CalGonJim 7/14 MONDAY 428am. 7/15 1140am Tuesday . These are the nutrients and amino acids enzymes I will be using and a new way to use germination station experiment . mesh fits 10 inch planter can be outside tent safe from bugs!!! 7/16 245pm putting her in 4 inch glass cube thing or maybe Bud Cups, or put the rock wolll in the Bud Cup

CalGonJim 7/21 12AM MONDAY. YOU DONT MESS AROUND WITH JIM. 2am. I've been thinking and I believe that growing weed may be the only sport where Whites could do better than Blacks, FINALLY one for my side.🎉🎉🎉 7/24 1040pm....ROCKWOLL SUCKS. I SHOULD HAVE GONE WITH DIRT..... 7/26 515am. she's veging with 2 other grows. 2ml per L AN Con. and Aminos and MB

CalGonJim 7/28 12am. now im stuck with a Jim Croce theme for some f reason ...shes going to be fine in a month. 7/29 1245am will delete this soon, fuck this 7/31 320am Adding methylene blue (MB) to the combination of essential amino acids (EAAs), proline, trimethylglycine (TMG), glutamine, and L-glycine for cannabis plants introduces a compound with unique properties that may influence plant physiology, primarily through its roles as a redox agent, photosensitizer, and potential biostimulant. While methylene blue is more commonly studied in medical and aquatic contexts, its use in plant cultivation, including cannabis, is less documented, and specific studies on this exact combination are absent. Below, I’ll outline the potential effects of methylene blue on cannabis plants, its interactions with the other compounds, and the likely outcomes, drawing from available plant science knowledge and inferred mechanisms. Given the novelty of MB in this context, recommendations are cautious and speculative where direct evidence is lacking. Effects of Methylene Blue on Cannabis Plants Methylene blue (C16H18ClN3S) is a synthetic dye with redox, antimicrobial, and photosensitizing properties. Its effects on plants depend on concentration, application method, and environmental conditions: * Antioxidant and Redox Activity: At low concentrations (e.g., 0.1–10 µM or ~0.03–3 mg/L), MB acts as a redox mediator, scavenging reactive oxygen species (ROS) and protecting cells from oxidative stress caused by drought, high light, or salinity. In cannabis, this could enhance stress tolerance, particularly in high-intensity indoor grows or outdoor environments with temperature fluctuations. * Photosynthesis Enhancement: MB can act as an electron carrier in photosynthetic pathways, potentially improving electron transport in photosystem II. Studies on algae and some plants suggest low doses (e.g., 1–5 µM) may boost chlorophyll fluorescence and photosynthetic efficiency, potentially increasing cannabis biomass and bud quality. * Antimicrobial Effects: MB has antifungal and antibacterial properties, which could protect cannabis roots or foliage from pathogens like Pythium or Botrytis (bud rot). This is particularly relevant in hydroponic systems or humid environments. * Stress Mitigation: MB may stabilize cellular membranes under stress, similar to proline and TMG, potentially reducing damage from environmental extremes. * Potential Toxicity at High Doses: At higher concentrations (10–50 µM or ~3–15 mg/L), MB can generate ROS via photodynamic action under light, causing oxidative damage to plant tissues. This makes precise dosing critical. Application Notes: Two drops of MB (assuming a standard 1% solution, ~10 mg/mL, where 1 drop ≈ 0.05 mL) in, e.g., 1 liter of water yields ~1 mg/L (3 µM), a low concentration likely safe for foliar or root application. However, exact dosing depends on solution strength and volume. Synergistic Effects with EAAs, Proline, TMG, Glutamine, and L-Glycine Adding MB to the existing mix may enhance or modulate the effects on cannabis plants: 1. Enhanced Stress Resilience: * MB + Proline/TMG/Glycine: Proline, TMG, and glycine act as osmoprotectants and antioxidants, while MB scavenges ROS and stabilizes redox balance. Together, they could significantly improve cannabis tolerance to drought, heat, or salinity, reducing leaf wilting or nutrient stress in challenging environments (e.g., outdoor grows or high-EC hydroponics). * Glutamine/EAAs Synergy: Glutamine and EAAs support glutathione production, which complements MB’s antioxidant effects, potentially amplifying protection against oxidative stress from high light or nutrient imbalances. 2. Growth and Biomass: * MB + EAAs/Glutamine/Glycine: EAAs, glutamine, and glycine drive protein synthesis and nitrogen assimilation, while MB’s potential to enhance photosynthesis could provide the energy needed for these processes. This may lead to increased vegetative growth, larger leaves, and potentially denser buds in cannabis. * Proline Contribution: Proline supports tissue integrity, complementing MB’s membrane-stabilizing effects, which could enhance overall plant vigor. 3. Secondary Metabolite Production: * MB + Glutamine/TMG/Glycine: MB’s role as a photosensitizer may influence metabolic pathways by altering redox states, potentially enhancing synthesis of cannabinoids (e.g., THC, CBD) or terpenes. Glutamine and glycine contribute to precursor pathways (e.g., GABA, purines), while TMG’s methyl donation supports enzyme activity. This combination could theoretically increase terpene diversity or cannabinoid yield, though direct evidence is lacking. * EAAs Role: Methionine (an EAA) and glycine may support sulfur-based terpenes, with MB potentially amplifying metabolic efficiency via improved photosynthesis. 4. Nutrient and Pathogen Management: * MB + Glycine/EAAs: Glycine’s chelating properties and EAAs’ nutrient uptake enhancement could work with MB’s antimicrobial effects to improve nutrient availability and protect roots from pathogens in hydroponic or soil systems. * TMG/Glutamine: TMG’s cellular hydration and glutamine’s role in nitrogen metabolism may enhance MB’s ability to maintain cellular function under stress, improving overall nutrient efficiency. Potential Risks and Considerations * Toxicity Risk: MB at concentrations 10 µM (~3 mg/L) can produce ROS under light, damaging chloroplasts or cell membranes. Two drops in 1 liter (~1 mg/L) is likely safe, but overuse or concentrated solutions could harm cannabis, causing leaf burn or stunted growth. * Absorption Competition: MB may interact with amino acids during uptake, potentially reducing the efficacy of EAAs, glutamine, or glycine if applied simultaneously. Stagger applications (e.g., MB foliar spray, amino acids via root drench) to minimize this. * Nitrogen Overload: Adding MB to an already nitrogen-rich mix (EAAs, glutamine, glycine) increases the risk of toxicity, especially in cannabis, which is sensitive to excess nitrogen. Monitor for dark green leaves, clawing, or reduced flowering. * Photodynamic Effects: MB’s photosensitizing properties require careful application timing. Apply during low-light periods (e.g., early morning or evening) to avoid ROS generation in high-intensity grow lights. * Limited Cannabis Data: MB’s effects are mostly studied in algae, bacteria, or medical contexts, not cannabis. Its benefits are speculative, and plant-specific responses may vary by cultivar (e.g., sativa vs. indica). Practical Recommendations * Dosing: * MB: Two drops of 1% MB solution (~1 mg/L or 3 µM) per liter of water for foliar spray or root drench. Start with 1 drop/L to test tolerance. * EAAs: 150–300 mg/L * Glutamine: 250–500 mg/L * Proline: 50–100 mg/L * TMG: 0.5–1 g/L * Glycine: 100–500 mg/L * Apply twice weekly during vegetative growth or early flowering, adjusting based on plant response. * Application: * Foliar Spray: Apply MB and amino acids in low-light conditions to avoid phototoxicity. Use a fine mist to cover leaves evenly. * Root Drench: Suitable for hydroponics or soil, ensuring MB is diluted to avoid root damage. * Stagger Applications: Apply MB separately from amino acids (e.g., MB in the morning, amino acids in the evening) to reduce uptake competition. * Monitoring: Check for signs of stress relief (greener leaves, faster growth) or toxicity (yellowing, wilting). Test on a few plants first, especially for MB, as cannabis sensitivity is unknown. * Synergy with Nutrients: Pair with balanced NPK fertilizers and micronutrients (e.g., magnesium, iron) to support MB’s photosynthetic effects and glycine’s chelating properties. * Cultivation Context: * Hydroponics: Use lower MB doses (~0.5 mg/L) to avoid nutrient lockout or microbial disruption in sterile systems. * Soil: Ensure healthy soil microbiota, as MB’s antimicrobial effects could impact beneficial microbes if overused. * Cultivars: Sativa-dominant strains may benefit more from MB’s stress mitigation, while indicas may respond better to amino acid-driven growth. Evidence Gaps * No Specific Studies: No research addresses MB combined with EAAs, proline, TMG, glutamine, and glycine in cannabis. MB’s effects are extrapolated from algae, bacteria, or limited plant studies (e.g., Arabidopsis, lettuce). * Cannabinoid/Terpene Impact: MB’s influence on secondary metabolites is speculative. Its redox and photosynthetic effects may enhance terpene or cannabinoid synthesis, but cannabis-specific data are needed. * Long-Term Effects: MB’s long-term impact on cannabis growth, soil microbiota, or bud quality is unknown. Short-term studies suggest low doses are safe, but chronic use requires caution. * X Search Results: No recent posts on X discuss MB in cannabis cultivation with this combination. General posts mention MB for water treatment or medical uses, not plant applications. Conclusion Adding two drops of methylene blue (~1 mg/L) to a mix of EAAs, proline, TMG, glutamine, and glycine likely enhances cannabis stress tolerance, photosynthetic efficiency, and pathogen resistance, complementing the growth-promoting and nutrient-uptake benefits of the amino acids and TMG. The combination may improve vegetative vigor, bud quality, and resilience to environmental stressors, with potential (but unconfirmed) effects on cannabinoid and terpene production. However, MB’s photodynamic and antimicrobial properties require precise dosing and application timing to avoid toxicity or microbial disruption. Start with low doses, test on a small scale, and monitor closely, consulting a cannabis cultivation expert for optimization. If you provide the MB solution concentration, application volume, or specific cannabis strain, I can refine dosing recommendations. Want me to search again for MB-related plant studies or focus on a specific aspect (e.g., MB’s photosynthetic effects)? 🚨. 🚨 Adding a nitric oxide (NO) capsule containing L-arginine (200 mg), arginine alpha-ketoglutarate (AKG) 2:1 extract (200 mg), L-citrulline HCl (200 mg), L-citrulline malate extract (100 mg), and beta-alanine (40 mg) to the existing mix of essential amino acids (EAAs), proline, trimethylglycine (TMG), glutamine, L-glycine, and methylene blue (MB) for cannabis plants introduces compounds that primarily influence nitrogen metabolism, stress response, and potentially secondary metabolite production. These components are known for their roles in boosting nitric oxide production in animals, but their effects on plants, including cannabis, are less studied. Below, I’ll outline the potential effects of each component in the NO capsule on cannabis plants, their interactions with the existing mix, and the likely outcomes, drawing from plant science principles and inferred mechanisms due to limited cannabis-specific data. Effects of Nitric Oxide Capsule Components on Cannabis Plants 1. L-Arginine (200 mg): * Role in Plants: L-Arginine is a precursor to nitric oxide (NO) in plants via the nitric oxide synthase-like pathway. NO regulates growth, stress response, and secondary metabolism. In cannabis, arginine (50–500 mg/L) may enhance root development, flowering, and stress tolerance by modulating NO signaling. * Stress Response: NO from arginine mitigates oxidative stress from drought, salinity, or heavy metals, potentially protecting cannabis in harsh environments. * Secondary Metabolites: NO influences terpene and alkaloid synthesis, possibly increasing cannabinoid (e.g., THC, CBD) or terpene production in cannabis buds, though direct evidence is limited. 2. Arginine AKG 2:1 Extract (200 mg): * Role in Plants: Arginine alpha-ketoglutarate combines arginine with alpha-ketoglutarate, a TCA cycle intermediate. In plants, it may enhance nitrogen assimilation and energy metabolism. Alpha-ketoglutarate could support carbon metabolism, boosting photosynthesis and growth in cannabis. * Synergy: Provides additional arginine for NO production and supports metabolic pathways, potentially amplifying arginine’s effects. 3. L-Citrulline HCl (200 mg) and L-Citrulline Malate Extract (100 mg): * Role in Plants: L-Citrulline is a precursor to arginine in the urea cycle, indirectly boosting NO production. In plants, citrulline (50–500 mg/L) accumulates under stress (e.g., drought), acting as a nitrogen storage compound and osmoprotectant. In cannabis, it may enhance stress tolerance and nitrogen use efficiency. * Malate Contribution: Citrulline malate provides malic acid, which supports the TCA cycle and photosynthesis, potentially increasing cannabis biomass and energy for growth. * Cannabis-Specific: Citrulline may improve root and shoot growth in hydroponic systems by enhancing nitrogen metabolism. 4. Beta-Alanine (40 mg): * Role in Plants: Beta-alanine is a non-protein amino acid and precursor to pantothenate (vitamin B5) and coenzyme A, which are critical for lipid and secondary metabolite synthesis. In plants, it may enhance stress tolerance by supporting metabolic pathways. Its role in cannabis is less studied but could indirectly support terpene or cannabinoid production via coenzyme A. * Limited Impact: At 40 mg, the dose is low, so effects may be minimal compared to other components. Application Notes: The NO capsule components (total 740 mg) are typically dissolved for human consumption, but for cannabis, they’d be diluted in water (e.g., 740 mg in 1–10 L, yielding ~74–740 mg/L). A lower concentration (e.g., 100–500 mg/L) is safer for foliar or root application to avoid nitrogen overload. Synergistic Effects with EAAs, Proline, TMG, Glutamine, L-Glycine, and Methylene Blue The NO capsule components may enhance the existing mix’s effects on cannabis plants: 1. Growth and Biomass: * Arginine/Citrulline + EAAs/Glutamine/Glycine: Arginine and citrulline boost NO production and nitrogen metabolism, complementing EAAs, glutamine, and glycine’s roles in protein synthesis and nutrient uptake. This could enhance cannabis vegetative growth, root development, and bud size. * Alpha-Ketoglutarate + Glutamine: Alpha-ketoglutarate supports the TCA cycle, amplifying glutamine’s role in nitrogen assimilation, potentially increasing photosynthetic efficiency and biomass. * Beta-Alanine: May support lipid metabolism, contributing to cell membrane formation and bud quality, though its low dose limits impact. 2. Stress Resilience: * Arginine/Citrulline + Proline/TMG/MB: Arginine and citrulline’s NO production enhances stress signaling, complementing proline and TMG’s osmoprotectant roles and MB’s antioxidant effects. Glycine’s glutathione production further bolsters stress tolerance. This mix could significantly improve cannabis resilience to drought, heat, or high light, reducing leaf wilting or nutrient stress. * Cannabis-Specific: Ideal for outdoor grows or high-intensity indoor setups where environmental stressors are common. 3. Secondary Metabolite Production: * Arginine/Citrulline + Glutamine/TMG/Glycine: NO from arginine and citrulline may upregulate pathways for cannabinoid and terpene synthesis, as NO influences phenylpropanoid and alkaloid pathways in plants. Glutamine, glycine, and TMG support precursor synthesis (e.g., GABA, purines, methylation), potentially enhancing THC, CBD, or terpene yields. * Beta-Alanine: Supports coenzyme A production, which may aid terpene synthesis, though its low dose may limit impact. * MB Synergy: MB’s photosynthetic enhancement could provide energy for NO-driven secondary metabolism, amplifying cannabinoid production, though this is speculative. 4. Nutrient Efficiency and Pathogen Resistance: * Arginine/Citrulline + Glycine/EAAs: Arginine and citrulline improve nitrogen use efficiency, complementing glycine’s chelating properties and EAAs’ nutrient uptake enhancement, optimizing cannabis growth in hydroponics or nutrient-poor soils. * MB Synergy: MB’s antimicrobial properties may synergize with NO’s role in plant defense signaling, protecting cannabis from pathogens like Botrytis or Pythium. Potential Risks and Considerations * Nitrogen Overload: The NO capsule adds arginine, citrulline, and beta-alanine, all nitrogen-containing compounds, to an already nitrogen-rich mix (EAAs, glutamine, glycine). This increases the risk of nitrogen toxicity in cannabis, causing dark green leaves, clawing, or reduced flowering. Dilute to 100–500 mg/L total and monitor plant response. * Absorption Competition: Arginine, citrulline, EAAs, glutamine, and glycine may compete for root or foliar uptake, reducing efficacy. Stagger applications (e.g., NO capsule components in the morning, others in the evening) or alternate days. * MB Interaction: MB’s redox activity may interact with NO from arginine/citrulline, potentially amplifying or disrupting signaling if doses are unbalanced. Keep MB at ~1 mg/L (e.g., two drops of 1% solution per liter). * Beta-Alanine Limited Impact: At 40 mg, beta-alanine’s effects may be negligible, as plant studies use higher concentrations (e.g., 100–500 mg/L) for measurable benefits. * Toxicity Risk: High doses of arginine or citrulline (1000 mg/L) may disrupt nitrogen balance, while MB (3 mg/L) could cause photodynamic damage. Test low doses first. * Cultivar Variability: Sativa-dominant cannabis may benefit more from stress mitigation (arginine, citrulline, proline, TMG, MB), while indicas may respond better to growth promotion (EAAs, glutamine, glycine). Practical Recommendations * Dosing: * NO Capsule: Dissolve one capsule (740 mg total: 200 mg L-arginine, 200 mg arginine AKG, 200 mg L-citrulline HCl, 100 mg L-citrulline malate, 40 mg beta-alanine) in 2–10 L water (~74–370 mg/L). Start at 100–200 mg/L for foliar or root application. * EAAs: 150–300 mg/L * Glutamine: 250–500 mg/L * Proline: 50–100 mg/L * TMG: 0.5–1 g/L * Glycine: 100–500 mg/L * MB: ~1 mg/L (e.g., two drops of 1% solution per liter) * Apply twice weekly during vegetative growth or early flowering. * Application: * Foliar Spray: Apply during low-light periods (e.g., early morning) to avoid MB phototoxicity. Combine NO capsule components with amino acids for balanced uptake. * Root Drench: Suitable for hydroponics or soil, ensuring low MB concentrations to avoid microbial disruption. * Staggering: Apply NO capsule + MB separately from amino acids/TMG to minimize uptake competition (e.g., NO/MB in morning, others in evening). * Monitoring: Watch for nitrogen toxicity (dark, curled leaves) or stress relief (greener leaves, robust growth). Test on a few plants first, especially for MB and NO components, due to limited cannabis data. * Synergy with Nutrients: Pair with balanced NPK fertilizers and micronutrients (e.g., magnesium, iron) to support MB’s photosynthetic effects and glycine’s chelating properties. * Cultivation Context: * Hydroponics: Use lower doses (~100 mg/L NO capsule, 0.5 mg/L MB) to avoid nutrient lockout or microbial imbalance. * Soil: Maintain healthy microbiota, as MB and high nitrogen inputs could disrupt beneficial microbes. * Cultivars: Adjust based on strain needs (e.g., stress-prone sativas vs. nutrient-hungry indicas). Evidence Gaps * No Specific Studies: No research addresses this exact combination (NO capsule + EAAs, proline, TMG, glutamine, glycine, MB) in cannabis. Effects are inferred from individual compound studies in plants (e.g., arginine for NO, MB in algae). * Cannabinoid/Terpene Impact: NO and MB may enhance secondary metabolism, but direct effects on THC/CBD or terpenes are unconfirmed. Cannabis-specific trials are needed. * Beta-Alanine Role: At 40 mg, beta-alanine’s impact is likely minimal, as plant studies use higher doses. * Long-Term Effects: Long-term impacts of MB and NO precursors on cannabis growth or soil health are unknown. Short-term use appears safe at low doses. Conclusion Adding a nitric oxide capsule (L-arginine, arginine AKG, L-citrulline, citrulline malate, beta-alanine) to EAAs, proline, TMG, glutamine, glycine, and MB likely enhances cannabis growth, stress tolerance, and nutrient efficiency by boosting NO signaling, nitrogen metabolism, and antioxidant defenses. The mix may improve vegetative vigor, bud quality, and resilience to environmental stressors, with potential (but unconfirmed) benefits for cannabinoid and terpene production. However, nitrogen overload, absorption competition, and MB’s phototoxicity require careful dosing (e.g., 100–200 mg/L NO capsule, 1 mg/L MB). Test on a small scale, monitor closely, and consult a cannabis cultivation expert for optimization. If you provide the application volume (e.g., liters of water), specific strain, or growth stage, I can refine dosing further. Want me to search for studies on NO precursors in plants or focus on a specific aspect (e.g., NO’s role in cannabinoid synthesis)? ..... 8/3 IF I COULD SAVE TIME IN A BOTTLE BEING EASILY DISTRACTED WOULDNT BE SUCH ABIG FUKCING PROBLEM AND I WOULDNT KILL SO MANY GOD DMAN PLANTS.... GODDMANIT. OMG....THAT WAS MORE BEAUTIFUL THAN THE ORIGINAL....IM SO FUCKING AWESOME....NOW IM GOINT TO FILL BOTTLES WITH TIME AND THROW THEM AT PEOPLE

CalGonJim 8/4 130am MONDAY. 8/7 218pm I will keep this going but updates are in 🍓🍰🍌🍆🥊🤨🌿🍑🍪🍎 for now until harvest. She is doing GREAT!!!!! 8/10 5:38am..... WHY IS A PHOTO FLOWERING???? DID I PUT THE WRONG CONTAINER BACK IN THE WRONG PACK????? NO....THE ONLY EXPLANATION IS TO WORK DAY AND NIGHT TO FIND SOMEONE ( NOT ME!!!) TO BLAME!!!😂😜.

CalGonJim 8/11, 1:17 AM Monday I’m beginning to think I put the wrong seed in or something happened. This is not a photo. It looks like an auto so I don’t know what I AUTO do? get it. Maybe I should fill more bottles with time and throw them at people while I’m figuring this out?👍