Contributions of Nanoscale Roughness to Anomalous Colloid Retention and Stability Behavior

Bradford, Scott A.; Kim, Hyun-Jung; Shen, Chongyang; Sasidharan, Salini; Shang, Jianying

doi:10.1021/acs.langmuir.7b02445

Cited by 98 publications

(99 citation statements)

References 54 publications

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“…Similar stabilization behavior has been reported for other macromolecules including polaxamers and poloxamines 290 [42,43,44], poly(ethylene glycol) (PEG) [48], and methoxy poly(ethylene glycol) (mPEG) [49,50]. This stability enhancement resulting from macromolecule adsorption is commonly attributed to electrosteric repulsion, though a recent study by Bradford et al [51] found that nanoscale roughness could also explain this behavior. This result is a key advantage for use in environmental systems 295 where the ionic content of natural waters can lead to aggregation and therefore modified transport characteristics.…”

supporting

confidence: 64%

Fabrication, detection, and analysis of DNA-labeled PLGA particles for environmental transport studies

McNew

Wang

Walter

et al. 2018

Journal of Colloid and Interface Science

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Poly(lactic-co-glycolic acid) (PLGA) particle carriers of synthetic DNA have recently received increased attention for environmental applications due to their biodegradability, customizability, and nearly limitless number of uniquely identifiable "labels". In this paper, we present methodologies for the preparation of DNA-labeled particles, control of particle size, extraction of DNA-labels, and analysis via quantitative polymerase chain reaction (qPCR). Characterization and analysis of the DNA-labeled particles reveal spherical particles of diameters ranging from 60 to 1000 nm, with consistent zeta potentials around -45 mV, that are stable to aggregation, even in the presence of concentrated mono- and divalent cations. A highly correlated and consistent relationship between particle concentration and DNA-label count was observed, with a detection range spanning 7 orders of magnitude, from 0.01 to 10,000 mg/L (10-10 particles/μL). The results of two environmental applications of the DNA-labeled particles are also presented, highlighting their feasibility for use in environmental studies. Whether exploring size-dependent transport phenomena or identifying potential pathogen transport pathways, the DNA-labeled particle approach presented here provides a powerful tool for the identification of overlapping particle signals at a range of concentrations.

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supporting

confidence: 64%

Fabrication, detection, and analysis of DNA-labeled PLGA particles for environmental transport studies

McNew

Wang

Walter

et al. 2018

Journal of Colloid and Interface Science

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“…The presence of some forms of hydrophobic organic matter in the solution (Table S1) and the sediment surface may enhance the hydrophobic interaction between the partially hydrophobic viruses (PRD1 and MS2), which lead to their higher retention. In addition, nanoscale chemical and especially physical heterogeneity on the surfaces of colloids are known to strongly influence their adhesive interaction (Attinti et al, 2010;Bradford et al, 2017). The viral protein coat may contain weakly acidic and basic amino acid groups which act as localized positive and negative charges (Gerba, 1984) and it has a span of hydrophobic amino acids which will determine the hydrophobicity of viruses (Bendersky and Davis, 2011;Bradford and Torkzaban, 2012;Shen, et al, 2012d).…”

Section: Virus Retention Under Various Physicochemical Conditionsmentioning

confidence: 99%

“…Natural solid surfaces like sand grains always contain a wide distribution of physical (e.g., roughness) or chemical (e.g., metal oxides) heterogeneities (Bhattacharjee et al, 1998;Shen et al, 2012c). Previous studies have demonstrated that roughness height and fraction, and positive zeta potential and fraction, at a specific location on the collector (sand) surface can significantly reduce the magnitude of the energy barrier to attachment and the depth of the primary minimum for viruses (Bradford et al, 2017;Torkzaban, 2013, 2015;Sasidharan et al, 2017b;Torkzaban and Bradford, 2016). In contrast to smooth latex nanoparticles, the virus exhibits chemical (e.g., lipid membrane and protein coat) (Meder et al, 2013) and physical heterogeneity (e.g., spikes and tail) (Huiskonen et al, 2007;Kazumori, 1981) on their surface.…”

Section: Mathematical Modeling Of Virus Retentionmentioning

confidence: 99%

Transport and fate of viruses in sediment and stormwater from a Managed Aquifer Recharge site

Sasidharan

Bradford

Šimůnek

et al. 2017

Journal of Hydrology

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a b s t r a c tEnteric viruses are one of the major concerns in water reclamation and reuse at Managed Aquifer Recharge (MAR) sites. In this study, the transport and fate of bacteriophages MS2, PRD1, and UX174 were studied in sediment and stormwater (SW) collected from a MAR site in Parafield, Australia. Column experiments were conducted using SW, stormwater in equilibrium with the aquifer sediment (EQ-SW), and two pore-water velocities (1 and 5 m day À1 ) to encompass expected behavior at the MAR site. The aquifer sediment removed >92.3% of these viruses under all of the considered MAR conditions. However, much greater virus removal (4.6 logs) occurred at the lower pore-water velocity and in EQ-SW that had a higher ionic strength and Ca 2+ concentration. Virus removal was greatest for MS2, followed by PRD1, and then UX174 for a given physicochemical condition. The vast majority of the attached viruses were irreversibly attached or inactivated on the solid phase, and injection of Milli-Q water or beef extract at pH = 10 only mobilized a small fraction of attached viruses (<0.64%). Virus breakthrough curves (BTCs) were successfully simulated using an advective-dispersive model that accounted for rates of attachment (k att ), detachment (k det ), irreversible attachment or solid phase inactivation (l s ), and blocking. Existing MAR guidelines only consider the removal of viruses via liquid phase inactivation (l l ). However, our results indicated that k att > l s > k det > l l , and k att was several orders of magnitude greater than l l . Therefore, current microbial risk assessment methods in the MAR guideline may be overly conservative in some instances. Interestingly, virus BTCs exhibited blocking behavior and the calculated solid surface area that contributed to the attachment was very small. Additional research is therefore warranted to study the potential influence of blocking on virus transport and potential implications for MAR guidelines.

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“…This could be explained by the difference in adhesive strength of the viruses at a specific attachment location. Previous studies demonstrated that the presence of nanoscale roughness and chemical heterogeneity on sand (Han et al, 2016; Choo et al, 2015) and virus (Kazumori, 1981; McKenna et al, 1992; Merckel et al, 2005; Peralta et al, 2013) are expected to reduce the magnitude of the energy barrier to attachment/detachment and the depth of the primary minimum (Bradford et al, 2017; Bradford and Torkzaban, 2013, 2015; Torkzaban and Bradford, 2016). The observation of low rates of virus detachment (Table 1) is consistent with slow, diffusion‐controlled, virus release from a primary minimum with a low probability of release (e.g., the energy barrier to detachment of 5 to 10 kT) (Bradford et al, 2017).…”

Section: Resultsmentioning

confidence: 99%

“…For example, irreversible virus attachment may occur at smooth surfaces with chemical heterogeneity due to the presence of deep primary minimum, whereas reversible virus interaction was expected on rough surfaces due to the presence of a shallow primary minimum (Bradford et al, 2017; Bradford and Torkzaban, 2012). This implies that only a very small fraction of the solid surface may contribute to irreversible virus attachment in a deep primary minimum since nanoscale roughness is ubiquitous on solid and virus surfaces (Bradford et al, 2017; Bradford and Torkzaban, 2015). These findings are consistent with the small values of α (0.028 – 0.081) and S f (8.5 × 10 −7 –7.8 × 10 −9 ) shown in Table 1, and the observed blocking behavior for both viruses in the BTCs (Fig.…”

Section: Resultsmentioning

confidence: 99%

Minimizing Virus Transport in Porous Media by Optimizing Solid Phase Inactivation

et al. 2018

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The influence of virus type (PRD1 and ΦX174), temperature (flow at 4 and 20°C), a no‐flow storage duration (0, 36, 46, and 70 d), and temperature cycling (flow at 20°C and storage at 4°C) on virus transport and fate were investigated in saturated sand‐packed columns. The vast majority (84–99.5%) of viruses were irreversibly retained on the sand, even in the presence of deionized water and beef extract at pH = 11. The reversibly retained virus fraction (fr) was small (1.6 × 10−5 to 0.047) but poses a risk of long‐term virus contamination. The value of fr and associated transport risk was lower at a higher temperature and for increases in the no‐flow storage period due to the temperature dependency of the solid phase inactivation. A model that considered advective–dispersive transport, attachment (katt), detachment (kdet), solid phase inactivation (μs), and liquid phase inactivation (μl) coefficients, and a Langmuirian blocking function provided a good description of the early portion of the breakthrough curve. The removal parameters were found to be in the order of katt > μs >> μl. Furthermore, μs was an order of magnitude higher than μl for PRD1, whereas μs was two and three orders of magnitude higher than μl for ΦX174 at 4 and 20°C, respectively. Transport modeling with two retention, release, and inactivation sites demonstrated that a small fraction of viruses exhibited a much slower release and solid phase inactivation rate, presumably because variations in the sand and virus surface roughness caused differences in the strength of adhesion. These findings demonstrate the importance of solid phase inactivation, temperature, and storage periods in eliminating virus transport in porous media. This research has potential implications for managed aquifer recharge applications and guidelines to enhance the virus removal by controlling the temperature and aquifer residence time. Solid phase inactivation is 2–3 orders of magnitude higher than liquid phase inactivation. Solid phase inactivation increases with temperature and column storage duration. The solid phase inactivation was higher for ΦX174 than PRD1. Solid phase inactivation reduced the reversible virus fraction by 1 to 2 orders of magnitude.

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Contributions of Nanoscale Roughness to Anomalous Colloid Retention and Stability Behavior

Cited by 98 publications

References 54 publications

Fabrication, detection, and analysis of DNA-labeled PLGA particles for environmental transport studies

Fabrication, detection, and analysis of DNA-labeled PLGA particles for environmental transport studies

Transport and fate of viruses in sediment and stormwater from a Managed Aquifer Recharge site

Minimizing Virus Transport in Porous Media by Optimizing Solid Phase Inactivation

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