes do ano de 2009, especialmente no Estado do Rio Grande do Sul, que alberga um dos maiores rebanhos de suínos do Brasil. Em vista disso, este trabalho teve como objetivo investigar ocorrência de swIAV em alguns rebanhos suínos comerciais do Estado do Rio Grande do Sul, Brasil, no período de 2013-2014, e determinar os tipos e subtipos de vírus circulantes naquelas propriedades. O primeiro capítulo deste estudo reporta os aspectos clínicos, patológicos e virológicos da ocorrência de influenza suína e co-infecções identificadas em seis propriedades suinícolas selecionadas na região do Vale do Taquari. Neste estudo foram analisados suabes nasais coletados de 66 animais e 6 amostras de tecido pulmonar de suínos com sinais de infecção respiratória. A detecção viral foi feita através de uma PCR de triagem e confirmada através do isolamento viral em células MDCK. A identificação dos subtipos virais foi feita através de uma PCR em Tempo Real (rRT-PCR) para o subtipo A(H1N1)pdm09 ou através de uma PCR multiplex (RT-PCR) para outros subtipos de swIAV. A detecção de agentes bacterianos foi realizada apenas nas amostras de tecido pulmonar, através da pesquisa de genomas bacterianos por PCR. O subtipo A(H1N1)pdm09 foi identificado em 4/6 granjas e o subtipo H1N2 em 2/6 granjas. Além disso, agentes envolvidos no complexo respiratório dos suínos foram identificados em todas as granjas; Pasteurella multocida foi identificada em 5/6 granjas e Mycoplasma hyopneumoniae em 3/6 granjas. Actinobacillus pleuropneumoniae (1/6), Haemophilus parasuis (1/6) e PCV2 (1/6) também foram detectados. O segundo capítulo deste estudo teve como objetivo o sequenciamento do genoma completo de um novo recombinante H1N2 de origem humana, detectado em suínos. O genoma completo foi gerado através de uma RT-PCR. Os produtos foram purificados e submetidos ao sequenciamento utilizando a plataforma MiSeq (illumina). A análise filogenética revelou que as sequencias dos genes HA e NA correspondem a genes de IAV de origem humana, enquanto que as sequencias dos genes que codificam as proteínas internas do vírus (PB1, PB2, PA, NP, M e NS) correspondem a genes de amostras do vírus A(H1N1)pdm09. O terceiro capítulo reporta o sequenciamento completo dos genomas de 8 amostras de vírus influenza identificados nas populações de suínos amostradas. Foram identificados dois subtipos virais de origem humana (H1N2 e H3N2), além do vírus A(H1N1)pdm09. Os subtipos de origem humana possuem os genes HA e NA similares a vírus sazonais de humanos e os genes internos são estreitamente relacionados com o vírus A(H1N1)pdm09.Influenza A virus (IAV) is a zoonotic agent of great relevance to human and animal health. Swine influenza was first recognized clinically in pigs in the Midwestern U.S., in 1918, coinciding with the human influenza pandemic. Since that time swine influenza has remained of importance to the swine industry throughout the world. The great genetic variability of influenza viruses is caused by two main genetic mechanisms: point mutations (antigenic drift) and gene reassortment (antigenic shift). Influenza is endemic in pigs in many countries and the emergence of new viruses has been challenging its control and diagnostics. Influenza virus (swIAV) infection in Brazilian swine population is not well characterized, and little evidence existed of swIAV circulation before 2009, especially in Rio Grande do Sul State, which hosts one of the largest swine populations in Brazil. Thus, this study aimed to investigate the occurrence of IAV in commercial swine herds in the state of Rio Grande do Sul, Brazil, between 2013-2014 and to know the types and subtypes of swine influenza viruses that are circulating in these herd. The first chapter of this study reports the clinical, pathological and virological aspects of the occurrence of swine influenza and related co-infections in six pig properties of the Taquari Valley region. In this study were analyzed nasal swabs collected from 66 animals and six lung tissue samples from pigs showing clinical signs of respiratory disease. IAV detection was performed by PCR screening and confirmed by virus isolation in MDCK cells and hemagglutination (HA). Influenza A subtyping was performed by real-time reverse transcription PCR (rRT-PCR) to detect the 2009 H1N1pandemic A(H1N1)pdm09; other swIAV subtypes were identifieded by multiplex RT-PCR. Bacterial infections were identified through detection of bacterial genomes by PCR, only in lung samples. Influenza A was detected by screening PCR in 46/66 swab samples and from 5/6 lungs. Virus was recovered from pigs of the six herds. Subtype A(H1N1)pdm09 was detected in 4/6 herds and H1N2 in the other 2/6 herds. In lung tissues, further agents involved in porcine respiratory disease complex were detected in all cases; Pasteurella multocida was identified in 5/6 samples and Mycoplasma hyopneumoniae in 3/6. Actinobacillus pleuropneumoniae (1/6), Haemophilus parasuis (1/6) and PCV2 (1/6) were also detected. The aim of the second chapter was to sequence the whole-genome of a novel human-like H1N2 swine influenza virus. Wholegenome sequences were generated by RT-PCR. Amplicons were purified followed by sequencing in the MiSeq sequencing platform (Illumina). Phylogenetic analyses revealed that the HA and NA genes clustered with influenza viruses of human lineage, whereas the internal genes (PB1, PB2, PA, NP, M and NS) clustered with the A(H1N1)pdm09. The third chapter reports the genetic sequencing of the full genomes of eight swine influenza viruses circulating in the sampled pig population. Two swine human-like subtypes (H1N2 and H3N2) and the A(H1N1)pdm09 virus were identified. The human-like subtypes have the HA and NA genes similar to the human seasonal strains and the internal genes are closely related to the virus A(H1N1)pdm09