A washing-disinfectant product was synthesized with citric acid which was a readily available raw material on the chemical markets. Following-up the established procedure to use this product reflected its efficiency to eliminate, to remove, to kill and to decrease significantly the binary fission of various germs and micro-organisms not only on raw materials but also on materials and containers that could cause consumers illness. Indeed, the quantifications of these micro-organisms on a product “spicy product energy booster (speb)” – “produit épicé boosteur d’énergie (pebe)” at the “Institut Pasteur de Madagascar” whose analyzes were accredited by COFRAC © reflected that firstly there were any Salmonella spp. and any Listeria monocytogenes; secondly its quantities of Bacillus cereus, Escherichia coli and Staphylococcus aureus respected the European standardization for food products; thirdly this “speb-pebe” product decreased significantly the binary fission speed of these previous micro-organisms in order 4.7 to 80 times less speed than its speeds deduced by a reference and/or by its generation time; and fourth the product “speb-pebe” best-before dates during a conservation at 303.15 (°K), natural ambient temperature, were calculated from each micro-organism’s binary fission speed. Then, two procedures titrations consisting in titration of the “speb-pebe” - spicy product energy booster’s equivalent-citric acid molecules in each level of its packaging using NaOH-0.0557N and in titration of the “speb-pebe” - spicy product energy booster’s alkenes-C= organic functions (on surface and on structure-texture) in each level of its packaging using HF-0.0026N were established and allowed to appreciate the “speb-pebe” quality in each level of its packaging and also to control its packaging-quality. It was noticed that the concentration of alkenes-C= organic functions on structure and on texture per grams on the Level-high-packaging were 5.9 times less than those on Level-medium-packaging 1.23E-1 [mol×l-1×g-1] and on Level-low-packaging 1.16E-1 [mol×l-1×g-1] confirming in return the highest value of the concentration of alkenes-C= organic functions on surface per grams of “speb-pebe” observed at Level-high-packaging sample (4.805E-3 [mol×l-1×g-1]) compared with Level-middle-packaging sample (1.72E-3 [mol×l-1×g-1]) and with Level-low-packaging sample (2.19E-3 [mol×l-1×g-1]). Another results, the dispersion of the equivalent-citric acids molecules on total alkenes-C= organic functions noted dispersion (Ac⁄C=) or dispersion ([Ac]⁄[C=]) for the Level-high-packaging sample, the Level-middle-packaging sample and the Level-low-packaging sample were respectively 0.2813, 0.0250 and 0.0714 and confirmed the useful role of citric acids molecules quantities and their protons H+ capacities and activities to catalyze some chemistry reactions and responsible of this “speb-pebe” - spicy product energy booster’s acidity-pH=2.62, flavors and tastes.
Published in | American Journal of Applied Chemistry (Volume 9, Issue 3) |
DOI | 10.11648/j.ajac.20210903.11 |
Page(s) | 53-64 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Micro-organisms, Disinfectant, Binary Fission Speed, Citric Acid, “Speb-Pebe”, NaOH, HF, Alkenes-C=
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APA Style
Nambinina Richard Randriana, Ernestine Ravomialisoa, Andry Tahina Rabeharitsara. (2021). Washing-Disinfectant Product Synthesis Tested During the Production of the “Speb-Pebe” - Spicy Product Energy Booster Characterized by Established Titration Procedures. American Journal of Applied Chemistry, 9(3), 53-64. https://doi.org/10.11648/j.ajac.20210903.11
ACS Style
Nambinina Richard Randriana; Ernestine Ravomialisoa; Andry Tahina Rabeharitsara. Washing-Disinfectant Product Synthesis Tested During the Production of the “Speb-Pebe” - Spicy Product Energy Booster Characterized by Established Titration Procedures. Am. J. Appl. Chem. 2021, 9(3), 53-64. doi: 10.11648/j.ajac.20210903.11
AMA Style
Nambinina Richard Randriana, Ernestine Ravomialisoa, Andry Tahina Rabeharitsara. Washing-Disinfectant Product Synthesis Tested During the Production of the “Speb-Pebe” - Spicy Product Energy Booster Characterized by Established Titration Procedures. Am J Appl Chem. 2021;9(3):53-64. doi: 10.11648/j.ajac.20210903.11
@article{10.11648/j.ajac.20210903.11, author = {Nambinina Richard Randriana and Ernestine Ravomialisoa and Andry Tahina Rabeharitsara}, title = {Washing-Disinfectant Product Synthesis Tested During the Production of the “Speb-Pebe” - Spicy Product Energy Booster Characterized by Established Titration Procedures}, journal = {American Journal of Applied Chemistry}, volume = {9}, number = {3}, pages = {53-64}, doi = {10.11648/j.ajac.20210903.11}, url = {https://doi.org/10.11648/j.ajac.20210903.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajac.20210903.11}, abstract = {A washing-disinfectant product was synthesized with citric acid which was a readily available raw material on the chemical markets. Following-up the established procedure to use this product reflected its efficiency to eliminate, to remove, to kill and to decrease significantly the binary fission of various germs and micro-organisms not only on raw materials but also on materials and containers that could cause consumers illness. Indeed, the quantifications of these micro-organisms on a product “spicy product energy booster (speb)” – “produit épicé boosteur d’énergie (pebe)” at the “Institut Pasteur de Madagascar” whose analyzes were accredited by COFRAC © reflected that firstly there were any Salmonella spp. and any Listeria monocytogenes; secondly its quantities of Bacillus cereus, Escherichia coli and Staphylococcus aureus respected the European standardization for food products; thirdly this “speb-pebe” product decreased significantly the binary fission speed of these previous micro-organisms in order 4.7 to 80 times less speed than its speeds deduced by a reference and/or by its generation time; and fourth the product “speb-pebe” best-before dates during a conservation at 303.15 (°K), natural ambient temperature, were calculated from each micro-organism’s binary fission speed. Then, two procedures titrations consisting in titration of the “speb-pebe” - spicy product energy booster’s equivalent-citric acid molecules in each level of its packaging using NaOH-0.0557N and in titration of the “speb-pebe” - spicy product energy booster’s alkenes-C= organic functions (on surface and on structure-texture) in each level of its packaging using HF-0.0026N were established and allowed to appreciate the “speb-pebe” quality in each level of its packaging and also to control its packaging-quality. It was noticed that the concentration of alkenes-C= organic functions on structure and on texture per grams on the Level-high-packaging were 5.9 times less than those on Level-medium-packaging 1.23E-1 [mol×l-1×g-1] and on Level-low-packaging 1.16E-1 [mol×l-1×g-1] confirming in return the highest value of the concentration of alkenes-C= organic functions on surface per grams of “speb-pebe” observed at Level-high-packaging sample (4.805E-3 [mol×l-1×g-1]) compared with Level-middle-packaging sample (1.72E-3 [mol×l-1×g-1]) and with Level-low-packaging sample (2.19E-3 [mol×l-1×g-1]). Another results, the dispersion of the equivalent-citric acids molecules on total alkenes-C= organic functions noted dispersion (Ac⁄C=) or dispersion ([Ac]⁄[C=]) for the Level-high-packaging sample, the Level-middle-packaging sample and the Level-low-packaging sample were respectively 0.2813, 0.0250 and 0.0714 and confirmed the useful role of citric acids molecules quantities and their protons H+ capacities and activities to catalyze some chemistry reactions and responsible of this “speb-pebe” - spicy product energy booster’s acidity-pH=2.62, flavors and tastes.}, year = {2021} }
TY - JOUR T1 - Washing-Disinfectant Product Synthesis Tested During the Production of the “Speb-Pebe” - Spicy Product Energy Booster Characterized by Established Titration Procedures AU - Nambinina Richard Randriana AU - Ernestine Ravomialisoa AU - Andry Tahina Rabeharitsara Y1 - 2021/06/21 PY - 2021 N1 - https://doi.org/10.11648/j.ajac.20210903.11 DO - 10.11648/j.ajac.20210903.11 T2 - American Journal of Applied Chemistry JF - American Journal of Applied Chemistry JO - American Journal of Applied Chemistry SP - 53 EP - 64 PB - Science Publishing Group SN - 2330-8745 UR - https://doi.org/10.11648/j.ajac.20210903.11 AB - A washing-disinfectant product was synthesized with citric acid which was a readily available raw material on the chemical markets. Following-up the established procedure to use this product reflected its efficiency to eliminate, to remove, to kill and to decrease significantly the binary fission of various germs and micro-organisms not only on raw materials but also on materials and containers that could cause consumers illness. Indeed, the quantifications of these micro-organisms on a product “spicy product energy booster (speb)” – “produit épicé boosteur d’énergie (pebe)” at the “Institut Pasteur de Madagascar” whose analyzes were accredited by COFRAC © reflected that firstly there were any Salmonella spp. and any Listeria monocytogenes; secondly its quantities of Bacillus cereus, Escherichia coli and Staphylococcus aureus respected the European standardization for food products; thirdly this “speb-pebe” product decreased significantly the binary fission speed of these previous micro-organisms in order 4.7 to 80 times less speed than its speeds deduced by a reference and/or by its generation time; and fourth the product “speb-pebe” best-before dates during a conservation at 303.15 (°K), natural ambient temperature, were calculated from each micro-organism’s binary fission speed. Then, two procedures titrations consisting in titration of the “speb-pebe” - spicy product energy booster’s equivalent-citric acid molecules in each level of its packaging using NaOH-0.0557N and in titration of the “speb-pebe” - spicy product energy booster’s alkenes-C= organic functions (on surface and on structure-texture) in each level of its packaging using HF-0.0026N were established and allowed to appreciate the “speb-pebe” quality in each level of its packaging and also to control its packaging-quality. It was noticed that the concentration of alkenes-C= organic functions on structure and on texture per grams on the Level-high-packaging were 5.9 times less than those on Level-medium-packaging 1.23E-1 [mol×l-1×g-1] and on Level-low-packaging 1.16E-1 [mol×l-1×g-1] confirming in return the highest value of the concentration of alkenes-C= organic functions on surface per grams of “speb-pebe” observed at Level-high-packaging sample (4.805E-3 [mol×l-1×g-1]) compared with Level-middle-packaging sample (1.72E-3 [mol×l-1×g-1]) and with Level-low-packaging sample (2.19E-3 [mol×l-1×g-1]). Another results, the dispersion of the equivalent-citric acids molecules on total alkenes-C= organic functions noted dispersion (Ac⁄C=) or dispersion ([Ac]⁄[C=]) for the Level-high-packaging sample, the Level-middle-packaging sample and the Level-low-packaging sample were respectively 0.2813, 0.0250 and 0.0714 and confirmed the useful role of citric acids molecules quantities and their protons H+ capacities and activities to catalyze some chemistry reactions and responsible of this “speb-pebe” - spicy product energy booster’s acidity-pH=2.62, flavors and tastes. VL - 9 IS - 3 ER -