Best Faculty Award 2025 🏆 | Nominate Top Educators Today! | #BestFacultyAward #Pencis

INTRODUCTION

In an era where research and education intersect to drive societal advancement, the Best Faculty Award 2025, presented by Pencis Conferences, emerges as a distinguished recognition for academic pioneers. This accolade celebrates individuals who exemplify innovation, academic leadership, and a lasting impact on teaching and research. Open to faculty members across all disciplines, the award acknowledges those who extend their influence beyond classroom instruction, leading transformative research and setting new standards in global education. With its international platform, the award not only honors excellence but also offers visibility at the Infectious Diseases Conference 2025, enabling awardees to engage with global thought leaders and contribute meaningfully to interdisciplinary research discussions. Institutions, peers, and students are encouraged to nominate faculty whose work continues to inspire academic progress and scholarly breakthroughs.

RESEARCH INTEGRATION IN EDUCATION

Faculty members today are expected to bridge the gap between teaching and research, and the Best Faculty Award 2025 underscores this dual responsibility. Effective educators don’t just disseminate knowledge—they create it. Integrating research into curriculum design enhances student engagement and deepens conceptual understanding, allowing learners to connect theory with real-world challenges. Award nominees are those who have successfully infused their research into teaching practices, transforming classrooms into collaborative hubs of innovation. These faculty members are often recognized not only for publishing in high-impact journals but also for mentoring student-led research, securing grants, and advancing their institutions’ research agendas. Their influence fosters a culture of inquiry, encouraging the next generation to pursue scientific and academic excellence with purpose.

CROSS-DISCIPLINARY COLLABORATION IN RESEARCH

One hallmark of impactful academic professionals is the ability to work beyond disciplinary boundaries. The Best Faculty Award 2025 spotlights faculty who exemplify interdisciplinary collaboration in research, producing knowledge that transcends conventional silos. These educators often serve as catalysts in forging alliances between scientific fields, fostering research that addresses complex global issues such as public health, sustainability, and digital transformation. By bringing together diverse perspectives, they help institutions become more adaptive and solutions-oriented. Their leadership in joint projects, international partnerships, and multi-sector research initiatives positions them as agents of academic integration and societal advancement.

RESEARCH MENTORSHIP AND CAPACITY BUILDING

Mentorship is a critical pillar in sustaining academic research, and award recipients of the Best Faculty Award 2025 are recognized not only for their own contributions but also for building future research leaders. Faculty who provide guidance to emerging scholars, especially in grant writing, publication ethics, and project development, shape long-term research capacity. Through mentorship, they promote a culture of scholarly rigor and accountability, often acting as principal investigators while empowering their mentees to explore independent ideas. Such mentorship has ripple effects—enriching institutional knowledge, strengthening postgraduate education, and elevating research standards across disciplines.

IMPACTFUL RESEARCH DISSEMINATION

Academic research holds little value unless it reaches and influences broader audiences. Faculty honored by the Best Faculty Award 2025 are those who ensure that their research outcomes are not just published but also translated into practice, policy, and public understanding. These educators understand the importance of dissemination beyond academia, often engaging in open-access publishing, science communication, and stakeholder-oriented presentations. Their research may inform national education policies, shape clinical practices, or lead to technological innovation. By sharing findings through conferences, webinars, and community partnerships, they contribute to a research ecosystem where knowledge fuels progress and accountability.

GLOBAL RESEARCH LEADERSHIP AND NETWORKING

International engagement is increasingly vital in the research landscape, and the Best Faculty Award 2025 champions those who have gained global recognition through their academic leadership. Whether leading multinational research teams or representing their institutions on global panels, these faculty members extend the influence of local research to international arenas. Their participation in events like the Infectious Diseases Conference 2025 serves as a platform to showcase their work and to initiate new collaborations across continents. These professionals act as research ambassadors, advocating for academic diplomacy and the global exchange of knowledge to address shared challenges and expand research frontiers.

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#BestFacultyAward2025 #AcademicExcellence #PencisConferences #FacultyRecognition #GlobalEducation #InnovativeTeaching #InfectiousDiseasesConference #AcademicLeadership #ResearchImpact #STEMInnovation #HumanitiesResearch #HigherEducation #EducationalInnovation #FacultyAchievement #ResearchExcellence #AcademicAwards #GlobalResearchCommunity #MentorshipInAcademia #FutureOfEducation #ScientificLeadership

AI in Diabetes Care 🧠 | Barriers & Breakthroughs from Healthcare Workers’ Views | #PencisHealthAI

INTRODUCTION

Diabetes, one of the most prevalent chronic conditions worldwide, poses an escalating challenge to public health systems. As technological innovations continue to reshape healthcare, Artificial Intelligence (AI) emerges as a promising tool to enhance diabetes management by improving accuracy, personalization, and efficiency in clinical decision-making. However, while AI offers transformative potential, its successful integration into diabetes care requires a deep understanding of both systemic and frontline perspectives. This study sets out to explore the perspectives of healthcare professionals—those at the heart of patient care—by identifying the barriers and facilitators affecting AI implementation. In doing so, it aligns technological advancement with real-world clinical needs, advocating for a bottom-up approach in future AI program development.

RESEARCH METHODOLOGY AND SCOPING APPROACH

This study employed a rigorous scoping review methodology guided by PRISMA-ScR standards and was registered with the Open Science Framework (OSF) for transparency. Literature was selected through a two-phase process: initial screening of titles and abstracts, followed by a detailed full-text review. Three independent reviewers ensured objectivity, with a fourth resolving any conflicts. The Joanna Briggs Institute (JBI) framework was used to extract and assess data, ensuring high methodological quality. The study synthesized both quantitative metrics and qualitative narratives, enabling a comprehensive understanding of AI implementation from the healthcare provider’s viewpoint.

BARRIERS TO AI ADOPTION IN DIABETES CARE

Multiple barriers hinder the adoption of AI in diabetes care, according to healthcare professionals. These include concerns over clinical accuracy, especially in dynamic, patient-specific scenarios, as well as high implementation and maintenance costs. Data privacy and cybersecurity risks further complicate trust in AI systems. Transparency in AI-driven decision-making remains a challenge, creating hesitation among practitioners who seek accountability and clarity. Moreover, limited access to AI training prevents many healthcare workers from fully engaging with or benefiting from these systems. These challenges emphasize the need for systemic and educational interventions before large-scale AI adoption.

FACILITATORS THAT ENCOURAGE AI INTEGRATION

Despite the barriers, several key facilitators promote the integration of AI in diabetes management. Healthcare workers recognize AI’s potential to enhance clinical efficiency by reducing workload, improving diagnostic accuracy, and saving time in routine processes. The ease of use and growing user-friendliness of AI interfaces also support broader adoption. Importantly, organizational support—such as investment in infrastructure, training, and interdisciplinary collaboration—significantly boosts trust in these technologies. These facilitators highlight that with the right support structures, AI can be seamlessly integrated into existing healthcare workflows, particularly in chronic disease management.

HEALTHCARE WORKERS’ ROLE IN BOTTOM-UP AI DEVELOPMENT

A key insight from this study is the pivotal role healthcare professionals play in shaping AI applications. Rather than imposing top-down systems, successful AI integration demands a bottom-up approach that values frontline insights and experiences. Healthcare workers can identify practical gaps, suggest realistic functionalities, and provide feedback for continuous system improvement. Their active participation not only increases system usability but also fosters a sense of ownership, trust, and accountability. This participatory approach aligns with sustainable innovation and ensures that AI systems are built to meet real clinical challenges.

IMPLICATIONS FOR PUBLIC HEALTH AND FUTURE RESEARCH

The findings carry profound implications for public health policy and AI research. Integrating AI in diabetes care is not merely a technical task but a socio-organizational transformation. Future research should focus on long-term evaluations of AI tools in real-world settings, paying attention to their impact on patient outcomes, clinician workflows, and equity in healthcare delivery. Furthermore, policy frameworks must prioritize training programs, ethical AI standards, and data governance. Aligning AI innovation with public health goals ensures not only technological progress but also socially responsible and equitable healthcare evolution.

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 Hashtags

#AIinHealthcare, #DiabetesManagement, #ArtificialIntelligence, #HealthTech, #ClinicalDecisionSupport, #HealthcareInnovation, #MedicalAI, #DigitalHealth, #ScopingReview, #PublicHealthResearch, #AIAdoption, #DataPrivacy, #HealthcareTraining, #BottomUpApproach, #EvidenceBasedMedicine, #HealthEquity, #ChronicDiseaseCare, #OrganizationalSupport, #MedicalBarriers, #TechFacilitators,

One Health Approach 🌍 | Sustainable Vector-Borne Disease Control | #InfectiousDiseases #Pencis

Introduction

Vector-borne diseases remain one of the major global public health concerns, particularly in low- and middle-income countries. The World Health Organization (WHO), recognizing the challenge, launched the Global Vector Control Response (GVCR) 2017–2030 to promote sustainable control and integrated management strategies. China’s implementation of this framework through the Four Pest-Free Village model marks a significant innovation in vector control by applying the One Health (OH) approach. By targeting the eradication of four common vectors—flies, mosquitoes, rodents, and cockroaches—through environmentally friendly methods and community participation, China integrates public health, veterinary care, and environmental protection to reduce disease transmission. Zhejiang Province, as a leading example, has demonstrated reduced disease incidence, improved wetland ecosystems, and lowered financial pressure on public health infrastructure. This integrated response holds promise for future vector control research and policy replication in other endemic regions.

The One Health Framework in Vector Control

The One Health concept promotes a collaborative, multisectoral, and transdisciplinary approach that connects human, animal, and environmental health. In the context of vector-borne disease control, this model offers a transformative platform by enabling interventions that simultaneously target health determinants across sectors. The Four Pest-Free Village initiative in China represents a successful embodiment of this approach. It not only addresses direct disease transmission risks from vectors but also facilitates ecological restoration and improved hygiene practices in rural areas. This integrated method underscores the importance of cross-sector partnerships between public health authorities, agricultural agencies, environmental scientists, and local communities to create sustainable and scalable disease prevention models.

Global Vector Control Response (GVCR) and Its Implementation

The GVCR 2017–2030 by WHO provides a global strategic framework to strengthen vector control capacity worldwide. Its pillars include increased intersectoral action, community engagement, evidence-based decisions, and capacity development. China's Four Pest-Free Village initiative aligns well with these pillars, effectively translating policy into action. The program's success in Zhejiang Province offers practical evidence supporting the GVCR’s core strategies. Research focusing on how such localized programs align with global policy can inform adaptations in different geographical and epidemiological contexts. Moreover, it provides a foundation for evaluating the scalability and sustainability of integrated vector management (IVM) strategies in other countries.

Eco-Friendly Approaches and Rural Transformation

A notable aspect of the Four Pest-Free Village strategy is its emphasis on environmentally friendly pest control solutions. Instead of relying solely on chemical interventions, the program promotes biological control methods, community sanitation, and habitat management. This transition contributes to rural transformation by improving public spaces, increasing biodiversity, and expanding wetlands—natural barriers to vector proliferation. Such ecological co-benefits create a feedback loop where health outcomes improve alongside environmental quality. Research into these synergies can support the development of environmentally sustainable public health interventions and offer models for climate-resilient disease control programs.

Community Participation and Multi-sector Engagement

Community engagement is central to the success of integrated vector control. In Zhejiang Province, local residents participated in pest eradication activities, waste management, and awareness campaigns. Their involvement ensured long-term program sustainability and cultural relevance. Additionally, coordination between health departments, agricultural bureaus, and environmental agencies created a multi-sectoral governance model. Future research should focus on the dynamics of community mobilization, incentive structures, and inter-agency collaboration to derive insights on enhancing participation, improving compliance, and achieving scalable results in other settings.

Economic Impact and Policy Implications

The Four Pest-Free Village model not only addresses health risks but also reduces the economic burden of vector-borne diseases. By lowering disease incidence, the program minimizes healthcare costs, reduces productivity losses, and lessens the demand for national subsidies for disease outbreaks. Zhejiang Province's implementation has proven cost-effective by integrating health promotion with rural development. Research evaluating the economic returns of such interventions can aid policymakers in justifying investments in preventive infrastructure. Economic modeling of vector control programs under the One Health lens can further influence global and national disease control budgets and priorities.

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Hashtags:
#VectorBorneDiseases, #OneHealthApproach, #SustainableControl, #IntegratedManagement, #GVCR2030, #WHOInitiative, #VectorControl, #MosquitoBorneDiseases, #ZoonoticDiseases, #RuralHealth, #EnvironmentalHealth, #PestFreeVillages, #WetlandRestoration, #CommunityEngagement, #PublicHealthPolicy, #InfectiousDiseasePrevention, #GlobalHealthSecurity, #ZhejiangModel, #ChinaVectorControl, #EcoFriendlySolutions

"Green Synthesis of Silver Nanoparticles from Bitter Melon 🌿 | Antibacterial Innovation Unveiled #Pencis #Nanotechnology"

Introduction

The growing concern over antibiotic resistance and the demand for sustainable alternatives has prompted research into biologically derived nanomaterials. In this study, silver nanoparticles (AgNPs) were synthesized using Momordica charantia (bitter melon) extracts, a medicinal plant widely recognized for its therapeutic properties. The biosynthesis approach employed offers a green and cost-effective route for nanoparticle production, especially pertinent to applications in agriculture and food safety. By integrating phytochemical-rich plant extracts with nanotechnology, this study bridges the gap between traditional medicine and modern microbiological solutions. The resultant AgNPs were subjected to antibacterial testing, revealing potent activity against Escherichia coli ATCC25922—a known foodborne pathogen. The experiment not only confirms the viability of plant-based AgNPs for microbiological control but also paves the way for scalable production strategies aimed at curbing agricultural and clinical infections.

Nanoparticle characterization techniques

To verify the structural and chemical integrity of the biosynthesized AgNPs, a series of characterization techniques were employed. Ultraviolet-visible (UV-Vis) spectroscopy confirmed the plasmon resonance peak, indicating nanoparticle formation. Fourier transform infrared spectroscopy (FTIR) was used to identify the functional groups in bitter melon extracts that facilitated reduction and stabilization of silver ions. Scanning electron microscopy (SEM) provided visual confirmation of particle morphology, suggesting spherical or quasi-spherical structures consistent with standard AgNP formation. These combined techniques not only validated the biosynthesis process but also established a reproducible characterization protocol for future studies in green nanotechnology. The application of these methods ensures consistency and enhances understanding of the interaction between bioactive plant components and silver ions.

Antibacterial efficacy of biosynthesized AgNPs

The AgNPs derived from Momordica charantia extracts demonstrated superior antibacterial performance when tested against Escherichia coli ATCC25922. Notably, the AgNPs achieved 100% bacterial kill at significantly lower concentrations and shorter incubation periods compared to silver ions alone. This improved efficacy is likely due to the enhanced surface area and reactive properties of nanoparticles, allowing more efficient disruption of microbial cell membranes and intracellular processes. These results are particularly significant in addressing antibiotic resistance, as AgNPs provide a non-traditional mechanism of action that is difficult for bacteria to evade. Their effectiveness in both solution and powder forms suggests potential for multiple application routes in agricultural pathogen control and food safety.

Comparison with conventional silver ions

A crucial part of the study involved evaluating the antibacterial performance of biosynthesized AgNPs against conventional silver ions. The results indicated that while both silver ions and AgNPs are antimicrobial, the nanoparticles outperformed their ionic counterparts in terms of kill rate and required dosage. The nanoscale structure likely enhances interaction with bacterial cells, leading to increased permeability and oxidative stress. These findings support the hypothesis that nanoparticle-based approaches are more effective and efficient, making them preferable candidates for antimicrobial interventions, especially in cases where traditional agents fail. This contrast further underlines the need to move towards nanotechnology-based applications in microbiological research.

Potential for industrial-scale production

The success of this synthesis method opens the door to large-scale production of AgNPs using Momordica charantia, a widely available and cost-effective plant. The biosynthetic pathway is eco-friendly, bypassing the need for toxic chemical reducers typically used in nanoparticle synthesis. The use of edible plant material not only ensures biocompatibility but also aligns with sustainability goals in industrial practices. The proven efficacy against foodborne pathogens highlights its relevance to food processing, packaging, and agricultural disinfection. Future work could focus on optimizing extraction conditions, reaction kinetics, and storage stability to support commercial deployment in diverse sectors including food technology, pharmaceuticals, and environmental sanitation.

Implications for antibiotic-resistant pathogens

The emergence of antibiotic-resistant strains poses a critical threat to global public health and agriculture. The current study’s demonstration of AgNP efficacy against E. coli—a model foodborne pathogen—underscores the nanoparticles’ role as a potential alternative to conventional antibiotics. Due to their unique antimicrobial mechanisms, AgNPs may circumvent traditional resistance pathways, providing a promising avenue for controlling pathogens that no longer respond to standard treatment. The findings suggest the importance of continued exploration into plant-based nanoparticle synthesis and their deployment in antimicrobial formulations aimed at resistant bacterial species in both agricultural and clinical settings.

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Hashtags

#SilverNanoparticles, #AgNPs, #MomordicaCharantia, #GreenNanotechnology, #NanoparticleSynthesis, #BitterMelonExtract, #AntibacterialNanoparticles, #EscherichiaColi, #EColiInhibition, #FoodbornePathogenControl, #UVVisSpectroscopy, #FTIRAnalysis, #SEMImaging, #NanoAntibiotics, #IndustrialNanotech, #NaturalAntimicrobials, #AntibioticResistance, #EcoFriendlySynthesis, #AgriculturalPathogens, #FoodSafetySolutions,

🔬 Fourth Nationwide Surveillance Reveals Japan’s Alarming Antimicrobial Resistance | #SurgicalInfections #Pencis

Introduction

Antimicrobial resistance (AMR) in surgical site infections (SSIs) is an escalating concern, particularly due to the misuse or inappropriate selection of antibiotic therapies. In Japan, a comprehensive nationwide survey conducted from 2021 to 2023 aimed to understand the shifting patterns of antimicrobial susceptibility in SSI-associated pathogens. This study compared recent data with those from earlier nationwide surveys conducted in 2010, 2014–2015, and 2018–2019. Key findings highlight that the susceptibility profiles of common pathogens such as Enterobacterales, Staphylococcus aureus, and Bacteroides species have significantly evolved over time, suggesting emerging resistance trends. The continuous monitoring of antimicrobial susceptibility helps in developing effective antibiotic stewardship programs and is crucial for improving clinical outcomes while reducing AMR risks in post-surgical patients. The present research underlines the necessity of adaptive therapeutic strategies guided by timely microbiological surveillance.

Emergence of resistant enterobacterales in ssi cases

The surveillance report reveals fluctuating but concerning trends in the emergence of extended-spectrum β-lactamase (ESBL)-producing Enterobacterales in SSIs across Japan. Initially at 4.4% in 2010, the incidence peaked to 13.5% in 2014–2015, dropped to 6.6% in 2018–2019, and then rose again to 11.2% by 2021–2023. These shifts underscore the dynamic nature of bacterial resistance, likely influenced by antimicrobial usage patterns in surgical prophylaxis and therapy. This resurgence suggests a pressing need to revise empirical treatment regimens and advocate for more effective surveillance systems and targeted antibiotic use, especially against ESBL-producing strains that limit the efficacy of many β-lactam antibiotics.

Trends in β-lactam susceptibility and therapeutic implications

A significant finding in the report is the declining susceptibility of E. coli and K. pneumoniae to commonly used β-lactam antibiotics, such as sulbactam/ampicillin and cefazolin. The diminished efficacy of tazobactam/piperacillin, with susceptibility decreasing from high rates in 2018–2019 to 71.8% in 2021–2023, is especially noteworthy. Geometric mean MICs of tazobactam/ceftolozane have also increased, indicating reduced potency over time. These trends emphasize the growing challenge of selecting effective β-lactam-based therapies and the potential need to pivot toward newer or combination therapies, backed by timely antibiograms to curb treatment failure.

Declining mrsa prevalence and its possible correlation with antimicrobial policy

One of the few positive trends observed in the surveillance was the declining incidence of methicillin-resistant Staphylococcus aureus (MRSA) from 72% in the first survey to just 39% in the most recent survey. This consistent reduction may reflect improved hospital infection control practices, judicious antibiotic use, and possibly the substitution of previously overused agents with more targeted therapies. The findings suggest that national antimicrobial stewardship efforts and updated surgical prophylaxis guidelines may be yielding tangible benefits in controlling resistant S. aureus strains in post-operative care.

Limited effectiveness of select antimicrobials against anaerobic pathogens

The report highlights that for Bacteroides species, susceptibility to several commonly prescribed antimicrobials remains low. Moxifloxacin (57%), cefmetazole (54%), and clindamycin (44%) all demonstrated suboptimal activity, pointing to reduced treatment options for anaerobic infections in SSIs. This is particularly alarming given the crucial role anaerobes play in deep surgical wound infections. These findings stress the importance of reevaluating current empirical treatment guidelines for anaerobic coverage and possibly integrating newer agents or combinations to enhance therapeutic outcomes in mixed bacterial infections.

 Sustained effectiveness of carbapenems amidst rising resistance

Despite rising resistance trends in various drug classes, carbapenems continue to show reliable activity against the majority of SSI-associated pathogens. Their broad-spectrum efficacy positions them as a last-resort therapy in complicated cases involving multi-drug resistant organisms. However, the sustained efficacy of carbapenems must be cautiously preserved, as over-reliance could lead to carbapenem-resistant strains. This reinforces the importance of using these agents judiciously and only in situations backed by susceptibility evidence, while also pushing for research into novel antimicrobials or alternative therapies to diversify the antibiotic arsenal.

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Hashtags

#AntimicrobialResistance, #SSIs, #JapanSurveillance, #Enterobacterales, #ESBL, #MRSA, #SurgicalInfections, #AntibioticTrends, #Carbapenems, #Tazobactam, #Ceftolozane, #Bacteroides, #AMRJapan, #MicrobialResistance, #AntibioticStewardship, #ClindamycinResistance, #MICTrends, #SSIResearch, #AntimicrobialTherapy, #PencisResearch,

Inhibition of Human Coronavirus 229E by Lactoferrin-Derived Peptidomimetics | #InfectiousDiseases #Lactoferrin #Pencis

Introduction

Viral respiratory infections continue to pose serious challenges to global public health and economic stability. Despite the effectiveness of vaccines, they are often insufficient on their own, particularly during the emergence of novel viral strains or in vulnerable populations with compromised immunity. This gap necessitates the parallel development of antiviral therapeutics to mitigate disease severity and transmission. In the context of human coronavirus 229E (HCoV-229E), a respiratory pathogen known to cause severe infections in immunocompromised individuals, the identification of therapeutic inhibitors is particularly urgent. Inspired by previous research on bovine lactoferrin (bLf)-derived compounds that showed potent in vitro activity against the influenza A virus, this study explores the potential of these agents in a coronavirus model. The study aims to determine whether these peptidomimetics can inhibit viral infection processes such as entry and replication. This research highlights the ongoing need for adaptive strategies in antiviral drug development and underscores the importance of drug repurposing approaches.

Compound repositioning as an antiviral strategy

Drug repositioning is an emerging approach in antiviral research that identifies new therapeutic uses for existing compounds. In this study, researchers revisited bLf-derived tetrapeptides and peptidomimetics previously shown to be effective against influenza A virus, repurposing them to target HCoV-229E. Such a strategy offers several advantages, including accelerated development timelines, reduced safety concerns due to prior characterization, and cost-effectiveness. By applying this method to coronavirus research, the study extends the utility of known bioactive molecules into new viral landscapes. These findings provide compelling evidence for the versatility of bLf-derived compounds and open new doors for rapid therapeutic interventions during future outbreaks.

Mechanisms of viral inhibition by SK(N-Me)HS and SNKHS

The compounds SK(N-Me)HS (3) and SNKHS (5) demonstrated promising antiviral activities through distinct mechanisms. SK(N-Me)HS was shown to disrupt both viral entry and replication, indicating a dual-action mode of inhibition. On the other hand, SNKHS predominantly blocks infection at early stages, suggesting interference with the initial binding or fusion processes. These mechanistic insights are vital for understanding the potential roles these compounds may play in combination therapies or prophylactic applications. Such specificity in targeting viral life cycle phases offers flexibility in tailoring treatment regimens and reducing the development of resistance.

Biophysical validation of spike protein binding

The efficacy of antiviral compounds is heavily dependent on their ability to interact with viral surface proteins. In this study, biophysical techniques confirmed the high-affinity binding of both SK(N-Me)HS and SNKHS to the spike protein of HCoV-229E. This protein is essential for mediating host cell entry, making it an attractive therapeutic target. The ability of the compounds to bind with high specificity suggests a potential to interfere with conformational changes required for membrane fusion, ultimately halting infection. This binding validation reinforces the pharmacological relevance of these compounds and supports their further optimization for clinical use.

Computational modeling of viral interaction sites

To further understand how these compounds exert their inhibitory effects, computational modeling was employed to predict interaction sites on the viral spike protein. The models revealed that the compounds likely bind to regions involved in structural rearrangements necessary for membrane fusion. This predictive approach enhances understanding of the molecular underpinnings of inhibition and supports structure-based drug design efforts. Computational insights also provide a roadmap for refining compound structures to improve efficacy and reduce off-target interactions, thereby streamlining the drug development pipeline.

Implications for future coronavirus therapeutic development

The findings from this study have broader implications for therapeutic strategies against coronaviruses. By demonstrating the efficacy of bLf-derived peptidomimetics in targeting HCoV-229E, this research paves the way for developing similar inhibitors against other coronaviruses, including SARS-CoV-2 and its variants. The study also reinforces the utility of compound repurposing and encourages continued investment in multifunctional therapeutics that can be rapidly deployed during outbreaks. As viral threats evolve, having a library of adaptable, high-affinity inhibitors ready for clinical translation is a critical component of global health preparedness.

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Hashtags

#CoronavirusResearch, #AntiviralDevelopment, #LactoferrinPeptides, #Peptidomimetics, #HCoV229E, #ViralInhibition, #SpikeProteinTargeting, #MembraneFusionBlockers, #DrugRepositioning, #TherapeuticInnovation, #InfectiousDiseases, #RespiratoryVirus, #bLfDerivedCompounds, #SKNMeHS, #SNKHS, #BiophysicalAnalysis, #ComputationalVirology, #EntryInhibitors, #ViralReplication, #FusionInhibitor

🌟 Most Cited Author Award | Global Recognition for Research Excellence | #PencisAwards #MostCitedAuthor

INTRODUCTION

The Most Cited Author Award stands as a global testament to research excellence, awarded to individuals whose scholarly work has amassed exceptional citations and influence. Hosted by Pencis Conferences, this recognition is rooted in scientific credibility and real-world impact. It acknowledges the authors whose publications not only advance knowledge but shape global research trends across disciplines such as infectious diseases, life sciences, and healthcare. This prestigious award emphasizes how vital consistent, innovative, and referenced work is to the progress of academic thought and real-world solutions. Through this award, leading scholars gain deserved visibility and acclaim while inspiring the next generation of researchers to pursue groundbreaking paths. It marks a pinnacle of research leadership and collaborative potential.

RESEARCH IMPACT AND CITATION EXCELLENCE

High citation metrics are more than just numbers—they represent the tangible influence of a scholar's work on their field and beyond. The Most Cited Author Award places emphasis on research that is not only prolific but profoundly impactful in shaping methodologies, knowledge dissemination, and future studies. Citation indexes and H-indices help to quantify how research is received, reused, and built upon. This award showcases how such scholarship transforms theoretical knowledge into real-world change, especially in fields like infectious diseases and public health, where timely insights save lives and inform policy.

GLOBAL SCHOLARLY RECOGNITION

Academic visibility on a global platform is key to advancing collaborative science. The Most Cited Author Award acts as an international hallmark, highlighting researchers whose work resonates across borders and cultures. By being recognized at this level, scholars amplify their reach, gain access to prestigious journals, and open doors to global partnerships. As science becomes increasingly interdisciplinary and cross-national, such recognition helps integrate ideas across continents, from high-impact healthcare solutions to life-saving infectious disease control strategies.

ACADEMIC LEADERSHIP AND REPUTATION

This award isn't just about numbers—it honors the intellectual leadership of researchers who guide entire fields with their vision and rigor. Being the Most Cited Author reflects a combination of scholarly excellence, research foresight, and community influence. It helps establish a legacy within the academic ecosystem, positioning researchers as role models and thought leaders. Such a status enhances opportunities for keynote roles, editorial board positions, and greater responsibility in shaping future research agendas.

INNOVATION AND COLLABORATIVE POTENTIAL

The recognition also shines a light on innovation—how novel methodologies, bold hypotheses, and new research frameworks redefine knowledge boundaries. The Most Cited Author Award recognizes these pioneering efforts and boosts researchers’ chances of collaborating across industries, academic institutions, and international bodies. Innovation often thrives when interdisciplinary minds converge, and awardees find themselves at the heart of these transformative intersections, especially in emerging areas of health and biosciences.

MOTIVATION FOR EMERGING SCHOLARS

Beyond honoring established researchers, this award serves as a powerful source of inspiration for early-career scientists and students. It symbolizes what’s possible through persistence, quality, and scholarly dialogue. Young researchers observing these awardees are encouraged to contribute meaningfully, stay consistent, and think globally. The visibility of this recognition encourages institutions to invest in talent, support research funding, and promote international collaboration in high-stakes fields such as infectious diseases.

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Hashtags

#MostCitedAuthor, #PencisConferences, #InfectiousDiseasesResearch, #GlobalResearchImpact, #AcademicLeadership, #CitationExcellence, #InnovationInScience, #ResearchRecognition, #HindexLeaders, #TopResearchers, #ScholarlyInfluence, #HealthScienceResearch, #LifeSciencesAwards, #AcademicVisibility, #ResearchInspiration, #CrossBorderScience, #InternationalCollaboration, #ScientificInnovation, #PeerRecognition, #PencisAwards,