Key Points for Optimizing the Production Process of Inoculants | Barium & Calcium inoculant!

In the metallurgical industry, barium inoculant and calcium inoculant play a crucial role in refining grain structures, enhancing mechanical properties, and improving cast iron quality. Optimizing the production process of these inoculants is essential to ensure consistency, efficiency, and cost-effectiveness. This article explores key strategies to enhance the manufacturing process of these vital foundry materials, including the role of ferro silicon magnesium in improving overall performance.

1. Selection of High-Quality Raw Materials

The quality of inoculants begins with the selection of superior raw materials. Ferroalloys such as ferrosilicon, calcium, and barium-based compounds are commonly used. Ensuring high purity minimizes impurities and enhances the inoculation effect.

Key Considerations:

Use of high-grade ferroalloys to maintain consistency.

Reduction of oxide inclusions through refined material selection.

Stringent quality checks to eliminate contaminants.

2. Optimized Alloying and Melting Techniques

The melting process significantly impacts the final quality of inoculants. Proper temperature control, furnace selection, and optimized alloying techniques contribute to enhanced performance and reduced production losses.

Optimization Methods:

Maintaining an optimal melting temperature range to prevent oxidation.

Using induction furnaces for precise temperature control.

Controlled alloying to achieve uniform chemical composition.

3. Precision in Composition Control

Ensuring a consistent chemical composition is crucial for effective inoculation. Implementing real-time chemical analysis and spectrometry testing helps maintain the ideal ratio of elements such as silicon, calcium, and barium.

Effective Control Measures:

Regular spectral analysis to verify elemental composition.

Fine-tuning of alloy proportions based on customer specifications.

Implementation of automated dosing systems to minimize human error.

4. Advanced Refining and Deoxidation Techniques

Unwanted oxides and non-metallic inclusions can degrade the effectiveness of barium and calcium inoculants. Utilizing refining agents and optimizing deoxidation techniques improve the purity of the final product.

Refinement Strategies:

Application of vacuum degassing to eliminate unwanted gases.

Addition of active deoxidizers to enhance metal purity.

Filtration techniques to remove non-metallic inclusions.

5. Efficient Casting and Solidification Process

Once the molten metal is prepared, the casting and solidification process must be carefully controlled to avoid segregation of elements and to maintain uniform microstructure.

Key Optimization Factors:

Using precise mold temperatures to control solidification rates.

Proper inoculant size distribution for enhanced dissolution in molten iron.

Implementing automated pouring systems for consistency.

6. Rigorous Quality Control & Testing

A robust quality control system is essential for ensuring that inoculants meet industry standards. Testing methods should include both laboratory analysis and real-world performance testing in foundry applications.

Essential Quality Checks:

Chemical composition verification through spectrometry.

Particle size analysis for consistent dispersion in molten iron.

Performance trials in controlled foundry conditions to test effectiveness.

7. Sustainable and Cost-Effective Production Methods

With growing environmental regulations, optimizing the production process must also focus on sustainability and cost reduction without compromising quality.

Sustainable Practices:

Waste minimization through optimized raw material usage.

Energy-efficient furnace operations to lower carbon footprint.

Recycling and reuse of byproducts to reduce material costs.

Conclusion

Optimizing the production process of barium and calcium inoculant involves careful control over raw materials, alloying, refining, and quality assurance. By implementing advanced manufacturing techniques and rigorous testing, foundries can achieve superior product consistency and enhanced casting performance. Ensuring efficiency in these processes not only improves quality but also leads to cost savings and sustainability in metallurgical applications.

By adopting these key strategies, manufacturers can enhance their inoculant production process, ensuring better results in casting applications and reinforcing their position as industry leaders.

#Inoculant #BariumInoculant #CalciumInoculant #FerroSiliconMagnesium #FeSiMgAlloys

Magnesium Oxide Market Growth: Exploring Key Factors

The Essential Properties and Applications of Magnesium Oxide Introduction

Magnesium oxide, commonly known as magnesia, is a white hygroscopic solid mineral that occurs naturally as periclase and is a source of magnesium. It has a chemical formula of MgO and has significant commercial uses due to its unique physical and chemical properties. Chemical Properties Magnesia is an ionic compound consisting of magnesium cations (Mg2+) and

oxide anions (O2-). It has a cubic crystal structure and each magnesium ion is surrounded by six oxide ions and vice versa. This results in a very stable crystalline structure that imparts useful properties to magnesia. It is thermally stable up to about 2,800°C as it requires considerable energy for the magnesium and oxygen to separate into their elemental forms. Due to ionic bonding, it is an electrical insulator with high melting point of 2,852°C. Magnesium oxide is also highly refractory due to its ionic lattice structure and thermal stability. Physical Properties Magnesium oxide is a white crystalline solid that exists in nature as periclase. Its theoretical density is 3.58 g/cm3 and it has a Mohs hardness of 5.5-6 on the hardness scale. It has a relatively high bulk density of around 2.4-3.0 g/cm3 which depends upon factors like grain size, impurities and production method. Due to its ionic character, it is highly stable and is hydroscopic in nature. Exposure to water results in hydration to magnesium hydroxide. Its significant solubility in acids allows it to be used as an antacid. Magnesia also has a high refractive index in the range of 1.728 - 1.738 and is optically isotropic. Commercial Production Naturally occurring magnesia is obtained by mining as periclase crystals mainly from serpentine ore deposits. Globally important areas include Cyprus, Kazakhstan and Serbia. However, magnesite (MgCO3) deposits are a more important commercial source for magnesium compounds. The two main industrial processes for its production are calcination of naturally occurring magnesium hydroxide/carbonate minerals and thermal decomposition of magnesium hydroxide precipitates. Sea water is another feedstock that is concentrated for magnesium extraction. The ore is calcined at high temperatures ranging from 1,000-2,000°C depending on composition and purity requirements. Calcination decomposes the mineral into magnesium oxide and releases carbon dioxide or water. The calcined product is then crushed and screened to obtain commercially useful magnesia powder. Major Applications Refractories: Due to high melting point and thermal conductivity, MgO is used as a refractory lining material in high temperature furnaces, kilns and incinerators operating above 1,000°C. Dead burned magnesite and caustic calcined types are suitable in basic and neutral environments respectively. Agriculture: Finely ground magnesium oxide, also called magnesia alba, is spread as a soil conditioner to neutralize soil acidity and supply magnesium to plants. It is particularly beneficial for crops like fruits, vegetables, sugarcane etc. Pharmaceuticals: Magnesium Oxide finds use as a dietary supplement, antacid and laxative due to its ability to neutralize gastric acid. It has low toxicity and does not cause systemic effects in moderate doses. Construction: Cement, plaster and paint industries use magnesia as a flame retardant filler and additive. Its high refractoriness allows production of fire resistant products. Ground calcium carbonate is a suitable mineral filler. Other Applications: As an electrical insulator, magnesia is used in the manufacture of telecommunication cables, capacitors and motor components. In metallurgy, it is employed as a deoxidizing agent, inoculant for iron and desulphurizing agent. It also finds niche applications in rubber, plastics and textile industries. Conclusion Magnesium Oxide is a commercially important mineral that exhibits desirable properties arising from its stable crystalline ionic structure. Its applications are widespread in refractories, agriculture, pharmaceuticals and construction industries due to high melting point, acid neutralizing ability and flame retardancy. Further research is being conducted to develop advanced ceramics utilizing the unique characteristics of Magnesia.

Agricultural Inoculant Market to See Huge Growth by 2029

Global Agricultural Inoculant Market Report from AMA Research highlights deep analysis on market characteristics, sizing, estimates and growth by segmentation, regional breakdowns & country along with competitive landscape, player’s market shares, and strategies that are key in the market. The exploration provides a 360° view and insights, highlighting major outcomes of the industry. These insights help the business decision-makers to formulate better business plans and make informed decisions to improved profitability. In addition, the study helps venture or private players in understanding the companies in more detail to make better informed decisions. Major Players in This Report Include, Bayer CropSciences (Germany), BASF SE (Germany), Brettyoung (Canada), Novozymes A/S (Denmark), E.I. Dupont De Nemours and Company (United States), Advanced Biological Marketing Inc. (United States), Precision Laboratories, LLC (United States), Queensland Agricultural Seeds Pty. Ltd. (Australia), Verdesian Lifesciences, LLC (United States), Xitebio Technologies Inc. (Canada). Free Sample Report + All Related Graphs & Charts @: https://www.advancemarketanalytics.com/sample-report/101841-global-agricultural-inoculant-market An agricultural inoculant composition used as a seed, plant, foliar spray, field spray, and compost inoculant. The agricultural inoculant composition includes both a peat humus base composition having predetermined quantities of peat moss, leather meal, granite meal, Calcium Phosphate, tobacco meal, animal manure, kelp, greensand, liquid seaweed, and bacterial inoculant. Additionally, a liquid seaweed base composition is mixed with the peat humus base composition and the liquid seaweed base composition includes a combination of liquid seaweed, carbohydrates and polysaccharides, vitamins, as well as liquid alfalfa. The agricultural inoculant has been found to increase both the quality and yield of various types of plant products when such is used either as a seed or plant inoculant. Market Drivers

Increasing Adoption of Organic Farming Practices

Governments Initiatives in Promoting Biocontrol Products

Market Trend

Technological Advancements in Farming Practices

Opportunities

Increasing Demand from Developing Region

Challenges

Lack of Awareness and Availability of Agricultural Inoculants

Enquire for customization in Report @: https://www.advancemarketanalytics.com/enquiry-before-buy/101841-global-agricultural-inoculant-market In this research study, the prime factors that are impelling the growth of the Global Agricultural Inoculant market report have been studied thoroughly in a bid to estimate the overall value and the size of this market by the end of the forecast period. The impact of the driving forces, limitations, challenges, and opportunities has been examined extensively. The key trends that manage the interest of the customers have also been interpreted accurately for the benefit of the readers. The Agricultural Inoculant market study is being classified by Type (Biocontrol Agents, Plant Resistant Stimulant, Plant Growth Promoting Microorganisms), Mode of Application (Seed Inoculant, Soil Inoculant, Other), Crop Types (Cereals & Grains, Oilseeds & Pulses, Fruits & Vegetables, Other), Microbes (Bacteria, Fungi, Other) The report concludes with in-depth details on the business operations and financial structure of leading vendors in the Global Agricultural Inoculant market report, Overview of Key trends in the past and present are in reports that are reported to be beneficial for companies looking for venture businesses in this market. Information about the various marketing channels and well-known distributors in this market was also provided here. This study serves as a rich guide for established players and new players in this market. Get Reasonable Discount on This Premium Report @ https://www.advancemarketanalytics.com/request-discount/101841-global-agricultural-inoculant-market Extracts from Table of Contents Agricultural Inoculant Market Research Report Chapter 1 Agricultural Inoculant Market Overview Chapter 2 Global Economic Impact on Industry Chapter 3 Global Market Competition by Manufacturers Chapter 4 Global Revenue (Value, Volume*) by Region Chapter 5 Global Supplies (Production), Consumption, Export, Import by Regions Chapter 6 Global Revenue (Value, Volume*), Price* Trend by Type Chapter 7 Global Market Analysis by Application ………………….continued This report also analyzes the regulatory framework of the Global Markets Agricultural Inoculant Market Report to inform stakeholders about the various norms, regulations, this can have an impact. It also collects in-depth information from the detailed primary and secondary research techniques analyzed using the most efficient analysis tools. Based on the statistics gained from this systematic study, market research provides estimates for market participants and readers. Contact US : Craig Francis (PR & Marketing Manager) AMA Research & Media LLP Unit No. 429, Parsonage Road Edison, NJ New Jersey USA – 08837 Phone: +1 201 565 3262, +44 161 818 8166 [email protected]

Unlocking the Enigma: A Simple Guide to Rare Mushroom Spores

In the vast world of fungi, some mushrooms stand out not only for their unique appearances but also for the rarity of their spores. Mushroom enthusiasts and cultivators often find themselves captivated by the allure of cultivating these rare varieties, not only for their scarcity but also for the potential discovery of new and exciting strains. In this article, we'll explore the intriguing realm of rare mushroom spores, shedding light on their significance and the steps involved in cultivating them.

Understanding Mushroom Spores:

Before delving into the rare varieties, let's start with the basics. Mushroom spores are the reproductive cells of fungi, functioning similarly to seeds in plants. These microscopic structures are released by mature mushrooms to propagate and create new colonies. Spores are essential for the life cycle of mushrooms, as they carry the genetic material needed to produce new mycelium, the vegetative part of the fungus.

The Appeal of Rare Mushroom Spores:

Certain mushroom species are deemed rare due to their limited distribution in nature or unique growth conditions. Cultivating these rare mushroom spores has gained popularity among enthusiasts and cultivators for several reasons:

Biodiversity Preservation: Rare mushroom spores often represent unique genetic variations. Cultivating these varieties contributes to the preservation of biodiversity within the fungal kingdom, preventing the loss of potentially valuable genetic traits.

Exploration and Discovery: Cultivators of rare mushroom spores may stumble upon previously undiscovered strains. This element of exploration adds an exciting dimension to the cultivation process, with the possibility of uncovering new and distinct mushroom varieties.

Educational Value: Growing rare mushroom spores provides an educational opportunity for enthusiasts and mycologists alike. Studying the growth patterns, characteristics, and ecological requirements of these rare species enhances our understanding of the fungal kingdom.

Steps to Cultivate Rare Mushroom Spores:

Cultivating rare mushroom spores involves a careful and methodical process. While the specific steps may vary depending on the mushroom species, the following general guidelines can provide a starting point for cultivators:

Research and Identification: Before embarking on the cultivation journey, thoroughly research and identify the specific rare mushroom species you intend to cultivate. Understanding the natural habitat, growth conditions, and nutritional requirements is crucial for successful cultivation.

Obtain Quality Spores: Acquire high-quality spores from reputable sources. Some rare mushroom spores may be available through specialized suppliers or mycological societies. Ensure that the spores are viable and free from contamination.

Create a Suitable Substrate: The substrate serves as the nourishing medium for mushroom mycelium to grow. Different mushroom species have distinct substrate preferences. Common substrates include a mixture of organic materials such as grain, sawdust, and supplements like gypsum or calcium carbonate.

Inoculation: Inoculate the substrate with the rare mushroom spores. This involves introducing the spores into the substrate to initiate the growth of mycelium. Techniques for inoculation may include spore syringes, spore prints, or agar plates, depending on the chosen method.

Incubation: Once inoculated, place the substrate in a controlled environment for incubation. Maintain optimal temperature and humidity conditions to encourage the mycelium to colonize the substrate. This stage typically takes several weeks, and the mycelium will gradually spread throughout the substrate.

Prepare for Fruiting: When the substrate is fully colonized, prepare the environment for fruiting. This involves inducing conditions that stimulate the formation of mushroom fruiting bodies. Adjust the temperature, humidity, and light to mimic the natural conditions conducive to mushroom production.

Harvesting and Spore Collection: As the mushrooms mature, harvest them carefully to collect spores. Spore prints or syringes can be created from the mature mushrooms. This process involves allowing the mushrooms to release their spores onto a sterile surface, such as paper, and then collecting them for future use or distribution.

Repeat and Share: Successful cultivation of rare mushroom spores opens the door to further exploration and discovery. Repeat the process to refine your cultivation skills and potentially uncover new insights about the rare species you are cultivating. Sharing your experiences and findings with the mycological community contributes to the collective knowledge of rare mushroom varieties.

Cultivating rare mushroom spores is a fascinating journey that combines science, exploration, and a deep appreciation for the intricacies of the fungal world. From the initial research and identification to the hands-on cultivation and eventual spore collection, each step contributes to the understanding and preservation of rare mushroom species. Whether you're a seasoned mycophile or a curious beginner, delving into the cultivation of rare mushroom spores offers an enriching experience that connects you to the mysteries and wonders of the natural world.

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nɪnɪɪʌrrlɛəætkfaɪpɛrʃ

Pronounced: niniiurrlayuhatkfaipayrsh.

Pantheon of: morality, phlogiston, saltiness.

Entities

Dəŋdʌzpərʌəəsəzfəpzaɪ

Pronounced: duhngduzpuhruuhuhsuhzfuhpzai Saltiness: brackishness. Morality: rightness. Legends: confrontation, search and rescue mission, conviction, centralization, tinning. Prophecies: inoculation, soubrette, strabotomy, detention. Relations: opnθnwnɛiʃwtʃdrædndɒv (gerund), ɪɑpɪprluroðɛaɪnyunɛɒt (snuff), əɪətəreaɪnsrrkɑɪsrtəɪ (train fare).

Efəgnŋpthuəɪnaɪɪðtəku

Pronounced: efuhgnngpthuuhinaiithtuhku Saltiness: brininess. Morality: conscience. Legends: campfire. Prophecies: abandonment, walk, commandership, catching. Relations: əɪətəreaɪnsrrkɑɪsrtəɪ (rh antibody).

Nəsrʌubvməʌltsntmdgt

Pronounced: nuhsruubvmuhultsntmdgt Saltiness: brackishness. Morality: conscience. Legends: epiphany, bay, amphibious landing. Prophecies: satyagraha, conjunction, oculism, skin flick, lowering. Relations: opnθnwnɛiʃwtʃdrædndɒv (finish coat), ɪɑpɪprluroðɛaɪnyunɛɒt (centrality), əɪfəoəɛləpəriəɪfməəɪ (formation), əɪətəreaɪnsrrkɑɪsrtəɪ (calamus oil).

Opnθnwnɛiʃwtʃdrædndɒv

Pronounced: opnthnwnayishwtshdradndouv Saltiness: brackishness. Morality: righteousness. Legends: ruse. Prophecies: philately, digital communications technology, reprieve, wear. Relations: rtəʃvstənʌɪðɑərgbɑvl (east southeast), ðsveɪmðərirpsmktueoə (joker), nəsrʌubvməʌltsntmdgt (interleaf).

Rtəʃvstənʌɪðɑərgbɑvl

Pronounced: rtuhshvstuhnuithahuhrgbahvl Saltiness: brackishness. Morality: rightness. Legends: mistake, ball hawking. Prophecies: rail technology, departure. Relations: ɪɑpɪprluroðɛaɪnyunɛɒt (calcium nitrate), dəŋdʌzpərʌəəsəzfəpzaɪ (hyponitrous acid), ðsveɪmðərirpsmktueoə (west northwest), zzlrwtsmədfzsðɛrsmrʃ (tithe).

Zzlrwtsmədfzsðɛrsmrʃ

Pronounced: zzlrwtsmuhdfzsthayrsmrsh Saltiness: brackishness. Morality: rightness. Prophecies: sunset, headstand, constriction, rectification, epidemic. Relations: ɪɑpɪprluroðɛaɪnyunɛɒt (candelilla wax), əkɪzdʒɑikɪpstɪotæɑert (labial stop), əɪfəoəɛləpəriəɪfməəɪ (sassafras oil).

Ðsveɪmðərirpsmktueoə

Pronounced: thsveimthuhrirpsmktueouh Saltiness: brackishness. Morality: virtue. Legends: updating, ski jumping, hit. Relations: zzlrwtsmədfzsðɛrsmrʃ (zeaxanthin), efəgnŋpthuəɪnaɪɪðtəku (menhaden oil), əkɪzdʒɑikɪpstɪotæɑert (phthalic acid).

Əkɪzdʒɑikɪpstɪotæɑert

Pronounced: uhkizjahikipstiotaahert Saltiness: brackishness. Morality: righteousness. Legends: exacta, insertional mutagenesis, notice, actual sin, singing. Prophecies: attack, haymaking, documentation, simony, knock. Relations: ɪɑpɪprluroðɛaɪnyunɛɒt (lemongrass), əɪfəoəɛləpəriəɪfməəɪ (fluosilicate).

Əɪfəoəɛləpəriəɪfməəɪ

Pronounced: uhifuhouhayluhpuhriuhifmuhuhi Saltiness: brackishness. Morality: conscience. Legends: cause, lithography, bank withdrawal, kindness. Prophecies: cricket, overexploitation, dirty tricks, truck farming, reservation. Relations: əkɪzdʒɑikɪpstɪotæɑert (basswood), nəsrʌubvməʌltsntmdgt (double time), əɪətəreaɪnsrrkɑɪsrtəɪ (oxalacetic acid).

Əɪətəreaɪnsrrkɑɪsrtəɪ

Pronounced: uhiuhtuhreainsrrkahisrtuhi Saltiness: brininess. Morality: rightness. Legends: disturbance. Prophecies: absence without leave, remuneration.

Ɪɑpɪprluroðɛaɪnyunɛɒt

Pronounced: iahpiprlurothayainyunayout Saltiness: brackishness. Morality: good. Legends: draw. Prophecies: haying, flyover, grant, contusion. Relations: əɪfəoəɛləpəriəɪfməəɪ (windfall profit), dəŋdʌzpərʌəəsəzfəpzaɪ (hydroxybenzoic acid), efəgnŋpthuəɪnaɪɪðtəku (sodium iodide).

Ferro Silicon Magnesium - Calcium Inoculant

Inoculants are included fluid cast iron to give the best and reliable qualities in the last projecting. They are utilized to control framework structure and try not to project deserts. Inoculants can be found under a few grain size disseminations to fulfil the area of the inoculant expansion inside the foundry interaction. Those locations of inoculant addition are known as in furnace, in ladle, in stream or in mould.

Inoculants are ferrosilicon based combinations. All components which are barium, Calcium Inoculant, aluminium, and uncommon earth can be included the specific sum into the base fluid iron to incite and confirm the last projecting lattice structure. Website Link : https://www.ferrosiliconmagnesium.com/products.php

Nous y voilà ! Pardon si le texte est long....

En gros : on nous empoisonne pour réduire les coûts de production et on nous inocule d'autres saloperies pour faire du fric.

L’histoire de la polio.

La maladie la plus souvent invoquée pour défendre les vaccins est sans conteste la poliomyélite. Par coïncidence, c’est aussi le plus grand mensonge et la plus grande escroquerie médicale de tous les temps. Les toxines causant la « polio » sont bien documentées. Le virus responsable de la polio n’a jamais existé.

1824 : Les ouvriers métallurgistes souffraient depuis des siècles d’une paralysie similaire à la polio, causée par le plomb et l’arsenic présents dans les métaux qu’ils travaillaient. Le scientifique anglais John Cooke observe : « Les fumées de ces métaux, ou leur réception en solution dans l’estomac, provoquent souvent des paralysies ».

1890 : Aux États-Unis, on commence à pulvériser de l’arséniate de plomb jusqu’à 12 fois par été pour tuer le carpocapse des pommes.

1892 : Des épidémies de polio commencent à se produire dans le Vermont, une région de culture de pommes. Dans son rapport, l’inspecteur du gouvernement, le Dr Charles Caverly, note que les parents signalent que certains enfants tombent malades après avoir mangé des fruits. Il déclare que « la paralysie infantile se produit généralement dans des familles comptant plusieurs enfants, et comme aucun effort n’a été fait pour les isoler, il est très probable qu’elle n’est pas contagieuse » (un seul enfant de la famille ayant été touché).

1907 : L’arséniate de calcium est utilisé principalement sur les cultures de coton.

1908 : Dans une ville du Massachusetts comptant trois usines de coton et des vergers de pommiers, 69 enfants tombent soudainement malades de paralysie infantile.

1909 : Le Royaume-Uni interdit les importations de pommes en provenance des États-Unis en raison de la présence de résidus importants d’arséniate de plomb.

1921 : Franklin D. Roosevelt développe la polio après avoir nagé dans la baie de Fundy, au Nouveau-Brunswick. La toxicité de l’eau pourrait être due à des écoulements polluants.

1943 : Introduction du DDT, un pesticide neurotoxique. Au cours des années suivantes, son utilisation se généralise dans les foyers américains. Par exemple, du papier peint imprégné de DDT a été placé dans les chambres d’enfants.

1943 : Une épidémie de polio dans la ville britannique de Broadstairs, dans le Kent, est liée à une laiterie locale où les vaches étaient lavées au DDT.

1944 : Albert Sabin rapporte qu’une cause majeure de maladie et de décès des troupes américaines basées aux Philippines était la poliomyélite. Les camps militaires américains y sont pulvérisés quotidiennement avec du DDT pour tuer les moustiques. Les colonies philippines voisines n’ont pas été touchées.

1944 : Le NIH rapporte que le DDT endommage les mêmes cellules de la corne antérieure qui sont endommagées dans la paralysie infantile.

1946 : Gebhaedt montre que la saisonnalité de la polio est en corrélation avec la récolte des fruits.

1949 : Le Dr Morton Biskind, endocrinologue, praticien et chercheur médical, constate que le DDT provoque « des lésions de la moelle épinière similaires à celles de la polio humaine ».

1950 : Le directeur médical de l’hygiène industrielle de la santé publique américaine, J.G. Townsend, note la similitude entre l’empoisonnement au parathion et la polio et pense que certaines polio pourraient être causées par la consommation de fruits ou de légumes contenant des résidus de parathion.

1951 : Le Dr Biskind traite ses patients atteints de polio comme des victimes d’empoisonnement, en éliminant les toxines de la nourriture et de l’environnement, en particulier le lait et le beurre contaminés par le DDT. Le Dr Biskind écrit : « Bien que les jeunes animaux soient plus sensibles aux effets du DDT que les adultes, dans la mesure où la littérature disponible est concernée, il ne semble pas que les effets de telles concentrations sur les nourrissons et les enfants aient même été pris en compte ».

1949-1951 : D’autres médecins déclarent avoir du succès dans le traitement de la polio avec des antitoxines utilisées pour traiter les empoisonnements, le dimercaprol et l’acide ascorbique. Exemple : Le Dr. F. R. Klenner rapporte : « Lors de l’épidémie de poliomyélite en Caroline du Nord en 1948, 60 cas de cette maladie ont été pris en charge… Le traitement consistait en des doses massives de vitamine C toutes les deux à quatre heures. Les enfants jusqu’à quatre ans recevaient une injection de vitamine C par voie intramusculaire… Tous les patients étaient cliniquement bien portants au bout de 72 heures ».

1950 : Le Dr Biskind présente au Congrès américain des preuves que les pesticides sont la principale cause des épidémies de polio. Il est rejoint par le Dr. Ralph Scobey qui déclare avoir trouvé des preuves évidentes d’empoisonnement en analysant les traces chimiques dans le sang des victimes de la polio.

Commentaire : C’était un non-lieu. La théorie de la causalité virale ne devait pas être remise en question. Les carrières d’éminents virologues et d’autorités sanitaires étaient menacées. Les idées de Biskind et Scobey sont tournées en ridicule.

1953 : Les vêtements sont rendus imperméables aux mites en les lavant dans de l’EQ-53, une formule contenant du DDT.

1953 : Le Dr Biskind écrit : « On savait déjà en 1945 que le DDT était stocké dans les graisses corporelles des mammifères et qu’il apparaissait dans leur lait… pourtant, loin d’admettre une relation de cause à effet entre le DDT et la polio qui est si évidente et qui, dans n’importe quel autre domaine de la biologie, serait immédiatement acceptée, pratiquement tout l’appareil de communication, tant profane que scientifique, a été consacré à nier, dissimuler, supprimer, déformer et tenter de convertir en son contraire cette preuve accablante. La diffamation, la calomnie et le boycottage économique n’ont pas été négligés dans cette campagne ».

1954 : Une législation reconnaissant les dangers des pesticides persistants est promulguée, et l’élimination progressive du DDT aux États-Unis s’accélère parallèlement à un transfert des ventes de DDT vers les pays du tiers monde.

(Notez que l’élimination progressive du DDT coïncide avec le début de la vaccination généralisée contre la polio. Cela dit, les cas de polio ne montent en flèche que dans les communautés qui acceptent le vaccin antipoliomyélitique, car ce dernier contient des métaux lourds et d’autres toxines, de sorte que le récit de la paralysie recommence. Comme les vaccins contre la polio provoquent d’énormes pics de polio, le public mal informé demande davantage de vaccins contre la polio et le cycle s’emballe de manière exponentielle).

1956 : l’American Medical Association impose à tous les médecins agréés de ne plus classer la polio comme telle. Tous les diagnostics de polio sont rejetés au profit du syndrome de Guillian-Barre, de la PFA (paralysie flasque aiguë), de la paralysie de Bell, de l’infirmité motrice cérébrale, de la SLA (maladie de Lou-Gehrig), de la SEP, de la MD, etc. Ce tour de passe-passe a été fabriqué dans le seul but de donner au public l’impression que le vaccin contre la polio avait réussi à faire reculer la polio ou à l’éradiquer. Le public a mordu à l’hameçon et, jusqu’à ce jour, de nombreux arguments en faveur des vaccins sont alimentés par le mensonge fabriqué concernant l’éradication de la polio par le vaccin.

1962 : Publication de Silent Spring de Rachel Carson.

1968 : Abandon de l’homologation du DDT aux États-Unis.

2008 : La paralysie flasque aiguë (PFA) fait toujours rage dans de nombreuses régions du monde où l’utilisation de pesticides est élevée, et où le DDT est toujours utilisé. La PFA, la sclérose en plaques, la paralysie de Bell, l’infirmité motrice cérébrale, la sclérose latérale amyotrophique (maladie de Lou Gehrig) et le syndrome de Guillain Barré sont tous des diagnostics de type « panier de crabes », aux symptômes similaires, liés à l’empoisonnement par les métaux lourds et à une charge toxique élevée.

2008 : L’OMS déclare sur son site web : « Il n’y a pas de remède à la polio. Ses effets sont irréversibles ».

Conclusion

La croyance moderne selon laquelle la polio est causée par un virus est une tragédie permanente pour les enfants du monde. Les fonds publics sont gaspillés pour des vaccins inutiles et dangereux alors que les enfants pourraient être traités avec des antitoxines. Un débat sur le mythe de la vaccination est justifié, ainsi qu’une enquête complète sur le véritable programme exécuté contre l’humanité, impliquant la science, les produits chimiques, les vaccins, le domaine médical en général et le gouvernement.

Sources via :

Algae Barn Coupon codes for my Farm Hands

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My 600 Gallon Hulk reef is powered by @algaebarn 💪💪. One step closer to creating a live ecosystem with biodiversity that’s full of benefits for my reef and picky fish. I used All Algae Barn products to bring my 600 to life. I started my reef will all dead sand and rock. Here are some before and after pictures of a dead reef to a thriving reef today. This is how I made my reef come to life with biodiversity I added live coralline algae in a bottle the Pink Fusion and the Purple Helix to get my rocks to start growing the coralline algae plus next I added The Ultimate Refugium Starter Pack

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One of the big yardsticks that reef aquarists commonly use to determine the health of a developing system (and particularly its readiness for stony coral culture) is coralline algae growth. These encrusting rhodophytes (red algae) give live rock an attractive, natural appearance and thwart the growth of ugly, less desirable hair and film algae. The easiest and surest way to get fast, early coralline algae growth is with Coralline Algae in a Bottle. Here, you get a choice of living pink (Pink Fusion®) or purple (Purple Helix®) corallines! Each product boasts several species of viable coralline algae spores. What's more, each includes live beneficial nitrifying bacteria! There is no faster way to turn your bare base rock into beautiful and vividly colored live rock.

Coralline Information:

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My 600 gallon before adding Algae Barn products.

Hulk Reef after adding Algae barn products

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600 GALLON PROGRESSION VIDEO

Virtual Meeting With The Brooklyn Aquarium Society

PatB Oneshot: We’re Just Mice

A/N: This is my first time writing for Pinky and the Brain! I was inspired after reading skimmingsurface’s and SylviaW1991’s fics because their characterizations are just phenomenal. Hope you enjoy!

FFN, A03

They liked torturing him with aggravating experiments. Another insipid maze that Brain could navigate with his eyes closed. The only deviation from the norm was that a normal mouse had been selected to run the maze with him instead of Pinky.

There wasn’t much of a difference between Pinky and a normal mouse’s usual finishing times though.

The lab tech roughly deposited Brain and the other mouse at the start of the maze, then rushed off to chat with a female coworker. Several mounted video cameras were stationed at the junctions, but the lights along their sides remained off.

They weren’t being observed and there would be no proper recordings either. The tech would have to falsify his results. It was unprofessionalism to the highest degree.

“A complete waste of time,” Brain grumbled. He itched to double-check his calculations in time for tonight’s plan. His estimations needed to be flawless, otherwise it could prove to be their downfall when he used humanity’s desire to protect endangered species against them.

“Come, Pinky,” he called out of habit, not fully expecting Pinky to follow him. His wayward associate would inevitably find the ceiling fascinating and stray off the correct path.

His words were met with a feeble squeak, and Brain suddenly found it disconcerting to be in a maze where he wouldn’t hear Pinky’s strange verbal patterns. Perhaps he was relying too much on muscle memory. The other mouse sniffed the air and shuffled away, disappearing around a corner.

Brain headed in the opposite direction. He knew better than to rely on the cheese scent, which would disappear in a few minutes once his nose became desensitized to it. If Pinky were here, he’d be able to identify the type of cheese by smell alone. Brain only knew how to scent rotten cheese because Pinky would ingest it without regard for potential food poisoning.

Pinky, Pinky, Pinky. He still managed to be an annoyance even without his physical presence!

“Out of sight, out of mind,” Brain muttered, though the phrase didn’t seem applicable when Pinky was involved. “Concentrate on the plan.”

First, the emotional story. He and Pinky would appeal to the National Wildlife Federation and present themselves as the last of the mus musculus intelligentus subspecies. They’d narrowly escaped being crushed under a bulldozer tearing down the forests of Northern California at ages too young to be separated from their parents. Banding together to survive, they taught themselves how to forage until a scientist caught them in a trap for research. They were taken to ACME Labs and genetically enhanced after enduring numerous cruel experiments. Finally, they decided to use their newfound ability to communicate with humans and share their story.

Once those seeds were planted, he’d allow their story to be circulated across The New York Times, National Geographic, and all the other major news and magazine organizations. Humans would be on their knees, begging to see the famous mus musculus intelligentus duo!

Then Brain would reveal the final stage: demand justice from the United Nations for the wrongs done to their species. And the only justice he’d accept was in the form of being crowned world leader. He wouldn’t settle for anything less.

Perhaps he’d create a labyrinth designed to stimulate people’s minds once he was ruler. He could easily create a far better maze than the ones he was forced to endure.

The pathways were predictable as always. It only took one left turn and two more rights before he reached the end of the maze. The two cheese balls weren’t attached to any electrical wires this time, but Brain disliked eating food used as an incentive for completing a task. He was a sentient creature and would never lower himself to baser instincts.  

He couldn’t help but entertain the idea of smuggling one of the cheese balls back to the cage. Pinky would be exuberant and prattle on about how it was the best cheese he’d eaten in his life even though he ate cheese whenever it was available to him.

Brain quickly pushed that image out of his mind. Normal food pellets didn’t have much nutritional value. Pinky was just eating an adequate source of calcium. It was vital to keep his energy level up so he could participate in their quests for world domination.

He settled against the cardboard wall, resigning himself to being stuck until the scientists clocked out for the day. Assuming someone bothered to remove him from the maze, of course. Not that he’d have any trouble finding his own way out.

“Hydrogen, helium, lithium, beryllium,” Brain recited. He had to occupy his mind somehow. His current environment was unsuitable for inspiring plans.

He’d just gotten to bismuth on his second recitation of the periodic table when he heard the angry footfalls. A livid red face loomed above him, and Brain only had a split second to recognize the incompetent lab tech before a sweaty hand seized his entire head and jerked him upward.

Brain twisted in the man’s vicegrip, attempting to bite the thumb so he could make his displeasure known. But his teeth snapped at empty air instead, his body slamming into a hard counter. Slightly dazed, Brain took a moment to rub his temples, clearing the black spots in his peripheral vision.

An irritatingly familiar cry of “narf” brought his senses back completely, just in time to see the normal mouse dangling by its tail, oddly limp and quiet in the lab tech’s hand.

The lab tech stomped over to a wastebasket and dropped the mouse into the plastic lining below. The mouse’s head flopped at an angle that shouldn’t have been possible with its anatomy.

Brain gripped the edge of the countertop as the lab tech threw scrap paper over the mouse’s unmoving body.

It was dead from a broken neck, a barbaric and senseless murder that would receive no justice.

The lab tech retreated into a different section of the lab, as if he hadn’t just committed an act of animal cruelty.

And a heartbroken sob from across the room told Brain he hadn’t been the only witness.

                                                O – O – O – O – O  

“Don’t get too attached. That one’s getting inoculated with a virus tomorrow.”

“Useful as snake food, not much else.”

“They’re just mice. We can always get more.”

The murderer had gone home. The other scientists had clocked out hours ago, unaware of the dead mouse buried in a heap of scrap paper without a shred of dignity.

Brain clutched the pencil, writing out a series of linear equations and engrossing himself in the familiar letters and numbers.

Equations were simple. Logical questions with logical solutions. Patterns that were set, established, and unable to be proven wrong.

Numbers didn’t have emotions.

Which was precisely the reason Brain wanted to deal with numbers before he had to deal with the living antithesis to logic and objectivity.

But nightfall was approaching fast, the last of the sun’s rays disappearing over the horizon. He couldn’t waste more time thinking about the corpse of a rodent he never knew.

Unlock the cage. Collect Pinky. Review plan. Bop Pinky for interrupting explanation. Implement plan.

Brain mentally repeated the simple steps as he retrieved his notebook and a paperclip, ignoring how he couldn’t hear his cagemate running on the squeaky wheel. He usually told Pinky to be quiet several times by now. But there hadn’t been a reason to say it once tonight.

He was annoyed by both the presence and absence of Pinky’s background noise, and the paradox confused and bothered him.

Brain approached the cage with his paperclip. Pinky’s ear twitched, but his gaze remained on the small garbage bin.

Pinky had the perfect vantage point to see everything in the room. His posture was hunched, his usual cheer replaced by an unnatural melancholic demeanor.

Brain was supposed to be the melancholy one. Never Pinky. That wasn’t how their friend…ahem, associative relationship worked.

Forcing himself to think about the plan, Brain straightened one end of the paperclip and jammed it into the keyhole, carefully listening for the soft click.

“Pinky,” Brain called as the cage door swung open. “It’s time to go over tonight’s plan.”

Pinky jumped, a hand thrown over his chest in shock. His blue eyes were round and shiny with tears, the fur around his cheeks damp.

His appearance took Brain aback too, and they stared at each other for an excruciatingly long time.

After what seemed like an eternity, Pinky finally broke the silence with an agonizing wail, throwing himself at Brain at a speed that even light would’ve envied.

“Ba-Brain! I thought you were a goner!” Pinky cried, winding his lanky body around Brain and clinging so tightly that it felt like he was being crushed by a furry boa constrictor. Tears spilled onto Brain’s head, and he quickly flattened his ears so the moisture didn’t slide into his auditory canals. “That…that mean ol’ techie was super mad and it wasn’t the fun fun silly-willy type of mad either! Layla told him no, and he said she owed him cause he helped her carry stuff and then the girls walked out all huffy. Then he stomped around for a while and plucked you and the other mouse up like spring chickens. The other mouse’s head flip-flopped all over the place. Poit, if my head did that I would be dizzier than a whirlywind!”

Pinky’s ramble dissolved into syllables one could only find in a Scrabble dictionary. Realizing Pinky had a sort of loose grasp on the situation but was barely coherent, Brain decided he needed to take control now before the blubbering proved too much.

He glanced at his notebook, the numbered steps open and inviting, but he’d never hammer his plan through Pinky’s genetically modified skull in his current emotional state.

“Pinky, cease your babbling this instant or I shall be forced to hurt you,” Brain managed to choke out despite Pinky’s iron grip on his entire body. Slowly, Pinky released him, but kept close. Brain inhaled deeply, his lungs screaming for precious oxygen. “Just for the record, your head can’t reproduce those motions and should never be capable of it while you breathe.”

Pinky blinked. “Were we recording?”

Brain sighed, grabbing Pinky’s nose and tugging him down so that they were eye level. “I was preoccupied in the maze and my surroundings prevented me from having the perspective you had. I want you to start from the top. And please try to be more coherent this time.”

“More confetti this time, got it,” Pinky nodded. “Well, the techie plopped you in the maze with the other mouse and zoomed right outta there when Layla walked by.”

“The new hire?” Brain asked. It was rare for seasoned employees to take interest in rookies, which contributed to the lab’s high turnover rate.

“Narf, that’s her! It’s so lovely of her to clean out our cage!” Pinky exclaimed. And it was even rarer to find employees who had a tiny notion for a lab animal’s living conditions. Most people just wanted their paychecks.

“At the cost of our sleep and my plans,” Brain muttered. Layla didn’t pick them up by their tails, an unusual trait for an ACME employee, but he still disliked how she came in early and disrupted his sleep and brainstorming sessions for new plans. Besides, Pinky did a perfectly adequate job of keeping their cage tidy. He didn’t require assistance from humans. “Continue.”

“He gave her a rose, but it was smooshy and plastic-y,” Pinky’s nose wrinkled. “Must’ve sat down on it too. Said he liked her and wanted a date. Bit old for her if you ask me.”

Brain turned away from Pinky, fixing his gaze on the wall above that accursed wastebasket. “And she said no. Then he lost his temper,” he finished, his own anger threatening to spill over. But he pushed it back. Not yet. Put the events in chronological order first.  

“They yelled an awful lot, Brain,” Pinky whimpered. “I could hear them over here, clear as egg yolk. I couldn’t hear my wheel squeak, and you know how loud my wheel squeaks. Layla was crying awfully hard and a bunch of the women had to help her leave. Didn’t you hear them?”

It was an honest question, but Brain didn’t want to answer. Had he really been so focused on taking over the world that he never noticed how this entire mess built up in the first place?

“He snapped that mouse’s neck,” Brain said, his voice sounding strange to his own ears. “And killed him. Because he couldn’t accept her refusal.”

By some stroke of dumb luck, Pinky made it out unscathed.

But it could’ve been Pinky…

It could’ve easily been Pinky.

“Layla’s favorite mouse in the whole wide lab,” Pinky whispered, his voice breaking. “She called him Basil. And she doesn’t know he’s…you know.”

Brain didn’t reply, turning his attention to his notebook instead. He had to focus on the plan now. And when he ruled the world, he’d have the power to enact laws and reform entire systems to prevent further desecrations and injustices from ever happening again.

And then he remembered the entire foundation for the plan.

Step One: Send message to the National Wildlife Federation. Appeal to pathos. Example opening statement: “We’re just mice. The last of the mus musculus intelligentus subspecies. We watched our brethren die because of human activity.”

Revise as needed.

Brain’s vision blurred, the paper crinkling in his hands. Someone’s voice called to him, but they would’ve had better luck speaking through a soundless vacuum.

We’re just mice.

Disposable living models to humans. Cosmic playthings to the universe.

We’re just mice.

Given sentience and no chance to make a difference in the world.

We’re just mice.

Whose minds and hearts would waste away, as if they never existed at all.

                                             O – O – O – O – O  

Brain didn’t remember what happened next. One moment he was reading the plan, the next he was in Pinky’s warm embrace, surrounded by a pile of shredded paper.

One of Pinky’s hands pressed Brain’s head to his heart, the fast yet strong thump-thump-thump resounding and soothing to his desperate mind. The other hand rubbed gentle circles into Brain’s back.

Pinky’s chest was damp, but he didn’t seem to care. He hummed a little tune, keeping his eyes tilted up to prevent his own glistening tears from falling.

“Poit. You ripped up your own plan thingy,” Pinky said, his voice trembling. “And you were angry crying. That mean techie hurt you, Brain. You can get madsad all you want. I’ll be here.”

Brain pressed his face into Pinky’s chest, an act he would consider mortifying under normal circumstances, yet his irrational side won out. “We’re just mice,” he said, pointedly ignoring Pinky’s uncomfortable observations on his emotions. “We hardly matter in the grand scheme of things.”

Pinky’s mouth curled into an obstinate pout. “You matter to me. You’re the smartest mouse I know. The smartest smartie candy ever.”

The words were oddly phrased, but sincere. Brain began to feel uncomfortably warm, and he stepped away before his emotions started making his body react in strange ways.

“I…appreciate your assistance, Pinky,” Brain admitted. “But tonight’s plan isn’t feasible. Humans don’t care enough to preserve our species’ dignity, last living individuals or not.”

“Layla cares,” Pinky replied. “She’ll cry when she finds Basil tomorrow morning. And she won’t stop being sad. I wish we could help her not be sad anymore, Brain.”

Brain shook his head. “There’s only so much you’re capable of, Pinky. She might reconsider her employment here because of the lab tech’s actions. There’s a high probability we may never see her again.”

He wouldn’t be accomplishing much tonight. But Brain didn’t want to sleep yet. Instead he gathered the shredded paper, keeping the written words face down so he didn’t have to see the heavy reminders of his mortality.

He was almost through with his self-appointed task when he spotted Pinky drawing closer to the wastebasket. There was a reverence in Pinky’s movements as he balanced on his toes, long arms reaching towards the rim. Crumpled paper spilled out as Pinky carefully tipped over the wastebasket.

Brain dropped the scraps of his plan, not caring if he kicked them off the counter as he rushed over to Pinky. Only Pinky would be stupid enough to believe there was something they could do in this awful mess.

Pinky tossed aside a forgotten report, uncovering the corpse, which somehow seemed bigger when he’d run the maze alongside Brain.

The dead mouse was named Basil, according to Pinky. Not a letter and number designation, or a colorful string of profanity when someone tried to use uncooperative animals in their experiments, but a real name.

Pinky dragged the lower half of Basil’s body out of the wastebasket, panting heavily since Basil’s stiffened paws scraped against the floor and required more exertion to move. Basil’s neck wasn’t flopping anymore, but it was locked into a crooked, unnatural angle.

“He’s stiff, Brain,” Pinky said, his voice hitching as he tried to move one paw into a more comfortable position. “How do we help him relax?”

Unwilling to explain the concept of rigor mortis to Pinky, Brain decided to change the subject. “What are you doing, Pinky?”

“He oughta be comfy,” Pinky said, a tear slipping down his face. A silent sob wracked his body, but Pinky somehow held on. “The bin isn’t a nice place to rest. It’s too prickly. And he’ll wind up in the big stinky trash mountain. He should sleep somewhere nice.”

Brain didn’t want to admit it, but Pinky was right. Basil would be thrown into a garbage truck and taken to a landfill to rot in the next few days if they left his body here. Or someone who took contamination procedures seriously would find Basil and throw him into a biohazard bag, like he was just another leftover bacteria culture.

Both disposal methods were unsettling, to say the least.

“There’s a beautiful tree outside,” Pinky continued. “With roots big enough to play hide and seek under. Do you think he’d like that, Brain?”

Basil wouldn’t like anything anymore. He was dead.

But Brain’s curt reply died on his tongue when he found his companion watching him with hopeful eyes, looking at him like he held all of life’s answers in his hands.

“He’d appreciate it very much, Pinky.”

                                               O – O – O – O – O  

Basil was laid to rest in a cushioned jewelry box. Pinky wrote the name on the lid in permanent Sharpie. He insisted on it. Brain let him, though it resulted in the top being covered in misspellings. But Pinky’s determination shone through.

They sealed the box shut with tape, protecting the body from predators and other forms of harm. Brain made sure to wind the tape around several times, knowing Pinky would be distraught if something managed to pry it open and damage Basil.

Pinky cried during the entire journey to the tree, but he refused to relinquish his hold on the box.

There was a hollow where the trunk connected to the roots. Large enough for Pinky to squeeze himself and the box through, but small enough that nobody else would be able to disturb Basil’s final resting place. They’d have to cut down the tree for that, which hopefully wouldn’t happen for a very long time.

Brain waited outside the hollow, underneath the vast canopy of the night sky. He didn’t look to the stars, as he was prone to do on some nights when he needed to think for a while. There would be plenty of opportunities for him to contemplate his existence in the future.

Pinky crawled out of the hollow, his fur caked with dirt, leaves, and tears. Brain brushed a few leaves off Pinky’s fur, letting them flutter gently to the ground.

“Don’t worry, Brain,” Pinky said, as if Brain was the emotional wreck who required comforting. “The streets are paved with cheese in heaven.”

“How unsanitary,” Brain muttered.

Pinky giggled, a tiny one that was probably inappropriate for the occasion, but it was enough. He wanted to stay out for a while longer, but Brain had something else he wanted to do before the night was over.

They cleaned themselves in the sink, then Pinky left to make tea with honey and lemon. After an emotional trainwreck of the day and night, Brain was looking forward to a thimble to settle his nerves.

In the meantime, he drew up the termination papers.

Aggression not conducive for safe workplace.

The humans would believe it was for harassment, which suited Brain just fine. He refused to let that neanderthal of a lab tech anywhere near Pinky.  

He rejoined Pinky on the counter. There were two steaming hot thimbles and several torn sticky notes next to him.

“Layla should know,” Pinky said, tongue sticking out as he attempted to spell ‘tree’.

“Keep it anonymous,” Brain replied.

But he transcribed the message between sips of tea anyway.

Pinky didn’t know Layla on a personal level. He would gain no reward, reap no benefits from his actions, yet her feelings mattered to him.

Pinky never shared a cage with Basil, never knew him when he was alive either. Even deceased, Basil’s comfort mattered to him.

And Pinky had proven time and time again that Brain mattered to him. Brain could forget, but Pinky never would.

Just a mouse, but an important mouse who deserved the world.

A/N: When I was in middle school, I went to a summer camp. At some point, the boys’ cabin decided to stuff a dead mouse into one of those long Pringles cans and leave it outside of the girls’ cabin. I was the first to find it, though I think I just left the can where I found it. I felt pretty bad for the mouse though.

I was almost tempted to use that in the story, but poor little Basil suffered enough.

Can you tell I love these two by how much I make them cry?

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ANTIOXIDANT - SODIUM D- ERYTHORBATE

1. Introduction

D-sodium erythorbate (d-sodium erythorbate), also known as sodium erythorbate, is a new type of bio-type food anti-oxidant anti-corrosion fresh-keeping color aid. It can prevent the formation of carcinogens in pickled products - nitrosamines, and eradicate the discoloration, peculiar smell and turbidity of food and beverages. Widely used in antisepsis, preservation and color enhancement of meat, fish, vegetables, fruits, wine, beverages and canned food

D-sodium erythorbate is white to yellow-white crystalline granule or crystalline powder, odorless and tasteless, and decomposes at a melting point above 200°C; it is quite stable when exposed to air in a dry state. However, it will oxidize with air, metal, heat and light in aqueous solution. It is easily soluble in water. The solubility at room temperature is 16g/100ml. It is almost insoluble in ethanol. The pH value of 1% aqueous solution is 6.5-8.0

D-sodium erythorbate, molecular formula: C6H7NaO6. Molecular weight: 198.11, melting point 200°C. White or slightly yellowish crystalline granules or powder, odorless, slightly salty, soluble in water (about 7mL of water can dissolve 1g). The dry state is stable in the air, and it is easy to deteriorate when it encounters air, trace metals, heat and light when it is in aqueous solution

Physiological effect

The role of ascorbic acid is only 1/20 of that of ascorbic acid; but its role in lowering blood pressure, diuresis, liver glycogen production pigment excretion, detoxification, etc. is roughly the same as that of ascorbic acid.

method

Using glucose as raw material, inoculate Pseudomonas fluorescens bacilli, and ferment with aeration to obtain calcium α-ketogluconate, after acidification and calcium removal, add methanol and a small amount of sulfuric acid for esterification to obtain solid methyl gluconate. Dissolve the ester in methanol, add sodium metal, heat the mixture to form a precipitate of sodium isoascorbate, separate, and then refine to obtain the product

Application field

Sodium D-erythorbate

1. In meat products: as a color development aid, maintain color, prevent the formation of nitrosamines (such as nitrite), improve flavor, and the cut is not easy to fade. Pickled pickles: maintain color and improve flavor.

2. Frozen fish and shrimp: keep the color and prevent the fish surface from oxidation to produce rancid smell.

3. Beer and wine: add after fermentation to prevent odor and turbidity, maintain color and fragrance, and prevent secondary fermentation

4. Fruit juices and sauces: add it when bottling to maintain natural VC, prevent fading, and maintain the original flavor.

5. Fruit storage: Spray or use with citric acid to maintain the color and flavor and extend the storage period.

6. Canned products: add to the soup before canning to keep the color and fragrance.

7. When used in bread, it can maintain the color and natural flavor of the bread and extend the shelf life without any toxic side effects.

8. China's "Hygienic Standards for the Use of Food Additives" stipulates that it is used for bread and instant noodles. The maximum usage amount is 0.2g/kg, and the maximum usage amount for soup and meat products is 1.0g/kg.

my country's "Hygienic Standards for the Use of Food Additives" (GB2760-2011) stipulates that it can be used in beer with a maximum dosage of 0.04g/kg; meat products with a maximum dosage of 0.5g/kg; wine and juice drinks with a maximum dosage of 0.15g/kg ; For canned fruits and vegetables, canned meat, jam, and frozen fish, the maximum dosage is 1.0g/kg.

In practical application, it is often widely used in food as an antioxidant and antiseptic preservative. In the process of pickling meat products, it can be used to replace vitamin C as a color development aid, and at the same time reduce the amount of sodium nitrite and ensure product quality. During fruit processing, it can prevent fruit from changing color. It can also be used to keep vegetables fresh. Adding isovitamin C sodium before beer bottling can prolong the shelf life of beer and still maintain the original clarity and flavor of beer. To prevent fish oxidation, immerse the fish before freezing in 0.1%~0.5% sodium isovitamin C solution for several minutes, or spray with 0.1%~0.2% aqueous solution

Instructions

The dosage for meat products is 0.5~0.8/kg. For frozen fish, soak with 0.1%-0.6% aqueous solution before freezing. The dosage for beverages such as fruit juice is 0.01%~0.025%. Canned apple sauce, 0.15g/Kg (use alone or in combination with ascorbic acid), luncheon meat, cooked minced meat, cooked pork foreleg, cooked ham, 0.5g/kg (use alone in combination with ascorbic acid and its sodium salt, Calculated by ascorbic acid), peaches, applesauce: 2g/kg canned fruit 0.75-1.5g/l, natural juice 0.08-0.11g/l, beer 0.03g/l.

BB Inoculants Material - Ferro Silicon Magnesium

Inoculants are added in liquid cast iron in order to provide the best and consistent characteristics in the final casting. They are used to control matrix structure and avoid casting defects. Inoculants can be found under several grain size distributions to satisfy the location of the inoculant addition within the foundry process. Those locations of inoculant addition are known as in furnace, in ladle, in stream or in mould.

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Female Vitality Blueprint Reviews - Does Female Vitality Blueprint beneficial? Read More

As grown-ups, we as a whole expertise significant nutrients and minerals are to our eating regimens yet what might be said about our kids? In spite of the energy they frequently have, Female Vitality Blueprint Reviews are consuming with smoldering heat what the body needs to advance wellbeing and fend off contamination. Make sure to give your kid nutrients for them to keep up with great wellbeing during the developing years.

As numerous awful air borne microbes that lead to ailment become resistant themselves to our inoculation techniques, the time is ideal to begin adding nutrients to your eating routine. L-ascorbic acid, E and others will frequently accomplish other things to ward off a cold or influenza in certain individuals than anything a specialist infuses in our body so why not win the battle before it could in fact start?

Do you as of now have a lacks of few supplement? In the event that you don't know, you want to visit your PCP for a blood test to find out. Whether it is B12 or calcium, understanding what supplements you want to build up on will assist you with rapidly feeling improved than at any other time.

In the event that you notice that you have been feeling odd in the wake of taking specific nutrients and minerals, it would be smart for you to let them be. Many individuals accept that nutrients make no side impacts, yet this isn't reality. Rather than managing sick impacts, you ought to search for one more method for getting what you want.

Potassium can be tracked down in dried organic products, grains, milk and beans. This significant mineral is utilized to treat Menière's illness, menopause side effects, joint inflammation, muscle throbs, Alzheimer's, digestive problems and sensitivities. Studies have shown that potassium might be gainful to those experiencing hypertension and may assist with forestalling stroke.

After you go out to shop, try to store your new foods grown from the ground in the cooler. Keeping your produce cold assists the food with holding significant nutrients, minerals and proteins. Buy new produce frequently and eat it everyday to maximize these food varieties. The more supplements you get from your food, the less you really want from supplements.

It is a fantasy that you can get every one of the supplements you require by simply eating the right food varieties. Provided that you ate a lot of vegetables and organic product, entire grains and proteins, and fat and carbs, essentially the entire day, might you at some point get what you really want. Supplements are an unquestionable necessity.

However you may not comprehend what happens inside your body, you can absolutely affect how well it functions. The article you just read gave you some incredible data on nutrients and their purposes. Add these tips to your day to day daily schedule and you will receive the benefits of a solid body that is appropriately made due.

Reference Link :

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Understanding the Differences: Barium Inoculant and Calcium Inoculant in Foundry Applications

In the metal casting and foundry industry, inoculants play a crucial role in improving the quality and performance of cast iron. Among the various inoculants used, Barium Inoculant and Calcium Inoculant are widely recognized for their ability to refine microstructure, enhance graphite formation, and improve mechanical properties. However, each inoculant offers distinct benefits depending on the casting requirements.

What is an Inoculant?

An inoculant is a crucial additive used in foundry metallurgy to refine the microstructure of cast iron and improve its mechanical properties. It is introduced into the molten metal before solidification to control the formation of graphite and carbide structures, ultimately enhancing the quality of the final casting.

Inoculants primarily serve three key functions:

Graphite Nucleation – They promote the formation of graphite in cast iron, ensuring a fine, evenly distributed microstructure.

Chill Reduction – By preventing the formation of unwanted carbides, inoculants help in reducing chill depth, making the cast iron more machinable.

Improved Mechanical Properties – They enhance the strength, ductility, and wear resistance of the casting by modifying the graphite structure and reducing defects.

Commonly, inoculants contain elements like barium (Ba), calcium (Ca), strontium (Sr), aluminum (Al), and zirconium (Zr), which influence graphite nucleation and carbide control. The choice of inoculant depends on the type of iron being cast (grey iron or ductile iron), section thickness, and desired mechanical properties.

Barium Inoculant: Properties and Benefits

Barium-based inoculants are particularly effective in reducing chill formation and enhancing graphite nucleation in cast iron. They are often used for:

Grey and ductile iron casting to refine graphite structure

Reducing carbide formation and promoting a uniform microstructure

Improving machinability and consistency in thin-section castings

Providing long-lasting inoculation effects, reducing fading over time

Calcium Inoculant: Properties and Benefits

Calcium-based inoculants, on the other hand, are known for their ability to control the solidification process and improve metallurgical properties. Their advantages include:

Promoting fine graphite dispersion and reducing shrinkage

Reducing gas porosity in molten metal, leading to defect-free casting

Enhancing mechanical strength and impact resistance

Controlling carbide formation to ensure better ductility

Key Differences Between Barium and Calcium Inoculants

Choosing the Right Inoculant for Foundry Applications

The selection of an inoculant depends on specific foundry needs. If the goal is strong chill reduction and better long-term inoculation effects, barium inoculants are the preferred choice. On the other hand, if fine graphite dispersion, porosity control, and improved strength are the priorities, calcium inoculants are more suitable.

Conclusion

Both Barium Inoculants and Calcium Inoculants play essential roles in improving cast iron quality, but their effectiveness depends on the casting conditions and the required properties of the final product. Foundries must carefully evaluate their applications and metallurgical requirements to select the most suitable inoculant for superior cast iron performance.

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