In this study, a two-dimensional "double-horizon peridynamics" formulation was presented for membranes. According to double-horizon peridynamics, each material point has two horizons: inner and outer horizons. This new formulation can reduce the computational time by using larger horizons and smaller inner horizons. To demonstrate the capability of the proposed formulation, various different analytical and numerical solutions were presented for a rectangular plate under different boundary conditions for static and dynamic problems. A comparison of peridynamic and classical solutions was given for different inner and outer horizon size values.
Citation: Zhenghao Yang, Erkan Oterkus, Selda Oterkus. Two-dimensional double horizon peridynamics for membranes[J]. Networks and Heterogeneous Media, 2024, 19(2): 611-633. doi: 10.3934/nhm.2024027
| [1] | Vakhtang V. Dzhavakhiya, Elena V. Glagoleva, Veronika V. Savelyeva, Natalia V. Statsyuk, Maksim I. Kartashov, Tatiana M. Voinova, Alla V. Sergeeva . New bacitracin-resistant nisin-producing strain of Lactococcus lactis and its physiological characterization. AIMS Microbiology, 2018, 4(4): 608-621. doi: 10.3934/microbiol.2018.4.608 |
| [2] | John Samelis, Athanasia Kakouri . Hurdle factors minimizing growth of Listeria monocytogenes while counteracting in situ antilisterial effects of a novel nisin A-producing Lactococcus lactis subsp. cremoris costarter in thermized cheese milks. AIMS Microbiology, 2018, 4(1): 19-41. doi: 10.3934/microbiol.2018.1.19 |
| [3] | Natalia Y. Kovalskaya, Eleanor E. Herndon, Juli A. Foster-Frey, David M. Donovan, Rosemarie W. Hammond . Antimicrobial activity of bacteriophage derived triple fusion protein against Staphylococcus aureus. AIMS Microbiology, 2019, 5(2): 158-175. doi: 10.3934/microbiol.2019.2.158 |
| [4] | Prateebha Ramroop, Hudaa Neetoo . Antilisterial activity of Cymbopogon citratus on crabsticks. AIMS Microbiology, 2018, 4(1): 67-84. doi: 10.3934/microbiol.2018.1.67 |
| [5] | Joseph O. Falkinham . Mycobacterium avium complex: Adherence as a way of life. AIMS Microbiology, 2018, 4(3): 428-438. doi: 10.3934/microbiol.2018.3.428 |
| [6] | Farzad Rahmati . Characterization of Lactobacillus, Bacillus and Saccharomyces isolated from Iranian traditional dairy products for potential sources of starter cultures. AIMS Microbiology, 2017, 3(4): 815-825. doi: 10.3934/microbiol.2017.4.815 |
| [7] | Yusuke Morita, Mai Okumura, Issay Narumi, Hiromi Nishida . Sensitivity of Deinococcus grandis rodZ deletion mutant to calcium ions results in enhanced spheroplast size. AIMS Microbiology, 2019, 5(2): 176-185. doi: 10.3934/microbiol.2019.2.176 |
| [8] | Alexandra Díez-Méndez, Raul Rivas . Improvement of saffron production using Curtobacterium herbarum as a bioinoculant under greenhouse conditions. AIMS Microbiology, 2017, 3(3): 354-364. doi: 10.3934/microbiol.2017.3.354 |
| [9] | Stephen H. Kasper, Ryan Hart, Magnus Bergkvist, Rabi A. Musah, Nathaniel C. Cady . Zein nanocapsules as a tool for surface passivation, drug delivery and biofilm prevention. AIMS Microbiology, 2016, 2(4): 422-433. doi: 10.3934/microbiol.2016.4.422 |
| [10] | Yunfeng Xu, Attila Nagy, Gary R. Bauchan, Xiaodong Xia, Xiangwu Nou . Enhanced biofilm formation in dual-species culture of Listeria monocytogenes and Ralstonia insidiosa. AIMS Microbiology, 2017, 3(4): 774-783. doi: 10.3934/microbiol.2017.4.774 |
In this study, a two-dimensional "double-horizon peridynamics" formulation was presented for membranes. According to double-horizon peridynamics, each material point has two horizons: inner and outer horizons. This new formulation can reduce the computational time by using larger horizons and smaller inner horizons. To demonstrate the capability of the proposed formulation, various different analytical and numerical solutions were presented for a rectangular plate under different boundary conditions for static and dynamic problems. A comparison of peridynamic and classical solutions was given for different inner and outer horizon size values.
Alicyclobacillus acidoterrestris is a thermoacidophilic, non-pathogenic, rod-shaped, spore-forming bacterium. It has the ability to grow in a wide temperature (25–60 ℃) and pH (2.5–6.0) ranges [1]. ω-alicyclic fatty acids are the major lipid components and provide its resistance to acidic conditions and high temperatures [2]. After fruit juice pasteurization, its spores can germinate into vegetative cells leading to spoilage [3]. Spoilage is difficult to detect visually [4] and has been detected in various pasteurized juice samples such as apple, tomato, white grape, grapefruit, orange, and pineapple juices but not in red grape juices and Cupuaçu [1].
The use of natural antimicrobials in foods inhibits the growth of many microorganisms without health risks to consumers [5]. In the food industry, it is important to determine the effects of non-thermal technologies on microbial inactivation and the growth parameters of the survivors such as the lag phase (λ) and the maximum specific growth rate (μ) [6]. Nisin is a heat stable bacteriocin produced by Lactococcus lactis sub sp. lactis. It shows antibacterial activity against Gram-positive bacteria and spore formers such as Bacillus and Clostridium spp. This antibacterial agent is essentially non-toxic to humans and degraded without causing any damage to the intestinal tract. In the United States, it was approved by the Food and Drug Administration (FDA) and allowed to be used in processed cheeses [7]. In the food industry, it has been used as a natural preservative in processed cheese, milk, dairy products, canned foods, hot baked flour products and pasteurized liquid egg [8]. On the other hand, its use is limited to 15 ppm in meat products by the FDA [9]. Nisin could be added directly to the juices [10,11,12] or incorporated in polymers for controlled release during storage against A. acidoterrestris [13]. Similar to nisin, hen egg white lysozyme has Generally Recognized as Safe (GRAS) status. It has been used as a food preservative in cheeses, cow's milk, beer, fresh fruits and vegetables, fish, meat and wine [8]. Also, lysozyme could inhibit the growth of A. acidoterrestris in solution, incorporated in water-soluble polyvinyl alcohol films or immobilized on polymer films [14]. Due to its safety and high technological stability, it is considered as an ideal food preservative. European Union allergen legistration requires its labeling because of its ability to cause allergies [15].
Temperature is one of the important extrinsic factors that affect the microbial growth and can be easily changed during food processing and storage. Many predictive models have been developed to investigate the growth kinetics under different temperature conditions [16]. To our knowledge, there is no study about the effect of storage temperature on the antimicrobial activities of nisin and lysozyme against A. acidoterrestris in juice. Therefore, the objectives of the present study were to determine the inhibitory effects of nisin and lysozyme against A. acidoterrestris DSM 3922 cells in the apple juice at different storage temperatures (27, 35 and 43 ℃) and finally to estimate the growth kinetic parameters at non-inhibitory doses.
A. acidoterrestris DSM 3922 type strain was kindly provided by Karl Poralla (Deutsche SammLung von Mikroorganismen und Zellkulturen's collection, Braunschweig, Germany). This culture was grown on Bacillus acidoterrestris Agar (pH 4.0, Merck, Germany) for 2 days at 43 ℃, and then stored in 20% glycerol-BAT broth (Döhler, Germany) at –80 ℃ for further analysis.
Concentrated apple juice (70.3° Brix) was kindly provided by ASYA Fruit Juice and Food Ind. Inc. (Isparta, Turkey) and reconstituted to 11.30 °Brix by a refractometer (Mettler Toledo, USA). The presence of Alicyclobacillus spp. contamination in juice samples was determined by membrane filtration method as previously described [17]. The pH of the juice was measured as 3.82 ± 0.01 (Hanna instruments, Hungary).
Lysozyme (≥40, 000 units/mg protein) from hen egg white and nisin from Lactococcus lactis (2.5%, balance sodium chloride and denatured milk solids) were obtained from Sigma Chem. Co. (St Louis, MO, USA).
First, A. acidoterrestris cells were grown overnight on Potato dextrose agar (Difco, BD) at 43 ℃. The colonies were suspended in 10 mL Maximum Recovery Diluent (Oxoid) to obtain a bacterial density of McFarland 1.0 (106 CFU/mL) using a densitometer (Den-1, HVD Life Sciences, Austria). After centrifugation at 16, 000 × g for 5 min, the pellet was dissolved in 10 mL apple juice. Then, 180 μL juice containing antimicrobial (nisin 0–100 IU/mL or lysozyme, 0–100 mg/L) and 20 μL of the bacterial suspension were added into the wells of a flat bottom 96-well plate in duplicates (Corning Costar) for each temperature tested. The plates were incubated individually at 27, 35 or 43 ℃ in a microplate reader (Varioskan® Flash, Thermo, Finland). Inoculated apple juice without antimicrobials was used as control. Absorbance of the well contents was determined at 600 nm. The averages of absorbance values versus time were plotted to form growth curves. The MIC was defined as the lowest concentration required for the inhibition. Experimental growth data were fitted to the Baranyi growth model [18] in DMFit Version 2.1 software (Institute of Food Research, Norwick, UK) to estimate the growth parameters at non-inhibitory doses.
The mean values and standard deviations were calculated by Excel (Microsoft Corp., USA). The fitting of the model to the experimental data was determined by coefficient of determination (R2) calculated by the DMFit 2.1 program. The higher R2 values provide better prediction by the fitted model [18].
Growth inhibition of A. acidoterrestris in apple juice with nisin was independent on storage temperature. MICs were found as 10 IU/mL nisin under all conditions. Since nisin has great stability at high temperatures and low pH, especially at the range of pH 3–4, it has been used to inhibit or control the growth of A. acidoterrestris in highly acidic drinks [11]. The antimicrobial activity of nisin depends on food environment factors such as pH, lipid content, particle size, storage time, and structural uniformity [19]. During storage, antibacterial activity of nisin is increased in high pH foods and at high temperatures [20]. In the related literature, different MIC values have been reported for Alicyclobacillus spp. This may be due to nisin concentration, the characteristics of juice or medium and the tested species [21]. The MICs of nisin were also found lower than those of other studies but it is difficult to compare the obtained results with previous studies because of the use of different organisms, growth and incubation conditions [21].
In another study, Yamazaki et al. (2000) concluded that nisin has inhibitory effect in unclear commercial juices and no effect in clear drinks. They suggested that nisin may bind polyphenols present in unclear juices and growth may be inhibited because of the binding of nisin to some particles present in the unclear apple juice and the synergism between the polyphenols and nisin. In a previous study, cell growth was completely inhibited in the presence of 100 IU/mL nisin in grapefruit, apple and orange juices at 43 ℃ [10]. According to Yamazaki et al. (2000), cell growth was inhibited on agar plates by 1.56 to 25 IU/mL and 25 to 100 IU/mL at pH 3.4 and 4.2, respectively during incubation at 46 ℃.
Storage at lower temperatures caused the use of higher amounts of lysozyme. The activity of lysozyme was increased at higher temperatures. Denatured lysozyme by heating was found to indicate enhanced antimicrobial activity due to the polymerization [22]. In this study, increasing the storage temperature may have improved the enzymatic activity of lysozyme against A. acidoterrestris by lowering the amount needed for inhibition. The MICs were 10, 2.5 and 1.25 mg/L at 27, 35 and 43 ℃, respectively. In the related literature, it was found to exhibit the highest antimicrobial activity against A. acidoterrestris in saline solutions and the addition of lysozyme in laboratory medium resulted in a protective effect [23]. These researchers also found that the MICs of lysozyme towards vegetative cells ranged from 0.1–6 mg/L in acidified malt extract broth. We also found the MICs of lysozyme in the apple juice within this range at 35 ℃ and 43 ℃.
Although the measurement of the absorbance is useful to estimate its growth, it might help to compare the growth rate and lag time under different conditions [24]. Since growth models developed in sterile broth do not always provide reliable predictions of pathogen growth on non-sterile and non-homogenous foods [25], growth studies were achieved in apple juice instead of laboratory medium or model juice to estimate the growth parameters in this study. As seen from Tables 1 and 2, the growth curves fitted to the Baranyi model had high R2 values (≥0.98). The R2 values indicated that fitted models provided good fit to the experimental data.
| T (℃) | IU/mL | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 25.79 ± 0.56 | 16.98 ± 0.37 | 0.997 |
| 2.5 | 29.83 ± 3.45 | 14.13 ± 1.67 | 0.997 | |
| 5.0 | 48.00 ± 1.69 | 18.07 ± 2.59 | 0.990 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 1.25 | 28.06 ± 0.62 | 33.40 ± 0.47 | 0.997 |
| 2.5 | 31.42 ± 0.25 | 34.11 ± 1.09 | 0.998 | |
| 5.0 | 36.50 ± 0.79 | 36.90 ± 0.00 | 0.995 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 1.25 | 18.48 ± 0.01 | 51.37 ± 0.00 | 0.983 |
| 2.5 | 10.1 ± 0.01 | 37.9 ± 0.03 | 0.992 | |
| 5.0 | 18.5 ± 0.00 | 51.4 ± 1.00 | 0.980 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
DownLoad: CSV| T (℃) | mg/L | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 30.53 ± 1.87 | 13.51 ± 0.27 | 0.999 |
| 2.5 | 43.04 ± 1.46 | 14.41 ± 0.47 | 0.999 | |
| 5.0 | 51.10 ± 1.33 | 16.52 ± 0.30 | 0.994 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 0.3 | 16.69 ± 0.22 | 22.17 ± 0.04 | 0.989 |
| 0.6 | 21.11 ± 0.31 | 25.28 ± 0.05 | 0.990 | |
| 1.25 | 25.71 ± 1.00 | 31.81 ± 0.40 | 0.986 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 0.08 | 7.06 ± 0.00 | 31.94 ± 0.00 | 0.991 |
| 0.16 | 7.80 ± 0.04 | 31.56 ± 1.01 | 0.992 | |
| 0.3 | 14.71 ± 0.03 | 36.61 ± 0.90 | 0.996 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
DownLoad: CSVThe estimated lag times decreased and growth rates increased with increasing storage temperature among the controls. The growth was favored at 43 ℃ with the highest growth rate and shortest lag times most probably due to the thermophilic nature of the tested organism. As seen from Table 1, there was a strong correlation between the growth rates and nisin concentrations at 35 ℃ (R2 > 0.91). In general, it is accepted that µ is not influenced by sublethal injuries after conventional preservation treatments and is identical to that of untreated cells. After exposure to some novel technologies such as pulsed electric fields and electron beam irradiation, the growth rate of surviving cells can be changed [6]. In the present study, the growth rates of the treated cells were higher than that of the controls within each temperature (Table 1). The addition of nisin in the apple juice resulted in an extension of lag phase compared to untreated control cells. We observed a relationship between the lag time and nisin concentrations at 27 and 35 ℃ (R2 > 0.83). At the highest non-inhibitory nisin dose, the increase in the lag time was approximately 25, 27 and 13 h at 27 ℃, 35 ℃ and 43 ℃, respectively.
The growth rates in the presence of lysozyme ranged from approximately 13.5 to 16.5, 22.2 to 31.8, and 31.6 to 36.6 × 10–4 h–1 at 27, 35, and 43 ℃, respectively (Table 2). We observed a linear relationship between the rate and lysozyme concentration at 27 ℃ (R2 > 0.94). As the temperature decreased, the effect of lysozyme on the lag phase extension was more pronounced. There was a strong linear relationship between the lag time and lysozyme concentrations at 27 and 35 ℃ (R2 > 0.98). The treatment with 1.25, 2.5 and 5 mg/L lysozyme delayed the lag time approximately 8, 20 and 28 h at 27 ℃, respectively. When the temperature was increased to 43 ℃, the lag time was delayed with approximately 2, 2.5 and 9 h in the apple juice with 0.08, 0.16 and 0.3 mg/mL lysozyme, respectively. To our knowledge, there is only one study about the modeling growth kinetics of A. acidoterrestris in the broth with monolaurin using absorbance data [26]. They found that the Gompertz and Baranyi models were satisfactorily described the growth curves of cells in the presence of monolaurin. According to their results, monolaurin could be used to inhibit the growth and it was effective on cells by delaying the lag phase approximately 8 h and reducing the growth index from 48% to 32–37%.
We observed a significant difference in the amounts of lysozyme for growth inhibition at three temperatures tested. Both nisin and lysozyme were effective to delay lag time and increase growth rate when used at lower amounts. Differences in the antimicrobial action of nisin and lysozyme against A. acidoterrestris could be explained by variations in storage temperature. The obtained results from this study will be useful to inhibit or delay the growth of A. acidoterrestris by combining extrinsic factors such as storage temperature and natural antimicrobials as a hurdle concept to prolong the shelf-life of commercial apple juices.
Authors would like to thank to the members of the Biotechnology and Bioengineering Research and Application Center of Izmir Institute of Technology for absorbance measurements.
All authors declare no conflicts of interest in this paper.
| [1] |
S. A. Silling, Reformulation of elasticity theory for discontinuities and long-range forces, J Mech Phys Solids, 48 (2000), 175–209. https://doi.org/10.1016/S0022-5096(99)00029-0 doi: 10.1016/S0022-5096(99)00029-0
|
| [2] |
D. De Meo, L. Russo, E. Oterkus, Modeling of the onset, propagation, and interaction of multiple cracks generated from corrosion pits by using peridynamics, J Eng Mater Techn, 139 (2017), 041001. https://doi.org/10.1115/1.4036443 doi: 10.1115/1.4036443
|
| [3] |
B. B. Yin, W. K. Sun, Y. Zhang, K. M. Liew, Modeling via peridynamics for large deformation and progressive fracture of hyperelastic materials, Comput. Methods Appl. Mech. Eng., 403 (2023), 115739. https://doi.org/10.1016/j.cma.2022.115739 doi: 10.1016/j.cma.2022.115739
|
| [4] |
X. Liu, X. He, J. Wang, L. Sun, E. Oterkus, An ordinary state-based peridynamic model for the fracture of zigzag graphene sheets, Proc. Math. Phys. Eng. Sci., 474 (2018), 20180019. https://doi.org/10.1098/rspa.2018.0019 doi: 10.1098/rspa.2018.0019
|
| [5] |
M. Dorduncu, Stress analysis of sandwich plates with functionally graded cores using peridynamic differential operator and refined zigzag theory, Thin Wall Struct, 146 (2020), 106468. https://doi.org/10.1016/j.tws.2019.106468 doi: 10.1016/j.tws.2019.106468
|
| [6] |
A. Kutlu, M. Dorduncu, T. Rabczuk, A novel mixed finite element formulation based on the refined zigzag theory for the stress analysis of laminated composite plates, Compos Struct, 267 (2021), 113886. https://doi.org/10.1016/j.compstruct.2021.113886 doi: 10.1016/j.compstruct.2021.113886
|
| [7] |
W. Chen, X. Gu, Q. Zhang, X. Xia, A refined thermo-mechanical fully coupled peridynamics with application to concrete cracking, Eng. Fract. Mech., 242 (2021), 107463. https://doi.org/10.1016/j.engfracmech.2020.107463 doi: 10.1016/j.engfracmech.2020.107463
|
| [8] |
M. Qin, D. Yang, W. Chen, S. Yang, Hydraulic fracturing model of a layered rock mass based on peridynamics, Eng. Fract. Mech., 258 (2021), 108088. https://doi.org/10.1016/j.engfracmech.2021.108088 doi: 10.1016/j.engfracmech.2021.108088
|
| [9] |
A. Lakshmanan, J. Luo, I. Javaheri, V. Sundararaghavan, Three-dimensional crystal plasticity simulations using peridynamics theory and experimental comparison, Int J Plasticity, 142 (2021), 102991. https://doi.org/10.1016/j.ijplas.2021.102991 doi: 10.1016/j.ijplas.2021.102991
|
| [10] |
H. Yan, M. Sedighi, A. P. Jivkov, Peridynamics modelling of coupled water flow and chemical transport in unsaturated porous media, J Hydrol, 591 (2020), 125648. https://doi.org/10.1016/j.jhydrol.2020.125648 doi: 10.1016/j.jhydrol.2020.125648
|
| [11] |
H. Wang, S. Tanaka, S. Oterkus, E. Oterkus, Study on two-dimensional mixed-mode fatigue crack growth employing ordinary state-based peridynamics, Theor. Appl. Fract. Mech., 124 (2023), 103761. https://doi.org/10.1016/j.tafmec.2023.103761 doi: 10.1016/j.tafmec.2023.103761
|
| [12] |
Z. Yang, S. Oterkus, E. Oterkus, Peridynamic formulation for Timoshenko beam, Procedia Struct. Integr, 28 (2020), 464–471. https://doi.org/10.1016/j.prostr.2020.10.055 doi: 10.1016/j.prostr.2020.10.055
|
| [13] |
Z. Yang, E. Oterkus, S. Oterkus, Peridynamic higher-order beam formulation, J Peridyn Nonlocal Model, 3 (2021), 67–83. https://doi.org/10.1007/s42102-020-00043-w doi: 10.1007/s42102-020-00043-w
|
| [14] |
Z. Yang, B. Vazic, C. Diyaroglu, E. Oterkus, S. Oterkus, A Kirchhoff plate formulation in a state-based peridynamic framework, Math Mech Solids, 25 (2020), 727–738. https://doi.org/10.1177/1081286519887523 doi: 10.1177/1081286519887523
|
| [15] |
Z. Yang, E. Oterkus, S. Oterkus, Peridynamic formulation for higher-order plate theory, J Peridyn Nonlocal Model, 3 (2021), 185–210. https://doi.org/10.1007/s42102–020–00047–6 doi: 10.1007/s42102–020–00047–6
|
| [16] |
J. Heo, Z. Yang, W. Xia, S. Oterkus, E. Oterkus, Free vibration analysis of cracked plates using peridynamics, Ships Offshore Struct, 15 (2020), S220–S229. https://doi.org/10.1080/17445302.2020.1834266 doi: 10.1080/17445302.2020.1834266
|
| [17] |
J. Heo, Z. Yang, W. Xia, S. Oterkus, E. Oterkus, Buckling analysis of cracked plates using peridynamics, Ocean Eng., 214 (2020), 107817. https://doi.org/10.1016/j.oceaneng.2020.107817 doi: 10.1016/j.oceaneng.2020.107817
|
| [18] |
Z. Yang, C. C. Ma, E. Oterkus, S. Oterkus, K. Naumenko, Analytical solution of 1–dimensional peridynamic equation of motion, J Peridyn Nonlocal Model, 5 (2023), 356–374. https://doi.org/10.1007/s42102–022–00086–1 doi: 10.1007/s42102–022–00086–1
|
| [19] |
Z. Yang, C. C. Ma, E. Oterkus, S. Oterkus, K. Naumenko, B. Vazic, Analytical solution of the peridynamic equation of motion for a 2–dimensional rectangular membrane, J Peridyn Nonlocal Model, 5 (2023), 375–391. https://doi.org/10.1007/s42102–022–00090–5 doi: 10.1007/s42102–022–00090–5
|
| [20] | E. Oterkus, E. Madenci, M. Nemeth, Stress analysis of composite cylindrical shells with an elliptical cutout, J mech mater struct, 2 (2007), 695–727. |
| [21] |
T. Ni, M. Zaccariotto, Q. Z. Zhu, U. Galvanetto, Coupling of FEM and ordinary state–based peridynamics for brittle failure analysis in 3D, Mech Adv Mater Struc, 28 (2021), 875–890. https://doi.org/10.1080/15376494.2019.1602237 doi: 10.1080/15376494.2019.1602237
|
| [22] |
A. Pagani, E. Carrera, Coupling three‐dimensional peridynamics and high‐order one‐dimensional finite elements based on local elasticity for the linear static analysis of solid beams and thin‐walled reinforced structures, Int J Numer Meth Eng, 121 (2020), 5066–5081. https://doi.org/10.1002/nme.6510 doi: 10.1002/nme.6510
|
| [23] |
Y. Xia, X. Meng, G. Shen, G. Zheng, P. Hu, Isogeometric analysis of cracks with peridynamics, Comput Method Appl M, 377 (2021), 113700. https://doi.org/10.1016/j.cma.2021.113700 doi: 10.1016/j.cma.2021.113700
|
| [24] |
R. Liu, J. Yan, S. Li, Modeling and simulation of ice–water interactions by coupling peridynamics with updated Lagrangian particle hydrodynamics, Comput. Part. Mech., 7 (2020), 241–255. https://doi.org/10.1007/s40571–019–00268–7 doi: 10.1007/s40571–019–00268–7
|
| [25] |
Y. Wang, X. Zhou, Y. Wang, Y. Shou, A 3–D conjugated bond–pair–based peridynamic formulation for initiation and propagation of cracks in brittle solids, International Journal of Solids and Structures, 134 (2018), 89–115. https://doi.org/10.1016/j.ijsolstr.2017.10.022 doi: 10.1016/j.ijsolstr.2017.10.022
|
| [26] |
V. Diana, A. Bacigalupo, M. Lepidi, L. Gambarotta, Anisotropic peridynamics for homogenized microstructured materials, Comput Method Appl M, 392 (2022), 114704. https://doi.org/10.1016/j.cma.2022.114704 doi: 10.1016/j.cma.2022.114704
|
| [27] |
Y. Mikata, Peridynamics for fluid mechanics and acoustics, Acta Mech, 232 (2021), 3011–3032. https://doi.org/10.1007/s00707–021–02947–0 doi: 10.1007/s00707–021–02947–0
|
| [28] | E. Madenci, A. Barut, M. Dorduncu, Peridynamic differential operator for numerical analysis, Berlin: Springer International Publishing, 2019,978–980. https://doi.org/10.1007/978–3–030–02647–9 |
| [29] |
H. Ren, X. Zhuang, T. Rabczuk, A higher order nonlocal operator method for solving partial differential equations, Comput Method Appl M, 367 (2020), 113132. https://doi.org/10.1016/j.cma.2020.113132 doi: 10.1016/j.cma.2020.113132
|
| [30] |
H. Ren, X. Zhuang, T. Rabczuk, A nonlocal operator method for solving partial differential equations, Comput Method Appl M, 358 (2020), 112621. https://doi.org/10.1016/j.cma.2019.112621 doi: 10.1016/j.cma.2019.112621
|
| [31] |
X. Zhuang, H. Ren, T. Rabczuk, Nonlocal operator method for dynamic brittle fracture based on an explicit phase field model, Eur J Mech A-solid, 90 (2021), 104380. https://doi.org/10.1016/j.euromechsol.2021.104380 doi: 10.1016/j.euromechsol.2021.104380
|
| [32] |
Z. Yang, E. Oterkus, S. Oterkus, C. C. Ma, Double horizon peridynamics, Math Mech Solids, 28 (2023), 2531–2549. https://doi.org/10.1177/10812865231173686 doi: 10.1177/10812865231173686
|
| [33] |
H. Ren, X. Zhuang, Y. Cai, T. Rabczuk, Dual‐horizon peridynamics, International Journal for Numerical Methods in Engineering, 108 (2016), 1451–1476. https://doi.org/10.1016/j.cma.2016.12.031 doi: 10.1016/j.cma.2016.12.031
|
| [34] |
B. Wang, S. Oterkus, E. Oterkus, Derivation of dual-horizon state-based peridynamics formulation based on Euler-Lagrange equation, Continuum Mech Therm, 35 (2023), 841–861. https://doi.org/10.1007/s00161–020–00915–y doi: 10.1007/s00161–020–00915–y
|
| [35] |
A. Javili, R. Morasata, E. Oterkus, S. Oterkus, Peridynamics review, Math Mech Solids, 24 (2019), 3714–3739. https://doi.org/10.1177/1081286518803411 doi: 10.1177/1081286518803411
|
| [36] | E. Madenci, E. Oterkus, Peridynamic Theory and Its Applications, New York: Springer New York, 2013. https://doi.org/10.1007/978–1–4614–8465–3 |
| [37] |
L. Lopez, S. F. Pellegrino, A space-time discretization of a nonlinear peridynamic model on a 2D lamina, Comput Math Appl, 116 (2022), 161–175. https://doi.org/10.1016/j.camwa.2021.07.004 doi: 10.1016/j.camwa.2021.07.004
|
| [38] |
S. Jafarzadeh, A. Larios, F. Bobaru, Efficient solutions for nonlocal diffusion problems via boundary-adapted spectral methods, J Peridyn Nonlocal Model, 2 (2020), 85–110. https://doi.org/10.1007/s42102–019–00026–6 doi: 10.1007/s42102–019–00026–6
|
| 1. | Alina Kunicka-Styczyńska, Agnieszka Tyfa, Dariusz Laskowski, Aleksandra Plucińska, Katarzyna Rajkowska, Krystyna Kowal, Clove Oil (Syzygium aromaticum L.) Activity against Alicyclobacillus acidoterrestris Biofilm on Technical Surfaces, 2020, 25, 1420-3049, 3334, 10.3390/molecules25153334 | |
| 2. | Soisuda Pornpukdeewattana, Aphacha Jindaprasert, Salvatore Massa, Alicyclobacillusspoilage and control - a review, 2020, 60, 1040-8398, 108, 10.1080/10408398.2018.1516190 | |
| 3. | Aryádina M Ribeiro, Aline D Paiva, Alexandra MO Cruz, Maria CD Vanetti, Sukarno O Ferreira, Hilário C Mantovani, Bovicin HC5 and nisin reduce cell viability and the thermal resistance of Alicyclobacillus acidoterrestris endospores in fruit juices , 2022, 102, 0022-5142, 3994, 10.1002/jsfa.11747 | |
| 4. | Patra Sourri, Chrysoula C. Tassou, George-John E. Nychas, Efstathios Z. Panagou, Fruit Juice Spoilage by Alicyclobacillus: Detection and Control Methods—A Comprehensive Review, 2022, 11, 2304-8158, 747, 10.3390/foods11050747 |
Figures(10)
Zhenghao Yang, Erkan Oterkus, Selda Oterkus. Two-dimensional double horizon peridynamics for membranes[J]. Networks and Heterogeneous Media, 2024, 19(2): 611-633. doi: 10.3934/nhm.2024027
| T (℃) | IU/mL | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 25.79 ± 0.56 | 16.98 ± 0.37 | 0.997 |
| 2.5 | 29.83 ± 3.45 | 14.13 ± 1.67 | 0.997 | |
| 5.0 | 48.00 ± 1.69 | 18.07 ± 2.59 | 0.990 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 1.25 | 28.06 ± 0.62 | 33.40 ± 0.47 | 0.997 |
| 2.5 | 31.42 ± 0.25 | 34.11 ± 1.09 | 0.998 | |
| 5.0 | 36.50 ± 0.79 | 36.90 ± 0.00 | 0.995 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 1.25 | 18.48 ± 0.01 | 51.37 ± 0.00 | 0.983 |
| 2.5 | 10.1 ± 0.01 | 37.9 ± 0.03 | 0.992 | |
| 5.0 | 18.5 ± 0.00 | 51.4 ± 1.00 | 0.980 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
DownLoad: CSV| T (℃) | mg/L | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 30.53 ± 1.87 | 13.51 ± 0.27 | 0.999 |
| 2.5 | 43.04 ± 1.46 | 14.41 ± 0.47 | 0.999 | |
| 5.0 | 51.10 ± 1.33 | 16.52 ± 0.30 | 0.994 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 0.3 | 16.69 ± 0.22 | 22.17 ± 0.04 | 0.989 |
| 0.6 | 21.11 ± 0.31 | 25.28 ± 0.05 | 0.990 | |
| 1.25 | 25.71 ± 1.00 | 31.81 ± 0.40 | 0.986 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 0.08 | 7.06 ± 0.00 | 31.94 ± 0.00 | 0.991 |
| 0.16 | 7.80 ± 0.04 | 31.56 ± 1.01 | 0.992 | |
| 0.3 | 14.71 ± 0.03 | 36.61 ± 0.90 | 0.996 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
DownLoad: CSV| T (℃) | IU/mL | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 25.79 ± 0.56 | 16.98 ± 0.37 | 0.997 |
| 2.5 | 29.83 ± 3.45 | 14.13 ± 1.67 | 0.997 | |
| 5.0 | 48.00 ± 1.69 | 18.07 ± 2.59 | 0.990 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 1.25 | 28.06 ± 0.62 | 33.40 ± 0.47 | 0.997 |
| 2.5 | 31.42 ± 0.25 | 34.11 ± 1.09 | 0.998 | |
| 5.0 | 36.50 ± 0.79 | 36.90 ± 0.00 | 0.995 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 1.25 | 18.48 ± 0.01 | 51.37 ± 0.00 | 0.983 |
| 2.5 | 10.1 ± 0.01 | 37.9 ± 0.03 | 0.992 | |
| 5.0 | 18.5 ± 0.00 | 51.4 ± 1.00 | 0.980 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
| T (℃) | mg/L | λ (h) | µ (h–110–4) | R2 |
| 27 | 1.25 | 30.53 ± 1.87 | 13.51 ± 0.27 | 0.999 |
| 2.5 | 43.04 ± 1.46 | 14.41 ± 0.47 | 0.999 | |
| 5.0 | 51.10 ± 1.33 | 16.52 ± 0.30 | 0.994 | |
| Control | 22.67 ± 0.59 | 10.13 ± 0.21 | 0.999 | |
| 35 | 0.3 | 16.69 ± 0.22 | 22.17 ± 0.04 | 0.989 |
| 0.6 | 21.11 ± 0.31 | 25.28 ± 0.05 | 0.990 | |
| 1.25 | 25.71 ± 1.00 | 31.81 ± 0.40 | 0.986 | |
| Control | 9.91 ± 1.80 | 28.58 ± 2.05 | 0.996 | |
| 43 | 0.08 | 7.06 ± 0.00 | 31.94 ± 0.00 | 0.991 |
| 0.16 | 7.80 ± 0.04 | 31.56 ± 1.01 | 0.992 | |
| 0.3 | 14.71 ± 0.03 | 36.61 ± 0.90 | 0.996 | |
| Control | 5.33 ± 0.04 | 33.76 ± 0.37 | 0.990 | |
| Values are estimated using an average of replicates obtained from growth curves. λ is lag phase (h); µ is specific growth rate (h–110–4). | ||||
