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      <title>Eportfolio 3 by Lee Zhi Qi</title>
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      <language>en-us</language>
      <pubDate>2025-05-31 14:13:11 UTC</pubDate>
      <lastBuildDate>2025-06-11 09:15:20 UTC</lastBuildDate>
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      <item>
         <title>Local and Scientific Name
</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474566605</link>
         <description><![CDATA[<p>Local Name: Nerve Plant, Mosaic Plant</p><p>Scientific Name: <em>Fittonia albivenis</em></p><p>Family: Acanthaceae</p><p><em>Fittonia albivenis</em> is commonly referred to as the "nerve plant" or "mosaic plant" due to its striking leaf venation pattern, which resembles a network of nerves. This characteristic feature makes it one of the most recognizable foliage plants in indoor gardening and horticulture.</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:17:56 UTC</pubDate>
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      <item>
         <title>Distribution</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474566981</link>
         <description><![CDATA[<p><em>Fittonia albivenis</em> is native to the humid tropical rainforests of South America, particularly found in Peru, Colombia, Ecuador, and parts of northern Bolivia (Christenhusz &amp; Byng, 2016). In its natural habitat, it thrives on the shaded forest floor where it receives filtered sunlight and consistently high humidity levels. These environmental conditions have shaped its physiological preferences and sensitivity, making it dependent on indirect light and moist air when cultivated outside its native range.</p><p>Globally, <em>Fittonia</em> has become a widely distributed ornamental plant, commonly found in terrariums, indoor plant collections, and botanical gardens. Its popularity is due not only to its aesthetic value but also to its compact growth habit and adaptability to indoor environments with proper care (Brickell, 2016).</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:18:45 UTC</pubDate>
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         <title>Botanical Description
</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474567627</link>
         <description><![CDATA[<p><em>Fittonia albivenis</em> is a small, creeping, herbaceous perennial that belongs to the family Acanthaceae. The plant typically grows to a height of 10–15 cm, although its trailing stems can spread more extensively across the soil or pot surface. It is characterized by its dark green, oval-shaped leaves adorned with prominent white, pink, or red veins, depending on the cultivar. This unique venation gives the plant its iconic "mosaic" appearance (Brickell, 2016).</p>]]></description>
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         <pubDate>2025-05-31 14:20:08 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474567627</guid>
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         <title></title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474568523</link>
         <description><![CDATA[<p>The plant prefers loamy, well-draining soil and environments with high humidity and indirect light. While it can survive in moderate indoor light, it thrives best in bright, filtered light conditions. The stems are soft and pliable, often rooting at the nodes, which allows the plant to spread horizontally.</p><p><em>Fittonia</em> occasionally produces small, tubular flowers that are pale yellow to purple, although flowering is rare when grown indoors. Its most distinctive physiological feature is its dramatic wilting response when it lacks water; however, it is capable of quickly recovering once watered. This trait makes it an excellent subject for plant physiology demonstrations, especially on the topic of turgor pressure and water stress (Taiz et al., 2015).</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:22:07 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474568523</guid>
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      <item>
         <title>Uses and Benefits</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474568839</link>
         <description><![CDATA[<p><strong>1. Ornamental Use</strong></p><p><em>Fittonia albivenis</em> is widely grown as an ornamental foliage plant due to its attractive leaf patterns and compact size. It is especially favored for terrariums and dish gardens, where it can benefit from stable humidity and controlled lighting. Its colorful leaves make it a popular choice for both indoor and commercial plant displays (Brickell, 2016).</p><p><strong>2. Air Purification</strong></p><p>Similar to many other tropical plants, <em>Fittonia</em> contributes to indoor air purification. A NASA study by Wolverton et al. (1989) found that certain houseplants can absorb indoor air pollutants such as formaldehyde, benzene, and xylene. While <em>Fittonia albivenis</em> was not directly tested in that study, its classification among indoor foliage plants suggests it may offer similar air-purifying effects.</p><p><strong>3. Educational Value</strong></p><p>Due to its high sensitivity to water availability, <em>Fittonia</em> is frequently used in plant physiology labs and classroom demonstrations. When deprived of water, the plant wilts visibly within hours due to the loss of turgor pressure. This response is reversible and provides a clear, visual example of plant water relations and cellular hydration (Taiz et al., 2015). Students can observe real-time changes in leaf posture and hydration, making <em>Fittonia</em> an excellent model for understanding basic plant physiology.</p><p><strong>4. Therapeutic and Psychological Benefits</strong></p><p>Several studies have indicated that interacting with indoor plants can have positive psychological effects, such as lowering stress levels, improving focus, and enhancing overall mood (Bringslimark et al., 2009). <em>Fittonia albivenis</em>, with its lush foliage and manageable size, is particularly suitable for homes, hospitals, schools, and offices where a visual connection with greenery is desired.</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:22:45 UTC</pubDate>
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         <title>1. Water</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474569487</link>
         <description><![CDATA[<p><strong>Roles of water&nbsp;</strong></p><p>Plants need water to make their own food through a process called photosynthesis. In this process, they use sunlight, carbon dioxide from the air, and hydrogen from water taken in by the roots. As a result, they produce oxygen and food for themselves. This exchange happens through tiny openings on the leaves called stomata. The water also helps carry nutrients and sugars made during photosynthesis from the roots to other parts of the plant like the stems, leaves, and flowers to help it grow and reproduce. Water helps support the structure of plant cells by creating pressure inside them, called turgor pressure. This pressure keeps the plant firm but flexible, so it can bend with the wind or move its leaves to face the sun and get more light for photosynthesis (<em>How plants use water, </em>2021).</p><p>Water is important for moving nutrients from the soil to the leaves through the plant’s xylem. If there isn’t enough water, the plant can’t absorb enough nutrients, which can cause poor growth, yellowing leaves, and nutrient problems.</p><p>Water is important for plants to do transpiration. Transpiration plays a key role in plant health. It helps move water and minerals to all parts of the plant. By constantly releasing water, the plant keeps its internal water levels balanced. This process supports osmosis, keeps cells firm, and helps them divide and grow. Transpiration also creates a pulling force that moves water upward from the roots. Some helpful salts collect on the leaf surface, keeping them moist. It also cools the plant by letting water evaporate from the leaves. Overall, proper transpiration supports healthy plant growth (Admin, 2023).</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:24:01 UTC</pubDate>
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         <title>Deficiency effect of water
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         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474569756</link>
         <description><![CDATA[<p>When plants don't get enough water, even just a little, they often grow slowly and stay small. Some leaves may lose their shine and look dull, which is an early sign of stress. Grasses are usually the first to show they’re drying out, the footprints stay visible on the lawn because the blades don’t bounce back. If the water shortage continues for a long time, plants can stop growing, wilt permanently, or produce fewer fruits and flowers. Their leaves, flower buds, and blooms may change color or look unhealthy. If the stress lasts too long, the plant can eventually die (<em>Drought and water stress,</em> 2024).</p><p>When plants don’t get enough water, their ability to do photosynthesis is affected. To save water, they close tiny pores on their leaves called stomata, but this also reduces the amount of carbon dioxide they can take in, which is needed to make food. Without enough water, plant cells lose pressure, making it harder for leaves to grow and stay open to sunlight. Too much light during this time can also damage parts of the plant that help with photosynthesis. In response, the plant slows down the production of photosynthesis-related proteins. If the water shortage is combined with heat, it can make things even worse. All these changes lower the plant’s ability to make energy and grow properly (Bray, 2001).</p><p>When plants face a lack of water, it can greatly affect their flowering process. Drought conditions often cause plants to start flowering earlier than usual as a way to quickly complete their life cycle under stress. However, this early flowering is usually followed by a higher rate of flower drop, where flower buds and blossoms fall off before developing into fruits. This happens because the plant has less energy and nutrients due to reduced photosynthesis, making it harder to support healthy flower growth. Sensitive plant types, such as LE 1 and COTH 2, show more flower loss under drought stress. In addition, drought reduces the activity of important enzymes like Sucrose Phosphate Synthase (SPS), which is needed to transport sugars to growing flowers. With less sugar available, the flowers are more likely to drop off. Overall, water stress results in fewer flowers, more flower shedding, and lower crop yields. However, some plant varieties like LE 118 and LE 57 are more drought-tolerant. They are better at keeping their enzyme activity and reducing flower loss, which helps them produce more fruits even during dry conditions (R. Sivakumar, &amp; S. Srividhya., 2016).</p><p><br></p>]]></description>
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         <pubDate>2025-05-31 14:24:38 UTC</pubDate>
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      <item>
         <title>Group Member </title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474571985</link>
         <description><![CDATA[<ol><li><p>Suzic Anak Eric (81308)</p></li><li><p>Junai Hazel Anak Satu (102638)</p></li><li><p>Bryan Lim Jin Hui (83408)</p></li><li><p>Elizaberth Anak Jawie (103953)</p></li><li><p>Emily Frances Anak Noping (106993)</p></li><li><p> Lee Zhi Qi (84307)</p></li></ol>]]></description>
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         <pubDate>2025-05-31 14:29:16 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3474571985</guid>
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      <item>
         <title>2. Mineral</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486479073</link>
         <description><![CDATA[<p><strong>Roles of Minerals</strong></p><p>Minerals play an important role as inorganic nutrients that directly influence the physiological development of <em>Fittonia albivenis</em> and would overall plant health. Minerals are generally absorb by the plant roots in ionic forms and again, from the root zone, are utilized by the plant to perform many metabolic and structural functions. One essential macronutrient is nitrogen (N), which is significant in amino acid, protein, nucleic acid, and chlorophyll synthesis. In <em>Fittonia albivenis</em>, sufficient nitrogen supports the large, green plant growth, as well as brighter, more pronounced venation on the leaves (Taiz et al., 2015). Likewise, phosphorus (P), is involved in root and storage organ development and energy molecule transfer processes like ATP as an example for cellular activities such as respiration and photosynthesis (Taiz et al., 2015). Potassium (K) is the final macronutrient and plays a role in varying functions like relieving and regulating stomatal movements, enzyme activity, and balancing osmotic potential levels. Potassium aids in water movement for the plant and also supports overall stress tolerance, even with fluctuating indoor conditions (Brady &amp; Weil, 2010).</p><p>There are additional inorganic nutrients that are important. Calcium (Ca) is key for cementing cell walls, stabilizing membranes, and could help avoid deformities in new growth that is needed for stability and to prevent damage. Magnesium (Mg) is at the centre of chlorophyll molecules and therefore is integral and essential for photosynthesis. Magnesium aids carbohydrate metabolism and acts as a cofactor in many enzyme reactions. Iron (Fe) is vital for chlorophyll synthesis and involvement in directional electron transport at the thylakoid membrane during photosynthesis and more so under low-light conditions where <em>Fittonia</em> likely performs even better than higher light conditions. Fixing these essential nutrients through obtained mechanisms, Fe is used in multiple metabolic pathways. Micronutrients such as Zinc, Manganese, and Copper are also essential as it relates to initiating enzyme reactions, hormone production, and prevents oxidation through various defence mechanisms (Marschner, 2012).</p>]]></description>
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         <pubDate>2025-06-11 08:56:26 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486479073</guid>
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         <title>Deficiency effect of minerals</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486479572</link>
         <description><![CDATA[<p>When <em>Fittonia albivenis</em> encounters mineral deficiencies, it can exhibit multiple physiological symptoms commencing with changes to leaf colour and growth. A deficiency of nitrogen will produce general chlorosis, particularly with older leaves, having overall poor leaf development and less vibrant leaves. A poor supply of phosphorus will lead to dark green or purple discoloration of leaves and overall poor root growth, potassium deficiency can derogate edge leaf necrosis in leaves, browning at the edge, and increased susceptibility to pests and environmental stress. Calcium deficiency can have new leaves develop poorly and poor growth of root tips, magnesium deficiency of the plant will create interveinal chlorosis in older leaves, whereby the veins remain green, but the leaf tissue turns yellow (Marschner, 2012). Iron deficiency occurs in younger leaves and shows interveinal chlorosis which leads to pale, almost white leaves with green veins intact.</p><p>These deficiencies will adversely impact the plant's ability to photosynthesize, transport nutrients, and maintain turgor pressure, which is essential for healthy growth and ornamental quality. Because of the high sensitivity of <em>Fittonia</em> to imbalances in the environment and it being grown in a potting medium, it would be prudent to regularly apply a well-balanced dilate liquid fertilizer to sustain the plants mineral needs as it is grown indoors with limited access to soil that has been naturally enriched with minerals (Taiz et al., 2015). This would all assist reduce the loss of compact growth, vibrant colouration and overall function.</p><p><br></p>]]></description>
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         <pubDate>2025-06-11 08:56:52 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486479572</guid>
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         <title>3. Temperature</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486481502</link>
         <description><![CDATA[<p>The physiological functions and normal growth of<em> Fittonia albivenis </em>depend heavily on temperature. This plant thrives in conditions that are stable, warm, and humid by nature. For the best growth, the temperature ought to range between 18°C and 27°C (60°F and 80°F), with 21°C (70°F) being the most optimum. The plant effectively completes metabolic processes like photosynthesis, nutrients transport, and the respiration process within this range of temperatures. Additionally, stable temperatures support the maintenance of enzyme activity and cellular membrane integrity, which helps the plant maintain its compact growth habit and colorful leaves. Since<em> F. albivenis</em> is extremely sensitive to abrupt temperature fluctuations and drafts, it is imperative that cold windows, vents, and heaters be avoided while cultivating indoors. High humidity is just as important as warmth, which is why this plant thrives in terrariums or bathrooms with lots of natural moisture (Bender, 2025).</p><p><br></p>]]></description>
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         <pubDate>2025-06-11 08:58:38 UTC</pubDate>
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      <item>
         <title>Deficiency effect of temperature

</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486481858</link>
         <description><![CDATA[<p>Deviation from the optimal temperature range, especially exposure to extremes, can interfere with development and cause severe physiological stress. According to Hatfield and Prueger (2015), every plant species has a specific temperature threshold for growth, above which performance drastically declines. For<em> Fittonia albivenis</em>, high temperatures (over 27°C) frequently result in leaf curling, dehydration, and rapid senescence, whereas cold stress (below 15°C) causes wilted or darkened leaves and slowed development. Conditions involving low humidity or a water deficit exacerbate these pressures. Extreme temperatures can disrupt critical developmental stages such tissue differentiation or cell expansion, even for brief periods of time (Hatfield &amp; Prueger, 2015). Additionally, erratic temperatures, particularly abrupt changes from day to night or being close to air conditioners, can hinder the plant's ability to recuperate. This vulnerability emphasizes how crucial it is to keep an environment steady and temperate in order to shield<em> F. albivenis </em>from the damaging effects of heat stress and to support its long-term vitality.</p>]]></description>
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         <pubDate>2025-06-11 08:58:57 UTC</pubDate>
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         <title>4. Light</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486482472</link>
         <description><![CDATA[<p>Light is a crucial environmental factor that directly affects the photosynthesis, growth, leaf coloration, and overall health of <em>Fittonia albivenis</em>. As a native of the shaded understory of tropical rainforests in South America, Fittonia has evolved to thrive under low to moderate indirect light conditions. In its natural habitat, it is adapted to thrive under filtered, dappled light, which mimics the conditions found beneath the forest canopy (Huxley et al., 1992).</p>]]></description>
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         <pubDate>2025-06-11 08:59:44 UTC</pubDate>
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         <title>Role of Light </title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486485066</link>
         <description><![CDATA[<p>Light is the energy source for photosynthesis, the process by which plants convert carbon dioxide and water into glucose and oxygen. In Fittonia, adequate light supports:</p><ul><li><p>Chlorophyll production for green pigmentation.</p></li><li><p>Energy generation for growth and cellular function.</p></li><li><p>Development of vibrant leaf vein coloration (white, pink, or red).</p></li></ul><p>According to Taiz et al. (2015), light influences not only photosynthesis but also photomorphogenesis — the way plant form and structure respond to light cues.</p><p><br></p><p><em>Fittonia albivenis</em> prefers bright, indirect light. It can tolerate lower light conditions, but its vibrant leaf coloration and patterns may fade. Direct sunlight should be avoided to prevent leaf scorch. A spot near a window with sheer curtains is ideal.<em>Fittonia albivenis</em> responded best to artificial lighting that mimics natural light in both intensity and spectral balance, particularly combinations that provide both red and blue wavelengths."</p><p>(Lee, Y. H. et al., 2012).<em>Fittonia albivenis</em> thrives best in bright, indirect light. While it can tolerate low light conditions, insufficient lighting may lead to diminished coloration and leggy growth. Conversely, direct sunlight can harm the plant's delicate leaves.<br></p>]]></description>
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         <pubDate>2025-06-11 09:03:09 UTC</pubDate>
         <guid>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486485066</guid>
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         <title>Effects of Light Deficiency and Excess</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486485787</link>
         <description><![CDATA[<p>Too little light	Etiolated (leggy) growth, pale green leaves, weak stems (Taiz et al., 2015)</p><p>Excessive light	Leaf scorching, chlorosis, pigment bleaching (Hogewoning et al., 2010)</p><p>Optimal light	Compact growth, strong leaf turgor, vivid white/pink venation.<br></p><p>Mechanism: Light and Chloroplast Activity</p><p>In low-light environments, chloroplasts migrate to the top cell layers to maximize light capture.</p><p><br/></p><p>Under excess light, they reposition to side walls to reduce damage (Wada et al., 2003).</p><p><br/></p><p>Fittonia albivenis increases light-harvesting complex II (LHCII) expression under low light, enhancing efficiency (Anderson et al., 1995).</p><p><br></p>]]></description>
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         <pubDate>2025-06-11 09:03:52 UTC</pubDate>
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         <title></title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486486496</link>
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         <pubDate>2025-06-11 09:04:28 UTC</pubDate>
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         <title>Reference</title>
         <author>zhiqi0203</author>
         <link>https://padlet.com/zhiqi0203/zauma2wtu5dydff6/wish/3486496973</link>
         <description><![CDATA[<p>Admin. (2023, October 6). <em>Transpiration</em>. BYJUS. <a rel="noopener noreferrer nofollow" href="https://byjus.com/biology/transpiration/">https://byjus.com/biology/transpiration/</a></p><p><br/></p><p><a rel="noopener noreferrer nofollow" href="http://Amazon.com">Amazon.com</a> : Fittonia Albivenis Seeds Nerve Plant, Mosaic Plant Fittonia Verschaffeltii Seeds Perennial Ground Cover Potted Houseplant Indoor 100Pcs Herb Seeds by YEGAOL Garden : Patio, Lawn &amp; Garden. (2025). <a rel="noopener noreferrer nofollow" href="http://Amazon.com">Amazon.com</a>. <a rel="noopener noreferrer nofollow" href="https://www.amazon.com/Fittonia-Albivenis-Verschaffeltii-Perennial-Houseplant/dp/B0BTXWW13S">https://www.amazon.com/Fittonia-Albivenis-Verschaffeltii-Perennial-Houseplant/dp/B0BTXWW13S</a></p><p><br/></p><p>Anderson, J. M., Chow, W. S., &amp; Park, Y. I. (1995). The grand design of photosynthesis: Acclimation of the photosynthetic apparatus to environmental cues. Photosynthesis Research, 46, 129–139. <a rel="noopener noreferrer nofollow" href="https://doi.org/10.1007/BF00020423">https://doi.org/10.1007/BF00020423</a>&nbsp;</p><p><br/></p><p>Bender, S. (2025, April 11). <em>Nerve Plant Is An Easygoing Houseplant Anyone Can Grow</em>. Southern Living. <a rel="noopener noreferrer nofollow" href="https://www.southernliving.com/garden/indoors/nerve-plant">https://www.southernliving.com/garden/indoors/nerve-plant</a></p><p><br/></p><p>Bray, E. A. (2001). Plant response to water‐deficit stress. <em>Encyclopedia of Life Sciences</em>. <a rel="noopener noreferrer nofollow" href="https://doi.org/10.1038/npg.els.0001298">https://doi.org/10.1038/npg.els.0001298</a></p><p><br/></p><p>Brady, N. C., &amp; Weil, R. R. (2010). <em>Elements of the Nature and Properties of Soils</em> (3rd ed.). Pearson.</p><p><br/></p><p>Brickell, C. (2016). <em>The Royal Horticultural Society Encyclopedia of Plants and Flowers</em> (5th ed.). Dorling Kindersley.</p><p><br/></p><p>Bringslimark, T., Hartig, T., &amp; Patil, G. G. (2009). The psychological benefits of indoor plants: A critical review of the experimental literature. <em>Journal of Environmental Psychology</em>, 29(4), 422–433. <a rel="noopener noreferrer nofollow" href="https://doi.org/10.1016/j.jenvp.2009.05.001">https://doi.org/10.1016/j.jenvp.2009.05.001</a></p><p><br/></p><p>Christenhusz, M. J. M., &amp; Byng, J. W. (2016). The number of known plant species in the world and its annual increase. <em>Phytotaxa</em>, 261(3), 201–217. <a rel="noopener noreferrer nofollow" href="https://doi.org/10.11646/phytotaxa.261.3.1">https://doi.org/10.11646/phytotaxa.261.3.1</a></p><p><br/></p><p><em>Drought and water stress</em>. Visit Missouri Botanical Gardens. 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