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Week 9 (Week 1 of flowering) has been a jaw-dropping experience in my Tropical Tangie Ninja Run. Our girl is absolutely killing it! Her luscious green foliage is a sight to behold, and my Lego Ninja buddies are always on point, making sure everything is in order. The excitement escalated as I spotted those little preflowers showing up towards the end of the week. I have a strong hunch that she's going to turn into a flowering monster during the first two weeks! <3 <3 <3 To support this explosive flowering growth, I made some savvy moves in my nutrient game. I decided to switch from my root booster to the fruit booster. Why, you ask? Well, my Tangie is transitioning her focus from root development to bud production. So, it's like shifting gears to give her exactly what she needs to create those magnificent flowers! But that's not all. I also added some P-booster to my nutrient mix. You might wonder why? It's because this little ninja booster is packed with phosphorus, the secret ingredient that stimulates robust flower formation. We want those buds to be big, dense, and super potent! <3 <3 With a canopy as lush as this, I'm already contemplating a potential defoliation around day 21 of flowering. It's like planning my ninja strategy in advance! But let's keep that for the next update hehe. As for her TDS numbers, they might not seem massive at 230, but remember, I'm using those amazing Aptus All-in-One Pellets mixed with the soil. Her main NPK is already packed in there, and these boosters are just giving her that extra ninja kick! With room temperatures at 28.9°C and a humidity level of 62%, the conditions are perfect for our Tangie to thrive. I can't contain my excitement for this epic ninja run! I'm deeply grateful for your unwavering support and the wonderful products from Aptus Holland that have played a crucial role in this journey. You all make this adventure truly special, and I'm thrilled to have you by my side, also of corse a huge SHOUT OUT to Dutch Passion for this incredible oportunity and for the amazing genetics they create and release to the world <3<3<3 Stay tuned for the next update, where we'll witness the true transformation of our Tangie into a flowering ninja goddess! <3 <3 <3 As always thank you all for stopping by, for the love and for it all , this journey of mine wold just not be the same without you guys, the love and support is very much appreciated and i fell honored and blessed with you all in my life<3 <3 <3 #aptus #aptusplanttech #aptusgang #aptusfamily #aptustrueplantscience #inbalancewithnature #trueplantscience #dutchpassion #dogdoctorofficial #legoninjago #growerslove 
 With true love comes happiness <3 <3 <3 Always believe in your self and always do things expecting nothing and with an open heart , be a giver and the universe will give back to you in ways you could not even imagine so <3 <3 <3 Friendly reminder all you see here is pure research and for educational purposes only <3 <3 <3 Growers Love To you All <3 <3 <3 🌿

She's chugging along this week. A few more tirchomes on show and the buds have swelled noticeably. Had to add some scaffolding to support some stems.... On she goes........

15 Noviembre: -Hoy se instaló el sistema de riego "Drip to Waste" que me permitirá hacer riego de precisión, con protocolo "Crop Steering". -Se instalaron sensores de humedad de suelo, para saber cuándo y cuánto regar, el sistema manda datos de humedad de suelo, temperatura y humedad ambiente, etc vía internet a mi celular. -Mañana se comienza con el primer riego de precisión. 17 Noviembre: Segundo día de riego automático, 3.0EC y 5.9pH, las plantas crecen a buen ritmo, las raíces ya están saliendo por los orificios de drenaje a 2 días de transplantadas. 20 Noviembre: Se realizó una pequeña defoliacion de las hojas tipo abanico muy grandes.

The plant has a few retarded leafs for whatever reason, but it's healthy in color and still growing. Nothing to report about though.

08/16/2020 This is my first clone from Red Sky, the mom of all these clones in the tent, (video #1). All others are at different stages of flowering, she is beginning week number 3 of flowering.

Que hay familia, vamos con la cuarta semana de floración de estas Apple Fritter de Zamnesia. La temperatura está entre los 21/24 grados, la humedad está entorno al 55%, y el ph lo mantengo ahora al principio en 6.2, el foco por supuesto está enchufado 12 horas , tener tienen que crecer fuertes. Y aparte añadimos nutrientes de Agrobeta, que no puede faltar semejante gama. Todo correcto hasta ahora, ya cara a la floración veremos cómo avanzan las próximas semanas. Os comento que tengo un descuento y para que compréis en la web de Zamnesia de un 20%, el código es ZAMMIGD2023 The discount 20% and the code is ZAMMIGD2023 https://www.zamnesia.com/ agrobeta: https://www.agrobeta.com/agrobetatiendaonline/36-abonos-canamo Mars hydro: Code discount: EL420 https://www.mars-hydro.com/ Hasta aquí es todo, buenos humos 💨💨💨.

Posting this as I’m on the last few days of the 3rd week from germination Great progress, a lot of roots for such a short period but not too much plant growth, will start watering daily instead of watering every 2-3 days Topped the girls today (Day 18 from germ) and starting to do mainline on all the Bubba kush.

happy and healthy little plant on day 26, im mostly getting smells of pine off this girl so far. hoping for more blueberry to show out

Que pasa familia, vamos con la septima semana de floración de estas Orange Sherbet Fast Flowering, de FastBuds. Agradezco a Agrobeta todos los kits obtenidos de ellos 🙏. Vamos al lío, El ph se controla en 6.2 , la temperatura la tenemos entre 22/24 grados y la humedad ronda el 50%, añadimos ya varios productos de la gama de Agrobeta. Las próximas semanas veremos cómo avanzan. Agrobeta: https://www.agrobeta.com/agrobetatiendaonline/36-abonos-canamo Hasta aquí todo, Buenos humos 💨💨💨

Yellow butterfly came to see me the other day; that was nice. Starting to show signs of stress on the odd leaf, localized isolated blips, blemishes, who said growing up was going to be easy! Smaller leaves have less surface area for stomata to occupy, so the stomata are packed more densely to maintain adequate gas exchange. Smaller leaves might have higher stomatal density to compensate for their smaller size, potentially maximizing carbon uptake and minimizing water loss. Environmental conditions like light intensity and water availability can influence stomatal density, and these factors can affect leaf size as well. Leaf development involves cell division and expansion, and stomatal differentiation is sensitive to these processes. In essence, the smaller leaf size can lead to a higher stomatal density due to the constraints of available space and the need to optimize gas exchange for photosynthesis and transpiration. In the long term, UV-B radiation can lead to more complex changes in stomatal morphology, including effects on both stomatal density and size, potentially impacting carbon sequestration and water use. In essence, UV-B can be a double-edged sword for stomata: It can induce stomatal closure and potentially reduce stomatal size, but it may also trigger an increase in stomatal density as a compensatory mechanism. It is generally more efficient for gas exchange to have smaller leaves with a higher stomatal density, rather than large leaves with lower stomatal density. This is because smaller stomata can facilitate faster gas exchange due to shorter diffusion pathways, even though they may have the same total pore area as fewer, larger stomata. Leaf size tends to decrease in colder climates to reduce heat loss, while larger leaves are more common in warmer, humid environments. Plants in arid regions often develop smaller leaves with a thicker cuticle and/or hairs to minimize water loss through transpiration. Conversely, plants in wet environments may have larger leaves and drip tips to facilitate water runoff. Leaf size and shape can vary based on light availability. For example, leaves in shaded areas may be larger and thinner to maximize light absorption. Leaf mass per area (LMA) can be higher in stressful environments with limited nutrients, indicating a greater investment in structural components for protection and critical resource conservation. Wind speed, humidity, and soil conditions can also influence leaf morphology, leading to variations in leaf shape, size, and surface characteristics. Small leaves: Reduce water loss in arid or cold climates. Large leaves: Maximize light capture in sunny, humid environments. Hairy leaves: Reduce water loss and protect against excessive sunlight. Lobed leaves: May enhance hydraulic conductivity and cooling. Drip tips: Facilitate water drainage from leaves in wet environments. Thick, waxy leaves: Reduce water loss in dry conditions. Environmental conditions significantly affect gene expression in plants. Plants are sessile organisms, meaning they cannot move to escape unfavorable conditions, so they rely on gene expression to adapt to their surroundings. Environmental factors like light, temperature, water, and nutrient availability can trigger changes in gene expression, allowing plants to respond to and survive in diverse environments. Depending on the environment a young seedling encounters, the developmental program following seed germination could be skotomorphogenesis in the dark or photomorphogenesis in the light. Light signals are interpreted by a repertoire of photoreceptors followed by sophisticated gene expression networks, eventually resulting in developmental changes. The expression and functions of photoreceptors and key signaling molecules are highly coordinated and regulated at multiple levels of the central dogma in molecular biology. Light activates gene expression through the actions of positive transcriptional regulators and the relaxation of chromatin by histone acetylation. Small regulatory RNAs help attenuate the expression of light-responsive genes. Alternative splicing, protein phosphorylation/dephosphorylation, the formation of diverse transcriptional complexes, and selective protein degradation all contribute to proteome diversity and change the functions of individual proteins. Photomorphogenesis, the light-driven developmental changes in plants, significantly impacts gene expression. It involves a cascade of events where light signals, perceived by photoreceptors, trigger changes in gene expression patterns, ultimately leading to the development of a plant in response to its light environment. Genes are expressed, not dictated! While having the potential to encode proteins, genes are not automatically and constantly active. Instead, their expression (the process of turning them into proteins) is carefully regulated by the cell, responding to internal and external signals. This means that genes can be "turned on" or "turned off," and the level of expression can be adjusted, depending on the cell's needs and the surrounding environment. In plants, genes are not simply "on" or "off" but rather their expression is carefully regulated based on various factors, including the cell type, developmental stage, and environmental conditions. This means that while all cells in a plant contain the same genetic information (the same genes), different cells will express different subsets of those genes at different times. This regulation is crucial for the proper functioning and development of the plant. When a green plant is exposed to red light, much of the red light is absorbed, but some is also reflected back. The reflected red light, along with any blue light reflected from other parts of the plant, can be perceived by our eyes as purple. Carotenoids absorb light in blue-green region of the visible spectrum, complementing chlorophyll's absorption in the red region. They safeguard the photosynthetic machinery from excessive light by activating singlet oxygen, an oxidant formed during photosynthesis. Carotenoids also quench triplet chlorophyll, which can negatively affect photosynthesis, and scavenge reactive oxygen species (ROS) that can damage cellular proteins. Additionally, carotenoid derivatives signal plant development and responses to environmental cues. They serve as precursors for the biosynthesis of phytohormones such as abscisic acid () and strigolactones (SLs). These pigments are responsible for the orange, red, and yellow hues of fruits and vegetables, while acting as free scavengers to protect plants during photosynthesis. Singlet oxygen (¹O₂) is an electronically excited state of molecular oxygen (O₂). Singlet oxygen is produced as a byproduct during photosynthesis, primarily within the photosystem II (PSII) reaction center and light-harvesting antenna complex. This occurs when excess energy from excited chlorophyll molecules is transferred to molecular oxygen. While singlet oxygen can cause oxidative damage, plants have mechanisms to manage its production and mitigate its harmful effects. Singlet oxygen (¹O₂) is considered a reactive oxygen species (ROS). It's a form of oxygen with higher energy and reactivity compared to the more common triplet oxygen found in its ground state. Singlet oxygen is generated both in biological systems, such as during photosynthesis in plants, and in cellular processes, and through chemical and photochemical reactions. While singlet oxygen is a ROS, it's important to note that it differs from other ROS like superoxide (O₂⁻), hydrogen peroxide (H₂O₂), and hydroxyl radicals (OH) in its formation, reactivity, and specific biological roles. Non-photochemical quenching (NPQ) protects plants from damage caused by reactive oxygen species (ROS) by dissipating excess light energy as heat. This process reduces the overexcitation of photosynthetic pigments, which can lead to the production of ROS, thus mitigating the potential for photodamage. Zeaxanthin, a carotenoid pigment, plays a crucial role in photoprotection in plants by both enhancing non-photochemical quenching (NPQ) and scavenging reactive oxygen species (ROS). In high-light conditions, zeaxanthin is synthesized from violaxanthin through the xanthophyll cycle, and this zeaxanthin then facilitates heat dissipation of excess light energy (NPQ) and quenches harmful ROS. The Issue of Singlet Oxygen!! ROS Formation: Blue light, with its higher energy photons, can promote the formation of reactive oxygen species (ROS), including singlet oxygen, within the plant. Potential Damage: High levels of ROS can damage cellular components, including proteins, lipids, and DNA, potentially impacting plant health and productivity. Balancing Act: A balanced spectrum of light, including both blue and red light, is crucial for mitigating the harmful effects of excessive blue light and promoting optimal plant growth and stress tolerance. The Importance of Red Light: Red light (especially far-red) can help to mitigate the negative effects of excessive blue light by: Balancing the Photoreceptor Response: Red light can influence the activity of photoreceptors like phytochrome, which are involved in regulating plant responses to different light wavelengths. Enhancing Antioxidant Production: Red and blue light can stimulate the production of antioxidants, which help to neutralize ROS and protect the plant from oxidative damage. Optimizing Photosynthesis: Red light is efficiently used in photosynthesis, and its combination with blue light can lead to increased photosynthetic efficiency and biomass production. In controlled environments like greenhouses and vertical farms, optimizing the ratio of blue and red light is a key strategy for promoting healthy plant growth and yield. Understanding the interplay between blue light signaling, ROS production, and antioxidant defense mechanisms can inform breeding programs and biotechnological interventions aimed at improving plant stress resistance. In summary, while blue light is essential for plant development and photosynthesis, it's crucial to balance it with other light wavelengths, particularly red light, to prevent excessive ROS formation and promote overall plant health. Oxidative damage in plants occurs when there's an imbalance between the production of reactive oxygen species (ROS) and the plant's ability to neutralize them, leading to cellular damage. This imbalance, known as oxidative stress, can result from various environmental stressors, affecting plant growth, development, and overall productivity. Causes of Oxidative Damage: Abiotic stresses: These include extreme temperatures (heat and cold), drought, salinity, heavy metal toxicity, and excessive light. Biotic stresses: Pathogen attacks and insect infestations can also trigger oxidative stress. Metabolic processes: Normal cellular activities, particularly in chloroplasts, mitochondria, and peroxisomes, can generate ROS as byproducts. Certain chlorophyll biosynthesis intermediates can produce singlet oxygen (1O2), a potent ROS, leading to oxidative damage. ROS can damage lipids (lipid peroxidation), proteins, carbohydrates, and nucleic acids (DNA). Oxidative stress can compromise the integrity of cell membranes, affecting their function and permeability. Oxidative damage can interfere with essential cellular functions, including photosynthesis, respiration, and signal transduction. In severe cases, oxidative stress can trigger programmed cell death (apoptosis). Oxidative damage can lead to stunted growth, reduced biomass, and lower crop yields. Plants have evolved intricate antioxidant defense systems to counteract oxidative stress. These include: Enzymes like superoxide dismutase (SOD), catalase (CAT), and various peroxidases scavenge ROS and neutralize their damaging effects. Antioxidant molecules like glutathione, ascorbic acid (vitamin C), C60 fullerene, and carotenoids directly neutralize ROS. Developing plant varieties with gene expression focused on enhanced antioxidant capacity and stress tolerance is crucial. Optimizing irrigation, fertilization, and other management practices can help minimize stress and oxidative damage. Applying antioxidant compounds or elicitors can help plants cope with oxidative stress. Introducing genes for enhanced antioxidant enzymes or stress-related proteins over generations. Phytohormones, also known as plant hormones, are a group of naturally occurring organic compounds that regulate plant growth, development, and various physiological processes. The five major classes of phytohormones are: auxins, gibberellins, cytokinins, ethylene, and abscisic acid. In addition to these, other phytohormones like brassinosteroids, jasmonates, and salicylates also play significant roles. Here's a breakdown of the key phytohormones: Auxins: Primarily involved in cell elongation, root initiation, and apical dominance. Gibberellins: Promote stem elongation, seed germination, and flowering. Cytokinins: Stimulate cell division and differentiation, and delay leaf senescence. Ethylene: Regulates fruit ripening, leaf abscission, and senescence. Abscisic acid (ABA): Plays a role in seed dormancy, stomatal closure, and stress responses. Brassinosteroids: Involved in cell elongation, division, and stress responses. Jasmonates: Regulate plant defense against pathogens and herbivores, as well as other processes. Salicylic acid: Plays a role in plant defense against pathogens. 1. Red and Far-Red Light (Phytochromes): Red light: Primarily activates the phytochrome system, converting it to its active form (Pfr), which promotes processes like stem elongation and flowering. Far-red light: Inhibits the phytochrome system by converting the active Pfr form back to the inactive Pr form. This can trigger shade avoidance responses and inhibit germination. Phytohormones: Red and far-red light regulate phytohormones like auxin and gibberellins, which are involved in stem elongation and other growth processes. 2. Blue Light (Cryptochromes and Phototropins): Blue light: Activates cryptochromes and phototropins, which are involved in various processes like stomatal opening, seedling de-etiolation, and phototropism (growth towards light). Phytohormones: Blue light affects auxin levels, influencing stem growth, and also impacts other phytohormones involved in these processes. Example: Blue light can promote vegetative growth and can interact with red light to promote flowering. 3. UV-B Light (UV-B Receptors): UV-B light: Perceived by UVR8 receptors, it can affect plant growth and development and has roles in stress responses, like UV protection. Phytohormones: UV-B light can influence phytohormones involved in stress responses, potentially affecting growth and development. 4. Other Colors: Green light: Plants are generally less sensitive to green light, as chlorophyll reflects it. Other wavelengths: While less studied, other wavelengths can also influence plant growth and development through interactions with different photoreceptors and phytohormones. Key Points: Cross-Signaling: Plants often experience a mix of light wavelengths, leading to complex interactions between different photoreceptors and phytohormones. Species Variability: The precise effects of light color on phytohormones can vary between different plant species. Hormonal Interactions: Phytohormones don't act in isolation; their interactions and interplay with other phytohormones and environmental signals are critical for plant responses. The spectral ratio of light (the composition of different colors of light) significantly influences a plant's hormonal balance. Different wavelengths of light are perceived by specific photoreceptors in plants, which in turn regulate the production and activity of various plant hormones (phytohormones). These hormones then control a wide range of developmental processes.

Start of week 6 flower, banners going strong, massive sativa pheno is starting to fatten up, still a long way to go with it Smaller more indica bushy pheno you can see will be finished sooner, she's starting to glisten from the trichomes forming Hadn't really got a proper whiff of the banner smell till now, damn it smells superb 😎💪

Giorno 46

growing bushy as all hell, lifted lights to try get them to grow vertically more , we got some chubby plants right now lol

Well, those in the catalog died or did not germinate well, apart from that, the 6 seeds without breed that we have saved from good buds that came into my hands germinated well. here I share a little of what could be recorded, as you can see there is a bigger one that was the attempt to germinate the cars with an approximate age advantage of 25 days, with that criterion I will comment on this one in particular and the others in your set. The largest in age also has the largest pot of all of 11 liters approx 3 gallons The 2nd largest is for having the 2nd largest pot of 7 or 8 liters approx 2 gallons The remaining 5 are in pots of 3.5 liters or 1 gallon We also started fighting with the high temperatures due to the weather, which will go down as the months go by in our favor, we turn on lights at night and turn off the lights during the day to compensate, which we will manage just as well as the plants adapt, as will be seen until 3 o'clock 4 week of flowering, which is the one we are currently going through when this diary is being updated