Tai Chi on Exercise Capacity and Quality of Life in Chronic Heart Failure #pencis #researchawards

Introduction

Chronic heart failure (CHF) remains a major global health burden, characterized by reduced exercise tolerance, impaired quality of life (QoL), and high healthcare utilization. Alongside conventional pharmacological and device-based therapies, non-pharmacological interventions such as cardiac rehabilitation play a crucial role in CHF management. Tai Chi (TC), a traditional mind–body exercise combining slow movements, controlled breathing, and mental focus, has gained attention as a potentially safe and accessible rehabilitation strategy for CHF patients. However, its clinical efficacy remains debated, necessitating evidence-based evaluation.

Rationale for Tai Chi in Cardiac Rehabilitation

Tai Chi is considered a low-to-moderate intensity aerobic exercise, making it suitable for older adults and patients with limited physical capacity, such as those with CHF. Its emphasis on balance, relaxation, and gentle movement may reduce sympathetic activation and improve psychosocial well-being. From a research perspective, TC offers a holistic intervention that may complement standard cardiac rehabilitation, particularly for patients unable or unwilling to engage in conventional exercise programs.

Methodological Approach of the Meta-Analysis

The meta-analysis synthesized evidence from randomized controlled trials (RCTs) evaluating TC in CHF patients with reduced left ventricular ejection fraction (≤45%). Comprehensive searches of PubMed and EMBASE databases ensured systematic identification of eligible studies. By calculating weighted mean differences (WMDs) and assessing heterogeneity using the I² statistic, the analysis aimed to quantitatively determine the impact of TC on functional capacity, biomarkers, hemodynamic parameters, and QoL outcomes.

Effects of Tai Chi on Quality of Life

One of the most consistent findings of the meta-analysis was the significant improvement in QoL among CHF patients practicing Tai Chi. The observed reduction in QoL scores suggests meaningful psychosocial and functional benefits, potentially mediated through reduced stress, enhanced self-efficacy, and improved emotional well-being. These findings highlight QoL as a sensitive outcome measure for mind–body interventions and underscore TC’s value beyond purely physiological endpoints.

Impact on Exercise Capacity and Clinical Outcomes

Despite favorable effects on QoL, Tai Chi did not demonstrate statistically significant improvements in objective clinical parameters such as N-terminal pro-brain natriuretic peptide levels, blood pressure, peak oxygen uptake, or six-minute walking distance. While trends toward improved exercise capacity were observed, the lack of significance may reflect limited sample sizes, short intervention durations, or variability in TC protocols across studies.

Research Gaps and Future Directions

The current evidence base is constrained by small-scale RCTs and methodological heterogeneity, limiting definitive conclusions regarding Tai Chi’s role in CHF management. Future research should prioritize larger, well-designed trials with standardized TC interventions, longer follow-up periods, and integration of both clinical and patient-reported outcomes. Such studies are essential to clarify whether Tai Chi can influence disease progression, functional capacity, and long-term prognosis in CHF patients.

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#ChronicHeartFailure #TaiChiResearch #CardiacRehabilitation #MetaAnalysis #QualityOfLife #ExerciseTherapy #MindBodyMedicine #HeartFailureManagement #ClinicalResearch #RCTs #NonPharmacologicalTherapy #EvidenceBasedMedicine #CardiovascularHealth #RehabilitationScience #PatientCenteredCare #ExerciseCapacity #HeartFailureStudies #IntegrativeMedicine #HealthOutcomes #FutureResearch

Decoding the Complexity of IgA Immune Responses Respiratory Syncytial Virus #pencis #researchawards

Introduction

Respiratory syncytial virus (RSV) remains one of the most significant viral threats to infant respiratory health worldwide, causing severe lower respiratory tract infections that can lead to hospitalization and long-term pulmonary complications. Despite decades of research, effective and durable protective strategies for early life remain elusive, largely due to fundamental age-dependent differences in immune function. Infants exhibit distinct mucosal immune responses compared to adults, particularly at the level of antibody production and immune regulation. Understanding how these developmental differences influence susceptibility to RSV is critical for advancing vaccine development and improving clinical outcomes in this vulnerable population.

Age-Dependent Mucosal Immunity in RSV Infection

Mucosal immunity in the respiratory tract undergoes profound developmental changes from infancy to adulthood, shaping host defense against RSV. In infants, immune responses are biased toward tolerance and immune regulation, a feature thought to protect against excessive inflammation during early microbial exposure. However, this bias results in diminished antiviral effector responses, including reduced antibody production at mucosal surfaces. These age-specific immune characteristics contribute to higher viral replication, prolonged infection, and increased disease severity in infants compared to adults during RSV infection.

Role of IgA in Controlling RSV at Respiratory Surfaces

Immunoglobulin A (IgA) is the predominant antibody isotype at respiratory mucosal surfaces and serves as a first line of defense against RSV by neutralizing the virus and limiting epithelial infection. In adults, robust RSV-specific IgA responses correlate with reduced viral load and milder disease. In contrast, infants exhibit markedly reduced IgA production following RSV exposure. This deficiency compromises mucosal barrier protection and facilitates viral persistence, highlighting IgA as a critical but underdeveloped component of early-life immunity against RSV.

Impaired Class Switch Recombination in Infant B Cells

The failure of infants to generate strong IgA responses during RSV infection is closely linked to impaired class switch recombination (CSR) in B cells. Neonatal B cells display intrinsic limitations in undergoing CSR due to reduced expression of key activation-induced cytidine deaminase (AID) and altered signaling through cytokine and costimulatory pathways. These molecular constraints limit the diversification of antibody isotypes, skewing responses toward less effective humoral immunity and reinforcing susceptibility to severe RSV disease in early life.

Regulatory B Cells as Modulators of Antiviral Immunity

Regulatory B cells (Bregs), particularly neonatal Bregs (nBregs), have emerged as critical modulators of immune responses during infancy. These cells exert immunosuppressive effects through cytokine production, such as interleukin-10, dampening antiviral T-cell responses and inhibiting effective B-cell activation. During RSV infection, nBregs can suppress class switch recombination and IgA production, thereby limiting protective mucosal immunity. While this regulatory function may prevent immunopathology, it paradoxically contributes to increased viral burden and disease severity in infants.

Implications for Infant-Specific RSV Vaccine Design

Elucidating the mechanisms underlying impaired IgA responses and Breg-mediated immune suppression has profound implications for RSV vaccine development. Traditional vaccine strategies designed for adults may fail in infants due to their unique immune regulatory environment. Targeted approaches that enhance mucosal IgA production, modulate Breg activity, or promote age-appropriate B-cell maturation may offer more effective protection. A deeper understanding of infant-specific immune pathways is essential for the rational design of next-generation RSV vaccines and immunomodulatory interventions tailored to early life.

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#RSVResearch, #InfantImmunity, #MucosalImmunity, #IgAResponse, #RespiratoryViruses, #NeonatalImmunity, #BCellBiology, #RegulatoryBCells, #RSVVaccines, #PediatricInfections, #AntiviralImmunity, #ImmuneDevelopment, #EarlyLifeImmunity, #ClassSwitchRecombination, #RespiratoryHealth, #ViralPathogenesis, #Immunoregulation, #VaccineDesign, #TranslationalImmunology, #PediatricResearch

Reveals Defense Pathways in Chinese Cabbage Against Black Spot Disease 🌱🧬 #pencis #researchawards

Introduction

Black spot disease, caused by Alternaria brassicicola, represents a major biotic constraint to Chinese cabbage production, leading to significant yield and quality losses. Understanding the molecular and biochemical defence strategies employed by resistant germplasm is essential for developing durable disease management approaches. Recent advances in multi-omics technologies have enabled integrated analyses of transcriptomic and metabolomic responses during early pathogen infection, offering new insights into host–pathogen interactions. In this context, the Chinese cabbage line 904B provides an excellent model to dissect early defence signalling and resistance-associated pathways against black spot disease.

Hormonal Reprogramming During Early Infection

Upon infection with A. brassicicola, Chinese cabbage line 904B exhibits a pronounced shift in phytohormone signalling. Growth-related hormones such as cytokinin and auxin are significantly suppressed, reflecting a strategic reallocation of resources away from development toward defence. In contrast, defence-associated hormones, particularly ethylene and jasmonic acid (JA), are strongly activated. This hormonal reprogramming highlights the central role of JA–ethylene crosstalk in mediating resistance to necrotrophic pathogens and underscores the importance of hormone balance in early immune responses.

Transcriptomic Insights Into Defence Activation

Transcriptomic profiling at 24 hours post-inoculation reveals extensive gene expression reprogramming in 904B. Genes involved in signal transduction, reactive oxygen species (ROS) production, and stress responses are markedly upregulated, while those associated with cell growth and differentiation are downregulated. Notably, defence-related kinases and transcriptional regulators show rapid induction, suggesting a tightly controlled signalling cascade that enables rapid perception of pathogen invasion and activation of downstream immune responses.

Metabolomic Remodeling and Secondary Metabolites

Metabolomic analysis demonstrates significant alterations in secondary metabolite accumulation following pathogen challenge. Among these, the sterol compound 4,4-dimethyl-5α-cholest-7-en-3β-ol is markedly upregulated in infected tissues, implicating sterol metabolism in plant defence. Differentially accumulated metabolites are primarily enriched in indole alkaloid metabolism and glycerolipid metabolism pathways, indicating their involvement in strengthening cellular barriers, modulating membrane integrity, and enhancing antimicrobial activity during black spot disease resistance.

Functional Role of BraPBL in Disease Resistance

BraPBL, a receptor-like cytoplasmic kinase (RLCK) family member, exhibits progressively increased expression with prolonged A. brassicicola infection. Functional analyses demonstrate that overexpression of BraPBL significantly enhances resistance to black spot disease, whereas gene silencing compromises host defence. Subcellular localization studies confirm that BraPBL resides at the plasma membrane, consistent with its proposed role in early pathogen perception and signal initiation.

BraPBL-Mediated Signalling and Defence Pathways

Overexpression of BraPBL leads to the activation of key defence-associated genes, including the ROS-generating enzyme RBOH and the mitogen-activated protein kinase kinase kinase MEKK1. This activation promotes ROS accumulation and signal amplification, while simultaneously stimulating the JA signalling pathway. Collectively, these findings position BraPBL as a crucial positive regulator of black spot disease resistance, linking membrane-associated signalling, hormone-mediated defence, and metabolic reprogramming in Chinese cabbage.

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#BlackSpotDisease, #ChineseCabbage, #AlternariaBrassicicola, #PlantPathology, #PlantImmunity, #Transcriptomics, #Metabolomics, #Phytohormones, #JasmonicAcid, #EthyleneSignaling, #SecondaryMetabolites, #SterolMetabolism, #BraPBL, #RLCK, #ROS, #MAPKSignaling, #DiseaseResistance, #HostPathogenInteraction, #PlantDefenseMechanisms, #CropProtection

Liver Crossroads🧬| Orchestrating Lipoprotein Dynamics & Lipid Homeostasis #pencis #researchawards

Introduction

The liver is a central metabolic organ responsible for maintaining systemic lipid homeostasis through tightly regulated processes such as fatty acid uptake, oxidation, and the assembly and secretion of very low-density lipoproteins (VLDLs). These pathways allow the liver to detoxify excess circulating free fatty acids and redistribute lipids to peripheral tissues for energy utilization. Disruption of these mechanisms contributes to hepatic lipid accumulation and the development of metabolic dysfunction-associated steatotic liver disease (MASLD), previously termed non-alcoholic fatty liver disease (NAFLD). Given the close association between hepatic lipid dysregulation, cardiovascular disease, and metabolic disorders, understanding liver lipid metabolism remains a major focus of biomedical research.

Hepatic Fatty Acid Uptake and Intracellular Trafficking

Hepatic fatty acid uptake occurs through both passive diffusion and transporter-mediated mechanisms involving proteins such as CD36 and fatty acid transport proteins (FATPs). Once inside hepatocytes, fatty acids are esterified, oxidized, or incorporated into lipoproteins. Intracellular trafficking of fatty acids toward mitochondria, peroxisomes, or the endoplasmic reticulum is tightly regulated to prevent lipotoxicity. Dysregulation at this stage can shift lipid flux toward storage rather than oxidation, promoting hepatic steatosis and metabolic stress, making this process a critical area for mechanistic and translational research.

Fatty Acid Oxidation and Hepatic Energy Homeostasis

Fatty acid oxidation is essential for maintaining hepatic energy balance and preventing lipid overload. Mitochondrial β-oxidation serves as the primary pathway for fatty acid catabolism, while peroxisomal oxidation handles very-long-chain fatty acids. Impairment in these oxidative pathways leads to lipid accumulation, mitochondrial dysfunction, oxidative stress, and inflammation—hallmarks of MASLD progression. Current research focuses on transcriptional regulators such as PPARα and AMPK, which coordinate fatty acid oxidation and represent potential therapeutic targets.

VLDL Biogenesis: Molecular Assembly and Lipidation

VLDL biogenesis is a multistep process initiated in the endoplasmic reticulum, where apolipoprotein B100 (ApoB100) is lipidated by microsomal triglyceride transfer protein (MTP). This process ensures efficient packaging of triglycerides and cholesterol into nascent lipoprotein particles. Defects in VLDL assembly can result in intracellular triglyceride accumulation, exacerbating hepatic steatosis. Despite its importance, the precise regulation of ApoB stability, lipid availability, and ER quality control during VLDL formation remains incompletely understood.

Regulation of VLDL Secretion and Systemic Lipid Distribution

Once assembled, VLDLs are secreted into the circulation to deliver triglycerides to peripheral tissues. This secretion process plays a protective role by exporting excess hepatic lipids; however, excessive VLDL output contributes to hypertriglyceridemia and atherosclerosis. Hormonal signals, nutrient availability, and insulin resistance strongly influence VLDL secretion rates. Ongoing research aims to clarify how altered hepatic insulin signaling selectively enhances VLDL secretion while failing to suppress lipid synthesis in metabolic disease states.

Clinical Implications and Future Research Directions

Dysregulation of fatty acid oxidation and VLDL metabolism links MASLD to systemic metabolic disorders, including type 2 diabetes and cardiovascular disease. Given that atherosclerosis remains the leading cause of global mortality, hepatic lipid handling has emerged as a critical determinant of cardiometabolic risk. Future research must integrate molecular biology, omics technologies, and clinical studies to unravel unresolved mechanisms governing hepatic lipid balance. Advancing this knowledge is essential for developing targeted therapies to prevent liver disease progression and reduce cardiovascular morbidity.

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#LiverMetabolism #VLDL #FattyAcidOxidation #LipidHomeostasis #MASLD #NAFLD #HepaticSteatosis #CardiometabolicHealth #Atherosclerosis #MetabolicDisease #ApoB100 #MTP #InsulinResistance #LipidResearch #Hepatology #MolecularMetabolism #TranslationalResearch #CardiovascularRisk #MetabolicSyndrome #LiverHealth

Cosmetic Wipe Microbiology Testing 🧴🦠 | Single-Lab Validation Study #pencis #researchawards

Introduction

Cosmetic wipes are widely used for baby care, personal hygiene, makeup removal, and topical product application due to their convenience and versatility. However, despite containing preservatives, these products remain susceptible to microbial contamination during manufacturing, packaging, and consumer use. Such contamination can pose risks ranging from product spoilage to skin infections, highlighting the need for reliable microbiological quality control. Currently, there is no universally validated method for microbiological testing of cosmetic wipes, creating a regulatory and analytical gap. Addressing this challenge is essential for consumer safety and for harmonizing testing protocols within regulatory frameworks such as the FDA Biological Analytical Manual (BAM).

Microbiological Risks Associated with Cosmetic Wipes

Cosmetic wipes provide a moist, nutrient-containing environment that can support microbial survival, especially when preservatives are unevenly distributed or compromised over time. Contamination may occur from raw materials, processing equipment, or repeated consumer handling. Spore-forming bacteria such as Bacillus cereus are of particular concern due to their resistance to preservatives and environmental stresses. The presence of such microorganisms can lead to dermatological reactions, infections, and reduced product shelf life, emphasizing the importance of accurate detection and enumeration methods.

Need for a Validated Sample Preparation Method

Traditional microbiological testing approaches used for cosmetics are often unsuitable for wipes due to their heterogeneous structure, variable liquid content, and complex preservative systems. Sampling only a small portion of a wipe may not reflect the true microbial load, while whole-wipe analysis presents technical challenges in extraction efficiency. The absence of a standardized, validated method complicates inter-laboratory comparisons and regulatory enforcement. Therefore, developing a specific, reproducible sample preparation protocol is critical for reliable quantitative microbial analysis of cosmetic wipes.

Comparative Evaluation of Extraction Methods

This study evaluated three extraction approaches: mBAM1g (1 g reference method), mBAMww (whole wipe method based on BAM Chapter 23), and ISOww (whole wipe method based on ISO without Tween 80). Ten different wipe formulations with varying compositions and preservative systems were inoculated with B. cereus spores and aged for 14 days. Results showed that for commercial wipes, whole-wipe methods (mBAMww and ISOww) performed as well as or better than the 1 g method, suggesting improved representativeness of microbial recovery when the entire wipe is analyzed.

Impact of Wipe Composition, Preservatives, and Surfactants

Wipe matrix composition, preservative type, and inoculation method significantly influenced microbial distribution and recovery. Laboratory-made wipes showed higher recovery from 1 g samples compared to whole wipes, likely due to cell loss or uneven distribution during aging. The inclusion of Tween 80 (T80) enhanced the recovery of B. cereus, indicating its role in improving microbial release from wipe fibers. These findings underscore the importance of considering formulation-specific factors when designing microbiological testing protocols.

Regulatory Implications and Recommended Method

Based on performance, reproducibility, and applicability to commercial products, the mBAMww whole-wipe method is recommended for routine microbiological analysis of cosmetic wipes. Adoption of this method within the FDA BAM would provide a standardized approach for industry and regulators, improving product safety assessment and consumer protection. This work represents a significant step toward establishing validated microbiological testing guidelines for cosmetic wipes and supports evidence-based regulatory decision-making.

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#CosmeticWipes,#MicrobiologicalTesting,#BacillusCereus,#FDA_BAM,#CosmeticSafety,#PreservativeEfficacy,#WholeWipeMethod,#SamplePreparation,#ProductContamination,#SkinHealth,#RegulatoryScience,#QualityControl,#MicrobialRecovery,#SporeFormingBacteria,#Tween80,#CosmeticMicrobiology,#MethodValidation,#ConsumerSafety,#ISOStandards,#PersonalCareResearch,

The Lungs 🫁❤️ | Cardiovascular Risk in COPD Patients with Prior Tuberculosis #pencis #researchawards

 

Introduction

Chronic obstructive pulmonary disease (COPD) and tuberculosis (TB) are increasingly recognized as intersecting global health challenges, particularly in low- and middle-income countries and among aging populations. Beyond shared risk factors, prior pulmonary TB has emerged as an independent and robust determinant of COPD, even in never-smokers. This overlap creates a unique clinical scenario in which structural lung damage, persistent immune activation, and systemic inflammation interact to elevate cardiovascular disease (CVD) risk. Understanding COPD through a TB-aware lens is therefore essential for advancing both respiratory and cardiovascular outcomes in high-burden settings.

Epidemiology and Distinct COPD–Post-TB Phenotypes

Epidemiological evidence consistently demonstrates higher COPD prevalence among individuals with a history of pulmonary TB. This post-TB COPD phenotype is clinically distinct, characterized by mixed obstructive–restrictive ventilatory defects, reduced diffusing capacity (DLCO), and radiographic sequelae such as fibrosis and bronchiectasis. Patients frequently experience higher exacerbation rates, increased hospitalizations, and worse functional status, underscoring the need to recognize post-TB lung disease as more than conventional smoking-related COPD.

Pathobiological Mechanisms Linking TB, COPD, and Cardiovascular Risk

Mechanistic studies suggest that convergent biological pathways drive excess cardiopulmonary risk in COPD patients with prior TB. Chronic immune activation, endothelial dysfunction, prothrombotic remodeling, and dysregulated lipid metabolism contribute to a milieu that promotes atherosclerosis, venous thromboembolism, and pulmonary hypertension. Additional processes such as molecular mimicry and epigenetic reprogramming following TB infection provide biologic plausibility for long-term systemic effects extending well beyond pulmonary impairment.

Biomarkers, Multimarker Panels, and Risk Stratification

Single biomarkers inadequately capture the complex risk profile of COPD–TB overlap. Emerging evidence supports the use of multimarker panels integrating inflammatory markers, endothelial injury indicators, myocardial strain or fibrosis biomarkers, and coagulation factors. These panels offer incremental prognostic value beyond traditional clinical variables, potentially enabling earlier identification of patients at heightened cardiovascular risk and facilitating more precise, personalized management strategies.

Risk Prediction Models and Sleep-Disordered Breathing Considerations

While contemporary tools such as QRISK4 now include COPD as a cardiovascular risk factor, they do not explicitly account for prior TB or post-TB COPD phenotypes. This gap limits their accuracy in TB-endemic regions. Additionally, sleep-disordered breathing, which is prevalent in COPD and associated with adverse cardiovascular outcomes, remains underexplored in post-TB populations. Incorporating TB history and sleep-related variables into future prediction models could substantially improve risk estimation.

Clinical and Implementation Implications in Resource-Limited Settings

In resource-constrained environments, pragmatic approaches are essential. Integrated assessments combining clinical history, targeted biomarkers, spirometry with lung volumes, DLCO, six-minute walk testing, and focused imaging can guide individualized care. Prioritized access to positive airway pressure therapy, guideline-concordant pharmacotherapy, and task-shifting strategies are feasible adaptations. Ultimately, TB-aware cardiopulmonary risk models and implementation studies are urgently needed to translate mechanistic insights into equitable, real-world benefits.

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#COPD, #Tuberculosis, #PostTBLungDisease, #CardiovascularRisk, #ChronicInflammation, #EndothelialDysfunction, #PulmonaryHypertension, #VenousThromboembolism, #DLCO, #Biomarkers, #MultimarkerPanels, #RiskPrediction, #QRISK4, #SleepDisorderedBreathing, #GlobalHealth, #LowMiddleIncomeCountries, #IntegratedCare, #RespiratoryResearch, #CardioPulmonaryHealth, #TranslationalResearch,

Lactic Acid Bacteria Traditional Fermented Milk 🥛🦠| Natural Antimicrobial #pencis #researchawards

Introduction

Lactic acid bacteria (LAB) have gained significant attention in food microbiology due to their natural ability to enhance food safety and extend shelf life through biopreservation. These microorganisms synthesize a wide range of antimicrobial compounds, including organic acids, hydrogen peroxide, and bacteriocins, which effectively inhibit foodborne pathogens. Traditionally fermented milk represents a rich and diverse ecological niche for LAB, making it a valuable source for isolating strains with functional and technological importance. Investigating LAB from such traditional products not only supports sustainable food preservation strategies but also contributes to the development of safer and more natural alternatives to chemical preservatives in the dairy industry.

Isolation and Screening of LAB from Traditionally Fermented Milk

In this study, thirty-two traditionally fermented dairy samples were systematically analyzed to isolate LAB strains with potential antimicrobial activity. The isolates were subjected to initial screening using agar spot and well diffusion assays to evaluate their antagonistic effects against two major foodborne pathogens, Listeria monocytogenes CECT 4032 and Staphylococcus aureus CECT 976. All isolated strains demonstrated noticeable inhibitory activity, confirming the antimicrobial richness of traditionally fermented milk. The strong suppression of pathogenic growth highlights the effectiveness of traditional fermentation practices in enriching functional microbial populations.

Antimicrobial Activity Against Foodborne Pathogens

The LAB isolates exhibited pronounced antimicrobial effects, with particularly strong inhibition observed against Listeria monocytogenes, a pathogen of major concern in dairy products. The consistent antagonistic behavior across all tested strains suggests the production of bioactive antimicrobial compounds that interfere with pathogen survival and proliferation. These findings reinforce the potential application of LAB as natural biopreservatives capable of enhancing food safety while reducing reliance on synthetic antimicrobial agents.

Molecular Identification and Taxonomic Characterization

Following phenotypic screening, five representative LAB isolates were selected for molecular identification using 16S rRNA gene sequencing. The analysis revealed that four isolates belonged to the genus Enterococcus, including one Enterococcus faecium and three Enterococcus durans, while one isolate was identified as a Lactococcus species. This taxonomic diversity reflects the complex microbial ecology of traditionally fermented milk and emphasizes the relevance of these genera in dairy fermentation and preservation processes.

Safety and Functional Assessment of Selected LAB Strains

A comprehensive evaluation of safety-related attributes and functional properties was conducted on the selected LAB strains. Importantly, none of the isolates exhibited proteolytic or lipolytic activities, which is a favorable characteristic for controlled dairy fermentation. Additionally, assessments of auto-aggregation and co-aggregation abilities indicated promising functional traits that may contribute to pathogen exclusion and microbial stability in food systems. These properties support the safe incorporation of these strains into food applications.

Technological Potential and Application in Dairy Biopreservation

The absence of undesirable enzymatic activities combined with strong antimicrobial performance underscores the technological suitability of the identified LAB strains for dairy fermentation and biopreservation. Their ability to inhibit major foodborne pathogens while maintaining desirable fermentation characteristics positions them as valuable candidates for developing natural starter cultures or protective adjuncts. Utilizing such LAB strains aligns with consumer demand for clean-label products and promotes the sustainable production of safer fermented dairy foods.

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#LacticAcidBacteria, #FoodBiopreservation, #FermentedMilk, #DairyMicrobiology, #FoodSafetyResearch, #AntimicrobialLAB, #ListeriaMonocytogenes, #StaphylococcusAureus, #NaturalPreservatives, #Enterococcus, #Lactococcus, #ProbioticResearch, #DairyFermentation, #MicrobialAntagonism, #Bacteriocins, #TraditionalFermentation, #FoodbornePathogens, #BioprotectiveCultures, #FunctionalMicrobes, #AppliedMicrobiology