Energy-efficient sludge sonication: power and sludge characteristics

This paper improves the energy efficiency for sludge treatment using ultrasound. The sludge organic content, solid concentration, ultrasonic intensity, and time were optimized. A new index, kWh/kgSCOD-increase, was used to evaluate the energy efficiency that covers both sludge characteristics and lysis effectiveness. The results showed that the energy efficiency of sludge sonication was in the range of 102-347kWh/kgSCOD-increase. Higher VS/TS ratio gave higher energy efficiency. Optimal solid concentration (TS) was found to be 20g/L; low TS (5.0g/L) consumed 137% more energy; while higher TS might assimilate the sound energy and decrease the efficiency. The cavitation threshold for sludge was 20-30W/cm(2), below which no sludge lysis was observed. The lowest effective sound intensity (31.4W/cm(2)) was best and saved 20-35% energy compared to higher intensities. The initial first minutes of sonication were most effective; hence intensive-short treatment was preferred.     

Feasibility assay in phase-separated anaerobic treatment of cheese industry wastewater

This research was conducted as a part of continuous development of innovative bioprocess technology for the treatment of high strength wastewater. Mixed cheese processing wastewater was tested for the feasibility of phase separated anaerobic digestion in batch mode. Three concentrations of soluble chemical oxygen demand (SCOD) made by dilution of raw wastewater were tested for acidification of organics in the wastewater at two pHs, 6.0 and neutral. More than 95% of fat, 97% of soluble protein and 100% of lactose in the mixed waste were acidified in the acidogenic phase. Three different concentrations of artificial substrate consisting of a mixture of short chain organic acids, acetic, propionic, butyric, and valeric acids, along with alcohol were investigated for waste stabilization in methanogenic phase experiments. More than 95% of SCOD reduction was achieved in the methanogenic phase. This translated that 73.5–83.8% of organics in the wastewater could be recovered as energy (methane gas) instead of massive production of sludge.     

Using acoustic cavitation to improve the bio-activity of activated sludge

This paper studied a new method to improve the microbial activity of the activated sludge for wastewater treatment. Concentrated sludge was sonicated in an extra chamber for short period and then returned to the activated sludge system. The results showed that the bio-activity of the activated sludge, expressed as oxygen utilization rate (OUR), could be enhanced by ultrasonic irradiation. Powerful ultrasound (in the magnitude of W/ml) was much more effective than weak ultrasound (in the magnitude of W/L) in stimulating the activated sludge, but too strong sonication (power density higher than 0.5 W/ml) disintegrated the sludge and thus decreased the sludge activity. Low frequency (25 kHz) was more effective than higher ones (80 kHz and 150 kHz), indicating that mechanical effects, instead of free radicals, were responsible for the bio-activity enhancement. The optimal sonication conditions were sound frequency of 25 kHz, power density of 0.2 W/ml and duration of 30s; under which the sludge OUR increased by 28%, the bio-mass growth rate increased by 12.5%, and the wastewater chemical oxygen demand (COD) and total nitrogen removal efficiency increased by 5-6%.     

Modeling of the inactivation of Salmonella typhimurium by supercritical carbon dioxide in physiological saline and phosphate-buffered saline

In this study, we used supercritical carbon dioxide (SC-CO(2)) to inactivate Salmonella typhimurium suspended in physiological saline (PS) or phosphate-buffered saline (PBS). The colony forming activity of S. typhimurium was completely lost (i.e., 8-log reduction) under the following condition ranges: pressures of 80-150 bar, temperatures of 35-45 degrees C and 10-50 min treatment times. The microbial inactivation process had three distinct phases and was modeled by the modified Gompertz model. Generally, an increase in pressure at constant temperature, and an increase in temperature at a constant pressure, both enhanced S. typhimurium inactivation. When the cells were suspended in PBS rather than PS, the length of time for the complete inactivation significantly increased. We observed the surface and internal morphological changes of the cells by SEM and TEM, respectively. The extraction of proteinous substances, nucleic acids and outer membrane proteins into the suspension during SC-CO(2) treatment was also observed. Through SDS-PAGE analysis of the total proteins and major outer membrane proteins (OMPs) of SC-CO(2)-treated cells, we found that a substantial amount of the total soluble proteins had converted into insoluble protein.     

Possible site-specific reagent for the general amino acid transport system of Saccharomyces cerevisiae.

The general amino acid transport system of Saccharomyces cerevisiae functions in the uptake of neutral, basic, and acidic amino acids. The amino acid analogue N-delta-chloroacetyl-L-ornithine (NCAO) has been tested as potential site specific reagent for this system. L-Tryptophan, which is transported exclusively by the general transport system, was used as a substrate. In the presence of glucose as an energy source, NCAO inhibited tryptophan transport competitively (Ki = 80 micrometer) during short time intervals (1-2 min), but adding 100 micrometer NCAO to a yeast cell suspension resulted in a time-dependent activation of tryptophan transport during the first 15 min of treatment. Following the activation a time-dependent decay of tryptophan transport activity occurred. Approximately 80% inactivation of the system was observed after 90 min. When a yeast cell suspension was treated with NCAO in the absence of an energy source, an 80% inactivation of tryptophan transport occurred in 90 min. The inactivation was noncompetitive (Ki congruent to 60 micrometer) and could not be reversed by the removal of the NCAO. Addition of a five-fold excess of L-lysine during NCAO treatment or prevented inactivation of tryptophan transport. Under parallel conditions of incubation, other closely related transport systems were not inhibited by NCAO.     

RNA removal from Candida utilis by chemical and thermal treatments

The removal of the content of nucleic acids of fodder yeast (Candida utilis) by treatment with HCl or heat shock was investigated Acid concentrations between 5 and 15% (on dried matter basis) were used. A maximal removal of the content of nucleic acids of 88% was realized wheńn was worked with 15% HCl, 90 °C during 30 minutes. But under this conditions were observed high demanges of protein and also of some essential amino acids Good results for diminishing the content of nucleic acids were reached with the highest concentration of acid and a treatment during 20 minutes The experiments with heat shock were carried out at 68 °C, different times for heating and different contents of yeast In this way better results than for treatment with acid according to diminishing the content of nucleic acids and yield of protein and essential amino acids were reached A removal of over 80% of the content of nucleic acids was achieved in all cases.     

The inactivation of enzymes by ultrasonic cavitation at 20 kHz

Alcohol dehydrogenase, lysozyme, and catalase were assayed after exposure to cavitating 20 kHz ultrasound for varying times. Catalase was little affected, but alcohol dehydrogenase and lysozyme were both inactivated at an exponential rate. The rate of enzyme inactivation decreased with increasing protein concentration and was inhibited by the presence of 2-mercaptoethanol. The presence of stainless steel in the sonication vessel accelerated enzyme inactivation. On the basis of the results obtained, it is suggested that the mechanism of inactivation is chemical rather than mechanical, and a comparison is made between the rate of inactivation and the yield of free radicals as measured with a radiochemical dosimeter. Suggestions are offered to minimize the sonochemical effects on proteins isolated from cells with an ultrasonic disintegrator.     

Heat inactivation of poliovirus in wastewater sludge.

The effect of raw and anaerobically digested sludge on heat inactivation of poliovirus was investigated. Raw sludge was found to be very protective of poliovirus plaque-forming ability at all temperatures studied, but digested sludge had variable effects that were highly dependent upon the experimental conditions. In low concentrations and at relatively low inactivation temperatures, digested sludge is nearly as protective of poliovirus as raw sludge. However, at higher tempeatures and concentrations, digested sludge caused a significant acceleration of poliovirus inactivation. The difference between the protective capability of raw and digested sludge is not due to loss of protective material, because this component is present in the solids of digested sludge as well as in those of raw sludge. Instead, the difference is due to a virucidal agent acquired during digestion. Addition of this agent to the solids of either raw or digested sludge reverses the protective potential of these solids during heat treatment of poliovirus.     

Heat inactivation of poliovirus in wastewater sludge.

The effect of raw and anaerobically digested sludge on heat inactivation of poliovirus was investigated. Raw sludge was found to be very protective of poliovirus plaque-forming ability at all temperatures studied, but digested sludge had variable effects that were highly dependent upon the experimental conditions. In low concentrations and at relatively low inactivation temperatures, digested sludge is nearly as protective of poliovirus as raw sludge. However, at higher tempeatures and concentrations, digested sludge caused a significant acceleration of poliovirus inactivation. The difference between the protective capability of raw and digested sludge is not due to loss of protective material, because this component is present in the solids of digested sludge as well as in those of raw sludge. Instead, the difference is due to a virucidal agent acquired during digestion. Addition of this agent to the solids of either raw or digested sludge reverses the protective potential of these solids during heat treatment of poliovirus.     

Development of mechanistically based model for simulating soluble microbial products generation in an aerated/non-aerated SBR

Soluble microbial products (SMPs) are considered as the main organic components in wastewater treatment plant effluent from biological wastewater treatment systems. To investigate and explore SMP metabolism pathway for further treatment and control, two innovative mechanistically based activated sludge models were developed by extension of activated sludge model no.3 (ASM3). One was the model by combining SMP formation and degradation (ASM3-SMP model) processes with ASM3, and the other by combining both SMP and simultaneous substrate storage and growth (SSSG) mechanisms with ASM3 (SSSG-ASM3-SMP model). The detailed schematic modification and process supplements were introduced for comprehensively understanding all the mechanisms involved in the activated sludge process. The evaluations of these two models were demonstrated by a laboratory-scale sequencing batch reactor (SBR) operated under aerated/non-aerated conditions. The simulated and measured results indicated that SMP comprised about 83% of total soluble chemical oxygen demand (SCOD) in which biomass-associated products (BAPs) were predominant compared with utilization-associated products (UAPs). It also elucidated that there should be a minimum SMP value as the reactive time increases continuously and this conclusion could be used to optimize effluent SCOD in activated sludge processes. The comparative results among ASM3, ASM3-SMP and SSSG-ASM3-SMP models and the experimental measurements (SCOD, ammonia and nitrate nitrogen) showed clearly the best agreement with SSSG-ASM3-SMP simulation values (R = 0.993), strongly suggesting that both SMP formation and degradation and SSSG mechanisms are necessary in biologically activated sludge modeling for municipal wastewater treatment.     

Modeling Analysis on Germination and Seedling Growth Using Ultrasound Seed Pretreatment in Switchgrass

Switchgrass is a perennial C4 plant with great potential as a bioenergy source and, thus, a high demand for establishment from seed. This research investigated the effects of ultrasound treatment on germination and seedling growth in switchgrass. Using an orthogonal matrix design, conditions for the ultrasound pretreatment in switchgrass seed, including sonication time (factor A), sonication temperature (factor B) and ultrasound output power (factor C), were optimized for germinating and stimulating seedling growth (indicated as plumular and radicular lengths) through modeling analysis. The results indicate that sonication temperature (B) was the most effective factor for germination, whereas output power (C) had the largest effect on seedling growth when ultrasound treatment was used. Combined with the analyses of range, variance and models, the final optimal ultrasonic treatment conditions were sonication for 22.5 min at 39.7°C and at an output power of 348 W, which provided the greatest germination percentage and best seedling growth. For this study, the orthogonal matrix design was an efficient method for optimizing the conditions of ultrasound seed treatment on switchgrass. The electrical conductivity of seed leachates in three experimental groups (control, soaked in water only, and ultrasound treatment) was determined to investigate the effects of ultrasound on seeds and eliminate the effect of water in the ultrasound treatments. The results showed that the electrical conductivity of seed leachates during either ultrasound treatment or water bath treatment was significantly higher than that of the control, and that the ultrasound treatment had positive effects on switchgrass seeds.     

The effect of volatile fatty acids on the inactivation of <Emphasis Type="Italic">Clostridium perfringens</Emphasis> in anaerobic digestion

The application of sludge digestion systems to remove pathogens has been employed to generate biosolids suitable for reuse in agriculture. Traditionally, temperature is considered the principal agent responsible for pathogen reduction in anaerobic digestion. However, other substances such as volatile fatty acids may also have an antimicrobial effect. The objective of this study was to assess the impact of fatty acid mixtures on the inactivation of C. perfringens over a range of digestion temperatures. An equimolar mixture of acetic acid, propionic acid and butyric acid was applied to digester effluent for a period of 24 h at temperatures of 35 °C, 42 °C, 49 °C and 55 °C. C. perfringens inactivation in digester effluents, when dosed with volatile organic acids, was found to depend on pH, acid concentration and temperature. Temperatures above 55 °C appeared to increase the inhibitory effects of the organic acids at higher concentrations. An interaction between temperature and pH on survival of C. perfringens was observed. The results suggest that high concentrations of organic acids at a pH value of 4.5–5.5 during thermophilic digestion substantially reduce concentrations of C. perfringens in municipal sludge.     

声化学诱导艾氏腹水瘤细胞凋亡机制初探

本研究采用频率1.43MHz,声强3W/cm2的高频聚焦超声处理艾氏腹水肿瘤细胞,研究超声激活血卟啉诱导艾氏腹水肿瘤细胞凋亡的途径及其与癌细胞内的氧自由基之间的关系。通过细胞免疫组织化学方法检测与癌细胞凋亡相关的Bax,细胞色素c和caspase-3蛋白的动态表达,黄嘌呤氧化酶法检测超氧化物歧化酶活性变化,硫代巴比妥酸法检测膜脂质过氧化物的含量。结果发现超声加血卟啉处理1h,癌细胞胞浆中的三种促凋亡蛋白表达增多,3h时表现为高表达;处理1h的癌细胞,超氧化物歧化酶活性下降,膜脂质过氧化物增多。研究结果表明超声激活血卟啉诱导艾氏腹水肿瘤细胞凋亡可能通过线粒体途径,且与癌细胞受损后产生的氧自由基有关。     

Soni-removal of nucleic acids from inclusion bodies

Inclusion bodies (IBs) are commonly formed in Escherichiacoli due to over expression of recombinant proteins in non-native state. Isolation, denaturation and refolding of these IBs is generally performed to obtain functional protein. However, during this process IBs tend to form non-specific interactions with sheared nucleic acids from the genome, thus getting carried over into downstream processes. This may hinder the refolding of IBs into their native state. To circumvent this, we demonstrate a methodology termed soni-removal which involves disruption of nucleic acid–inclusion body interaction using sonication; followed by solvent based separation. As opposed to conventional techniques that use enzymes and column-based separations, soni-removal is a cost effective alternative for complete elimination of buried and/or strongly bound short nucleic acid contaminants from IBs.     

Inactivation of Ascaris suum by short-chain fatty acids

Ascaris suum eggs were inactivated in distilled water and digested sludge by butanoic, pentanoic, and hexanoic acids. The fatty acids (short-chain fatty acids [SCFA]) were effective only when protonated and at sufficient concentrations. The conjugate bases were not effective at the concentrations evaluated. Predictions from an inhibition model (50% inhibitory concentration [IC(50)]) based on quantitative structure-activity relationships were congruent with inactivation data.     

Inactivation of the human thyroid peroxidase by ultrasound cavitation]

The inactivation kinetics of a human thyroid peroxidase protein fraction upon sonication (ultrasound frequency 27 kHz, power 60 W/cm2) of the enzyme solution in 15 mM phosphate buffer, pH 7.5, was studied. To quantitatively characterize the dependence of the slowest stage of the human thyroid peroxidase inactivation on temperature (36.0-50.4) degrees C, an effective constant of ultrasound inactivation rate Kin(US) was used. From the temperature dependence of Kin(US) at temperatures below 43 degrees C, the activation energy was estimated to be 8.11 kcal/mol. It was shown that the rate of human thyroid peroxidase inactivation strongly depends on the concentration of total protein in solution: the kin(US) value decreases more than sixfold in the protein concentration range from 0.2 to 0.8 mg/ml. It was also shown that poly(2-aminodisulfide-4-nitrophenol), its complexes with human serum albumin as well as the complexes human serum albumin--poly(gallic acid disulfide) substantially inhibit the ultrasound-induced inactivation of the enzyme and can be its effective stabilizers in the ultrasound cavitation field. This confirms the suggestion that active free radicals HO., O2.- and HO2. play a key role in the inactivation of human thyroid peroxidase. A general scheme of the inactivation of human thyroid peroxidase is proposed, which represents a chain of successive and parallel reversible and irreversible elementary steps.     

Biosynthesis of proteins, nucleic acids and glycosphingolipids by synchronized KB cells

The biosynthesis of glycosphingolipids and various types of proteins and nucleic acids at specific periods of the cell cycle was studied by using synchronized KB cells. Maximum incorporation of radioactive galactose, leucine and thymidine into several proteins and nucleic acids occurred as has been reported previously (6,11). Maximum incorporation of $\text{D}$-1[¹⁴C] galactose into glycosphingolipids was observed during the M and G-1 phases. There was a 5 fold increase in the levels of gangliosides and combined neutral glycosphingolipids during the M and G-1 phases. Thus, regulated biosynthesis of glycosphingolipids and macromolecules might be important in the cyclic expression of some of the functional properties which are characteristic of these compounds.     

Glycine and alanine synthesis from formaldehyde and hydroxylamine in the field of ultrasound waves

High intensity ultrasound waves coupled with other form of energy obviously were initiators of pre-biochemical reactions; these reactions occurred in the water masses of the primordial Earth.Essential biological substances like formaldehyde, ammonia, hydrocyanic acid, and amino acids compounds similar to carbohydrates by their properties were synthesized in the field of ultrasound waves in model experiments.The main partners of these reactions are water and gases of reductional atmosphere: hydrogen, carbon monoxide, methane, nitrogen and argon.Formation of amino acids takes place in aqueous solutions of formaldehyde and hydroxylamine. The sonication yielded alanine and glycine, 2.0×10^–7 and 1.8×10^–7 molecules per 100 eV respectively.     

Laboratory-scale ultrasound pre-treated digestion of sludge: Heat and energy balance

The objective of this work was to maximize the digestibility of biological sludge to elucidate the feasibility of a new sludge management strategy to recover good quality sludge for agricultural use. The combined effects of organic loading rates (from 0.7 to 2.8 g VS L⁻¹ d⁻¹) and the degree of disintegration by anaerobic digestion of sonicated activated sludge were discussed, and the thermal and energetic balances were evaluated. Despite low sonication inputs, sludge digestion performance improved in terms of solids degradation and biogas production depending on the soluble organic load. The biogas production by sonicated sludge was higher (up to 30%) with respect to the control. Filterability improved during digestion of sonicated sludge at medium OLR due to a significant abatement of the fines. Thermal balances indicated that sonication may be a proper system to guarantee self-sustaining WAS mesophilic digestion. Nevertheless, thickening is a pre-requisite to achieve a positive energy balance.     

Inactivation of Viruses and Bacteria by Ozone, With and Without Sonication

Selected organisms with public health significance were placed in a reaction chamber for treatment by ozonation, by ozonation and sonication, by sonication, or by sonication during oxygenation. Vesicular stomatitis virus, encephalomyocarditis virus, GDVII virus, Staphylococcus aureus, Pseudomonas fluorescens, Salmonella typhimurium, enteropathogenic Escherichia coli, Vibrio cholerae, and Shigella flexneri were inactivated by treatment with ozone. When microorganisms were suspended in phosphate-buffered saline, they were inactivated rapidly by treatment with ozone. However, microorganisms suspended in secondary effluent from a wastewater treatment plant required longer contact times with ozone for complete inactivation. Simultaneous treatments by ozonation and sonication reduced the contact time for complete inactivation of microorganisms in secondary effluent. Treatment by sonication alone or sonication and oxygenation did not inactivate microorganisms. Therefore, the simultaneous treatment of microorganisms in secondary effluent with ozone and sonication resulted in a synergistic effect.