In Vitro Inhibition of Pathogens by Polyols: Optical Density-Based Screening and Implications for the Oral-Systemic Axis

Preprints.org · 2026-04-02

Polyols are widely used as non-cariogenic sweeteners in foods and oral care products, yet their comparative activity against diverse oral microbes and their potential relevance to the oral–systemic axis remain incompletely defined. Here, we performed an in vitro, optical-density (OD)-based screening of four polyols—allulose, D-mannose, erythritol, and xylitol—against Streptococcus mutans, Streptococcus anginosus, Candida albicans, and Fusobacterium nucleatum. Cultures were grown with polyols at 1–20% (w/v), and OD600 was recorded at organism-specific endpoints (~24 h). Allulose, erythritol, and xylitol produced strong, concentration-dependent suppression of streptococcal growth at ≥5–10%, whereas C. albicans showed minimal changes across the tested range. F. nucleatum was highly sensitive to allulose, D-mannose, and xylitol at ≥5% (reducing OD to ≤13% of untreated control), while low concentrations of D-mannose and erythritol increased OD above control, suggesting species-specific utilization or stress responses. One-way ANOVA with Tukey’s HSD post hoc testing supported significant between-polyol differences for most concentrations in Streptococcus spp. and F. nucleatum. Collectively, these results identify polyol- and taxon-specific growth phenotypes that can inform the formulation of swallow-safe oral hygiene products and motivate follow-up work in polymicrobial biofilm models and clinical studies targeting oral inflammation and downstream systemic risk.

In Vitro Inhibition of Pathogens by Polyols: Optical Density-Based Screening and Implications for the Oral–Systemic Axis

Microorganisms · 2026-04-15

Polyols are widely used as non-cariogenic sweeteners in foods and oral care products, yet their comparative activity against diverse oral microbes and their potential relevance to the oral–systemic axis remain incompletely defined. Here, we performed an in vitro, optical density (OD)-based screening of four polyols—allulose, D-mannose, erythritol, and xylitol—against Streptococcus mutans, Streptococcus anginosus, Candida albicans, and Fusobacterium nucleatum. Cultures were grown with polyols at 1–20% (w/v), and OD600 was recorded at organism-specific endpoints (~24 h). Allulose, erythritol, and xylitol produced strong, concentration-dependent suppression of streptococcal growth at ≥5–10%, whereas C. albicans showed minimal changes across the tested range. F. nucleatum was highly sensitive to allulose, D-mannose, and xylitol at ≥5% (reducing OD to ≤13% of the untreated control), while low concentrations of D-mannose and erythritol increased OD beyond that of the control, suggesting species-specific utilization or stress responses. One-way ANOVA with Tukey’s HSD post hoc testing supported significant between-polyol differences for most concentrations in Streptococcus spp. and F. nucleatum. Collectively, these results identify polyol- and taxon-specific growth phenotypes that can inform the formulation of swallow-safe oral hygiene products and motivate follow-up work in polymicrobial biofilm models and clinical studies targeting oral inflammation and downstream systemic risk.

Living in the subsurface: local adaptations that define a global biome

2025-01-01

Wastewater-based surveillance for influenza and respiratory syncytial virus: Insights from a 21-month study in Oklahoma

Epidemics · 2025-10-11 · 1 citations

Upper respiratory infections caused by viruses such as respiratory syncytial virus (RSV) and influenza are major health concerns globally. Traditional surveillance methods of these viruses rely on clinical data, which can miss mild or asymptomatic cases, leading to gaps in understanding of their epidemiology. Wastewater-based surveillance (WBS) offers an alternative monitoring approach, providing real-time, population-representative data infection levels. This study aimed to evaluate the value of WBS for monitoring influenza A and B and RSV in Oklahoma from August 2022 to May 2024. Wastewater samples were collected weekly from 18 treatment plants statewide, and viral RNA was quantified using RT-qPCR. We compared wastewater data with reported influenza hospitalizations and RSV test positivity. We found significant seasonality in clinical outcomes as well as wastewater concentrations for influenza A and RSV. Our results also showed comparatively high wastewater concentrations during times when influenza hospitalizations and RSV test positivity were at their seasonal highs. Our study demonstrates the potential for WBS to offer timely insights into respiratory virus trends, particularly for underserved communities. This method complements traditional surveillance, offering a broader understanding of viral transmission and supporting public health interventions. • Broad Application : First study to evaluate Wastewater Based Surveillance (WBS) for monitoring influenza A, influenza B, and RSV over a large geographic area in Oklahoma, covering many underserved and vulnerable populations. • Seasonal Tracking : WBS identified seasonal patterns of influenza and RSV, correlating with traditional clinical indicators. • Equity in Public Health : Demonstrated potential of WBS to enhance surveillance in underserved communities with limited access to traditional healthcare systems. • Complementary Methodology : WBS can supplement traditional surveillance, offering a more comprehensive understanding of respiratory virus transmission in Oklahoma.

Wastewater surveillance as a tool for understanding West Nile virus transmission and distribution in Oklahoma

The Science of The Total Environment · 2025-05-20 · 6 citations

Real-Time Monitoring of SARS-CoV-2 Variants in Oklahoma Wastewater through Allele-Specific RT-qPCR

Preprints.org · 2024-09-09

During the COVID-19 pandemic, wastewater surveillance was used to monitor community transmission of SARS-CoV-2. As new genetic variants emerged, the need for timely identification of these variants in wastewater became an important focus. In response to increased reports of Omicron transmission across the United States, the Oklahoma Wastewater Surveillance team utilized allele-specific RT-qPCR assays to detect and differentiate variants, such as Omicron, from other variants found in wastewater in Oklahoma. The PCR assays showed presence of the Omicron variant in Oklahoma on average two weeks before official reports, which was confirmed through genomic sequencing of selected wastewater samples. Through continued surveillance from November 2021 to January 2022, we also demonstrated the transition from prevalence of the Delta variant to prevalence of the Omicron variant in local communities. We further assessed how this transition correlated with certain demographic factors characterizing each community. Our results highlight RT-qPCR assays as a rapid, simple and cost-effective method for monitoring community spread of SARS-CoV-2 genetic variants in wastewater. Additionally, they demonstrate that specific demographic factors such as ethnic composition and household income can correlate with the timing of SARS-CoV-2 variant introduction and spread.

Acceleration of Deep Subsurface Fluid Fluxes in the Anthropocene

Earth s Future · 2024-04-01 · 4 citations

Abstract The Anthropocene has been framed around humanity's impact on atmospheric, biologic, and near‐surface processes, such as land use and vegetation change, greenhouse gas emissions, and the above‐ground hydrologic cycle. Groundwater extraction has lowered water tables in many key aquifers but comparatively little attention has been given to the impacts in the deeper subsurface. Here, we show that fluid fluxes from the extraction and injection of fluids associated with oil and gas production and inflow of water into mines likely exceed background flow rates in deep (>500 m) groundwater systems at a global scale. Projected carbon capture and sequestration (CCS), geothermal energy production, and lithium extraction to facilitate the energy transition will require fluid production rates exceeding current oil and co‐produced water extraction. Natural analogs and geochemical modeling indicate that subsurface fluid manipulation in the Anthropocene will likely appear in the rock record. The magnitude and importance of these changes are unclear, due to a lack of understanding of how deep subsurface hydrologic and geochemical cycles and associated microbial life interact with the rest of the Earth system.

Real-Time Monitoring of SARS-CoV-2 Variants in Oklahoma Wastewater through Allele-Specific RT-qPCR

Microorganisms · 2024-09-30 · 1 citations

During the COVID-19 pandemic, wastewater surveillance was used to monitor community transmission of SARS-CoV-2. As new genetic variants emerged, the need for timely identification of these variants in wastewater became an important focus. In response to increased reports of Omicron transmission across the United States, the Oklahoma Wastewater Surveillance team utilized allele-specific RT-qPCR assays to detect and differentiate variants, such as Omicron, from other variants found in wastewater in Oklahoma. The PCR assays showed presence of the Omicron variant in Oklahoma on average two weeks before official reports, which was confirmed through genomic sequencing of selected wastewater samples. Through continued surveillance from November 2021 to January 2022, we also demonstrated the transition from prevalence of the Delta variant to prevalence of the Omicron variant in local communities. We further assessed how this transition correlated with certain demographic factors characterizing each community. Our results highlight RT-qPCR assays as a rapid, simple, and cost-effective method for monitoring the community spread of SARS-CoV-2 genetic variants in wastewater. Additionally, they demonstrate that specific demographic factors such as ethnic composition and household income can correlate with the timing of SARS-CoV-2 variant introduction and spread.

Acceleration of Deep Subsurface Fluid Fluxes in the Anthropocene

2024-03-25 · 1 citations

The Anthropocene has been framed around humanity's impact on atmospheric, biologic, and near-surface processes, such as land use and vegetation change, greenhouse gas emissions, and the above-ground hydrologic cycle.Groundwater extraction has lowered water tables in many key aquifers but comparatively little attention has been given to the impacts in the deeper subsurface.Here, we show that fluid fluxes from the extraction and injection of fluids associated with oil and gas production and inflow of water into mines likely exceed background flow rates in deep (>500 m) groundwater systems at a global scale.Projected carbon capture and sequestration (CCS), geothermal energy production, and lithium extraction to facilitate the energy transition will require fluid production rates exceeding current oil and co-produced water extraction.Natural analogs and geochemical modeling indicate that

Wastewater Detection of Emerging Vector-Borne Diseases: West Nile Virus in Oklahoma

SSRN Electronic Journal · 2024-01-01 · 4 citations