Don E. Langworthy scite author profile

Don E. Langworthy

4Publications

108Citation Statements Received

62Citation Statements Given

How they've been cited

170

How they cite others

Affiliations

Procter & Gamble (United States), University Medical Center Groningen, Freeman Hospital

Publications

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Evaluation of a new water treatment for point-of-use household applications to remove microorganisms and arsenic from drinking water

Souter

Cruickshank

Tankerville

et al. 2003

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Contamination of drinking water by microorganisms and arsenic represents a major human health hazard in many parts of the world. An estimated 3.4 million deaths a year are attributable to waterborne diseases. Arsenic poisoning from contaminated water sources is causing a major health emergency in some countries such as Bangladesh where 35 to 77 million people are at risk. The World Health Organization (WHO) has recently recognized point-of-use water treatment as an effective means of reducing illness in developing country households. A new point-of-use water treatment system that is based on flocculation, sedimentation and disinfection was evaluated for the removal of bacterial, viral and parasitic pathogens as well as arsenic from drinking water to estimate its potential for use in developing countries. Tests were conducted with United States Environmental Protection Agency (EPA)-model and field- sample waters from developing countries. Samples were seeded with known numbers of organisms, treated with the combined flocculation/disinfection product, and assayed for survivors using standard assay techniques appropriate for the organism. Results indicated that this treatment system reduced the levels from 10(8)/l to undetectable (<1) of 14 types of representative waterborne bacterial pathogens including Salmonella typhi and Vibrio cholerae. No Escherichia coli were detected post-treatment in 320 field water samples collected from five developing countries. In addition, the water treatment system reduced polio and rotavirus titres by greater than 4-log values. Cyrptosporidium parvum and Giardia lamblia inocula were reduced by greater than 3-log values following use of this water treatment system. Arsenic, added to laboratory test waters, was reduced by 99.8%, and naturally occurring arsenic in field samples from highly contaminated Bangladeshi wells was reduced by 99.5% to mean levels of 1.2 microg/l. This water treatment system has demonstrated the potential to provide improved drinking water to households in developing countries by removing microbial and arsenic contaminants.

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Adhesion and viability of waterborne pathogens on p‐DADMAC coatings

Mei

Rustema-Abbing

Langworthy

et al. 2007

Biotech & Bioengineering

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The attachment of waterborne pathogens onto surfaces can be increased by coating the surfaces with positive charge-enhancing polymers. In this paper, the increased efficacy of polydiallyldimethylammonium chloride (p-DADMAC) coatings on glass was evaluated in a parallel plate flow chamber with the use of waterborne pathogens (Raoultella terrigena, Escherichia coli, and Brevundimonas diminuta). p-DADMAC coatings strongly compensated the highly negative charges on the glass surface and even yielded a positively charged surface when applied from a 500 ppm solution. Whereas none of the strains adhered from water to glass due to electrostatic repulsion, R. terrigena and E. coli readily adhered in high numbers to p-DADMAC coated glass slides applied from 1, 100, or 500 ppm aqueous solutions. B. diminuta only adhered to a positively charged p-DADMAC coating applied from a 500 ppm solution. In addition, all p-DADMAC coatings indicated strong contact killing with the bacterial species used in this study by live/dead staining techniques. In summary, this paper demonstrates the potential of p-DADMAC coatings to strongly enhance bacterial adhesion. Moreover, once adhered, bacterial viability can be reduced by the positively charged ammonium groups in the coating.

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Removal of Two Waterborne Pathogenic Bacterial Strains by Activated Carbon Particles Prior to and after Charge Modification

Busscher¹,

Dijkstra

Engels

et al. 2006

Environ. Sci. Technol.

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Waterborne diseases constitute a threat to public health despite costly treatment measures aimed at removing pathogenic microorganisms from potable water supplies. This paper compared the removal of Raoultella terrigena ATCC 33257 and Escherichia coli ATCC 25922 by negatively and positively charged types of activated carbon particles. Both strains display bimodal negative zeta-potential distributions in stabilized water. Carbon particles were suspended to an equivalent external geometric surface area of 700 cm2 in 250 mL of a bacterial suspension, with shaking. Samples were taken after different durations for plate counting. Initial removal rates were less elevated for the positively charged carbon particle than expected, yielding the conclusion that bacterial adhesion under shaking is mass-transport limited. After 360 min, however, the log-reduction of the more negatively charged R. terrigena in suspension was largest for the positively charged carbon particles as compared with the negatively charged ones, although conditioning in ultrapure or tap water of positively charged carbon particles for 21 days eliminated the favorable effect of the positive charge due to counterion adsorption from the water. Removal of the less negatively charged E. coli was less affected by aging of the (positively charged) carbon particles, confirming the role of electrostatic interactions in bacterial removal by activated carbon particles. The microporous, negatively charged coconut carbon performed less than the mesoporous, positively charged carbon particle prior to conditioning but did not suffer from loss of effect after conditioning in ultrapure or tap water.

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Interaction forces between waterborne bacteria and activated carbon particles

Busscher

Dijkstra

Langworthy

et al. 2008

Journal of Colloid and Interface Science

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Don E. Langworthy

Evaluation of a new water treatment for point-of-use household applications to remove microorganisms and arsenic from drinking water

Adhesion and viability of waterborne pathogens on p‐DADMAC coatings

Removal of Two Waterborne Pathogenic Bacterial Strains by Activated Carbon Particles Prior to and after Charge Modification

Interaction forces between waterborne bacteria and activated carbon particles

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