Soilless Culture System Research Articles

Hydroponics: Advancing Sustainable Technologies and Applications in Crop Production with a Focus on Lettuce Cultivation

The pressing need to adopt sustainable, climate-resilient, and resource-efficient agricultural practices has brought hydroponics—a soilless cultivation system—into the spotlight. Lettuce (Lactuca sativa), a popular leafy vegetable, is particularly suited for hydroponic farming due to its high-water content, fast growth cycle, and adaptability. This study explores various hydroponic techniques for lettuce cultivation, focusing on their potential to enhance yield and quality. Key methods such as the nutrient film technique (NFT), deep water culture (DWC), aeroponics, and others are evaluated for productivity, resource efficiency, and scalability. The integration of advanced technologies, including artificial intelligence (AI), precision agriculture, and plant growth-promoting rhizobacteria (PGPR), further strengthens the role of hydroponics as a sustainable approach to urban agriculture and global food security. Comparative analyses demonstrate that adaptive hydroponic systems deliver higher yields stability (up to 4.0 kg/m²) and superior quality while effectively addressing climate change, water scarcity with water utilization (0.8 kg/L), and soil degradation excelling in return on investment (ROI).

Foliar application of sodium nitroprusside alters the physicochemical properties, antioxidant capacities, and enzymatic activities of strawberry cv. Camarosa

Strawberry (Fragaria × ananassa) is a horticultural crop known for its sensitivity to mechanical damage and susceptibility to postharvest decay. In recent years, various strategies have been implemented to enhance both the yield and quality of strawberries, among which the application of nitric oxide-producing compounds has garnered special attention. The present study aimed to investigate the effects of varying concentrations of sodium nitroprusside (SNP), specifically 0, 200, 400, and 600 μM, on strawberries (cv. Camarosa) cultivated in a soilless culture system. It was attempted to identify optimal treatment concentrations that would improve the quality and yield of the strawberries. The analysis of variance revealed significant differences (p ≤ 0.01) in all morphological and phytochemical properties, as well as antioxidant and enzymatic activities, between the treated samples and the control group. Notably, the highest concentrations of total phenolics, phenylalanine ammonia-lyase (PAL) enzyme activity, guaiacol peroxidase enzyme activity, and potassium content in the fruit were recorded at the 400 μM SNP treatment. Specifically, these values were 6.67 mg GAE 100 g⁻1 FW, 57.42 nmol g⁻1 FW min⁻1, 0.183 μmol H2O2 min-1 100 ml-1 extract, and 5.9% DW, respectively. Furthermore, the 200 μM SNP treatment yielded the highest ascorbic acid content (0.587 mg AA 100 g-1 FW) and the lowest 50% inhibitory concentration for free radicals at 44.18 μl. In contrast, the 600 μM treatment resulted in the highest total flavonoid content (0.529 mg QE 100 g⁻1 FW). In conclusion, the findings indicated that SNP treatment can effectively enhance the yield and improve the quality and marketability of the strawberry fruit.

A Proposed Saffron Soilless Cultivation System for a Quality Spice as Certified by Genetic Traceability.

Saffron (Crocus sativus L.) is one of the most expensive spices in the world due to its strong market demand combined with its labor-intensive production process, which needs a lot of labor and has significant costs. New cultivation methods and traceability systems are required to improve and valorize local Italian saffron production. In this study, we conducted a three-year trial in Umbria (Central Italy), looking for a soilless cultivation method based on wooden bins posted at a suitable height from the ground to ease the sowing of corms and harvesting of flowers. Moreover, the spice traceability could be based on investigating the genetic variability of Italian saffron populations using SNP markers. The proposed novel cultivation method showed significantly higher stigma and corm production than the traditional one. At the same time, the genetic analysis revealed a total of 55 thousand SNPs, 53 of which were specific to the Italian saffron populations suitable to start a food traceability and spice certification.

Effect of Biochar and Wood Distillate on Vegeto-Productive Performances of Tomato (Solanum lycopersicum L.) Plants, var. Solarino, Grown in Soilless Conditions

Nowadays, tomato, a commercially important crop, is increasingly cultivated in a soilless cultivation system to counteract climate change. Normally, this system uses cocopeat as a substrate, but its high cost and environmental impact have led to growing interest in alternatives like biochar (BC). In addition, biostimulants, such as wood distillate (WD), a pyrolysis by-product, are increasingly being used to improve fruit yield and quality. BC was used to partially replace (2% and 5%) cocopeat in growth bags for soilless tomato cultivation. Moreover, WD (3 mL/L) was distributed in the substrate every two weeks. The effect of BC and WD on tomato plant growth, fruit quality, and substrate microbial community was investigated. The integration of BC and WD into a soilless growing system for tomato cultivation can improve the fruit quality and influence the microbial activity of the substrate. Replacing part of the cocopeat in the substrate with BC and using an agri-waste-derived biostimulant represent a step forward in making agriculture more sustainable.

The Effect of NaCl-Salinity Applications on the Improvement of Quality Characteristics and Yield of Tomato (Lycopersicon esculentum L.) Grown in Substrate Culture

Salt application in soilless cultivation systems can be considered as a strategic tool to improve tomato fruit quality. In this context, the effects of increasing the salt concentration in the nutrient solution added to the solid culture medium on yield and yield components, biophysical and organoleptic quality traits of tomato (Lycopersicon esculentum L. cv. Kardelen F1) under greenhouse conditions were studied. The salt in the nutrient solution was applied to tomato plants as sodium chloride (NaCl) at four concentrations (0, 14.1, 44.4, and 70.4 mM). Each pot received 150 mL of nutrient solution daily during the vegetative period, while 300 mL was applied daily after flowering. This study was conducted with three replicates following a randomized block design. Plants were harvested 90 days after transplanting. Low salt application in the nutrient solution (14.1 mM NaCl) increased total fruit yield, while the high salt application did not effect fruit yield compared to the control. Salt application at increasing concentrations decreased fruit size and diameter but increased the dry matter in the fruit. The salt treatment mainly positively affected the commercial and organoleptic quality parameters of the tomato fruits. In conclusion, a low level of sodium chloride (14.1 mM NaCl) in soilless culture enhanced fruit production, while moderate (44.4 mM) and high (70.4 mM) concentrations improved various fruit quality traits.

Impacts of Light Exposure and Soil Covering on Sweet Potato Storage Roots in a Novel Soilless Culture System

Soilless culture systems, which promote plant growth and enable the precise control of the root-zone environment, have yet to be fully established for sweet potatoes. In this study, we developed a soilless culture system and examined the effects of soil covering and light exposure on the storage roots of sweet potatoes. Sweet potato seedlings with induced storage roots were transplanted into five systems: a previously developed pot-based hydroponics system (Pot), an improved version with storage roots enclosed in a plastic box and covered with a soil sheet (SS), the SS system without the soil sheet (SD), the SD system with light exposure to storage roots after 54 days (SL), and a deep flow technique (DFT) hydroponics system. Our study enabled the time-course observation of storage root enlargement in the SS, SD, and SL systems. In the SL system, light exposure suppressed the storage root enlargement and reduced epidermal redness. No storage root enlargement was observed in the DFT system, even at 151 days after transplantation. Light exposure in the SL system increased the chlorophyll and total phenolic contents in the cortex beneath the epidermis, while the starch content was the lowest in this system. These findings indicate that the developed system can induce normal storage root enlargement without soil. Additionally, the observed changes in growth and composition due to light exposure suggest that this system is effective for controlling the root-zone environment of sweet potatoes.

Biostimulants Enhance the Nutritional Quality of Soilless Greenhouse Tomatoes.

The application of biostimulants in vegetable cultivation has emerged as a promising approach to enhance the nutritional quality of crops, particularly in controlled environment agriculture and soilless culture systems. In this study, we employed a rigorous methodology, applying various biostimulants amino acids, Plant Growth-Promoting Rhizobacteria (PGPR), fulvic acid, chitosan, and vermicompost along with mineral fertilizers, both foliar and via the roots, to soilless greenhouse tomatoes during spring cultivation. The experiment, conducted in a coir pith medium using the 'Samyeli F1' tomato cultivar, demonstrated that plants treated with biostimulants performed better than control plants. Notable variations in nutritional components were observed across treatments. PGPR had the best effects on the physical properties of the tomato fruit, showing the highest fruit weight, fruit length, equatorial diameter, fruit volume, fruit skin elasticity, and fruit flesh hardness while maintaining high color parameters L, a, and b. PGPR and fulvic acid demonstrated significant enhancements in total phenolics and flavonoids, suggesting potential boosts in antioxidant properties. Amioacid and vermicompost notably elevated total soluble solids, indicating potential fruit sweetness and overall taste improvements. On the other hand, vermicompost stood out for its ability to elevate total phenolics and flavonoids while enhancing vitamin C content, indicating a comprehensive enhancement of nutritional quality. In addition, vermicompost had the most significant impact on plant growth parameters and total yield, achieving a 43% increase over the control with a total yield of 10.39 kg/m2. These findings underline the specific nutritional benefits of different biostimulants, offering valuable insights for optimizing tomato cultivation practices to yield produce with enhanced health-promoting properties.

Efficacy of slow sand filtration enriched with Trichoderma atroviride in the control of Rhizoctonia solani in soilless culture

Soilless cultivation is increasingly common, but the nutrient-rich drainage from substrate cultivation is often discarded. However, drainage can be safely reused if previously disinfected. Slow sand filtration (SSF) is a low-cost, ecological, and effective method for water disinfection, primarily through biological control. Enhancing SSF with antagonistic microorganisms is not well-studied. Additionally, SSF has not been tested to control Rhizoctonia solani, a phytopathogen that can be spread by irrigation water. Therefore, the objective of his work was to test the efficacy of a slow sand filter improved through the inoculation of the antagonistic fungus Trichoderma atroviride, evaluating its suppression capacity against Rhizoctonia solani spread by the irrigation water in a closed substrate cultivation of cucumber (Cucumis sativus). Five experiments were conducted, testing the presence and absence of a sand filter, T. atroviride, and R. solani in each trial. Median disease severity was expressed on a scale of 1–5. The improved SSF increased disease control percentage by 49% compared to SSF alone and by 86% compared to no disease control method. In some experiments, SSF with T. atroviride totally controlled R. solani. The results confirm that biologically enhanced SSF with T. atroviride can effectively disinfect drainage in closed soilless cultivation systems infected with R. solani.

The Impact of Substrate Type on Physiological and Morphological Performance of Saffron in Soilless Cultivation System

The Impact of Substrate Type on Physiological and Morphological Performance of Saffron in Soilless Cultivation System

Amino acid‐based biostimulants and microbial biostimulants promote the growth, yield and resilience of strawberries in soilless glasshouse cultivation

AbstractIntroductionThe increasing demand for strawberries in the United Kingdom, valued for their flavour, nutrition and economic significance, presents challenges in maintaining consistent production, especially under various biotic and abiotic stress conditions. Traditional reliance on conventional agrochemicals to meet these demands is tempered by concerns about their health and environmental impacts, paving the way for eco‐friendly alternatives, such as biostimulants. However, their efficiency in commercial table‐top systems for June‐bearing and ever‐bearing strawberries under glasshouse conditions remains underexplored.Materials and methodsThis study investigated the efficiency of two commercial biostimulants in enhancing the growth, productivity and resilience of two strawberry varieties: ‘Malling Centenary’ (June‐bearer) and ‘Malling Ace’ (ever‐bearer) strawberry cultivars in a soilless hydroponic system within an unheated glasshouse. ‘Vitalnova Prime’ (VP), an amino acid and peptide‐based biostimulant derived from yeast, was applied every 2 weeks as a foliar spray (1 mL/L), whereas ‘Vitalnova Triboost’ (VT), a microbial inoculant with live cultures, was incorporated into the medium post‐transplanting (500 g/m3).ResultsVP significantly enhanced vegetative growth in both cultivars, resulting in substantial increases in number of leaves, crowns, crown diameter and shoot biomass accumulation compared to the control. VT also effectively improved multiple growth parameters compared to the control. Both biostimulants similarly improved crown formation and shoot dry weight in ‘Malling Centenary’. In terms of yield, both VP and VT increased yield in ‘Malling Ace’; notably, VP significantly enhanced the number of marketable fruits by 55% and average fruit weight by 56% compared to the control. Additionally, both biostimulants significantly reduced the occurrence of diseased fruits in both cultivars.ConclusionThis study demonstrates that biostimulants significantly enhance the growth, yield, and resilience of strawberries in soilless cultivation systems within unheated glasshouses. These findings suggest that biostimulants offer a sustainable and promising approach to addressing the increasing global demand for high‐quality strawberries.

Effect of Tomato Grafting onto Novel and Commercial Rootstocks on Improved Salinity Tolerance and Enhanced Growth, Physiology, and Yield in Soilless Culture

Grafting high-yielding tomato varieties onto stress-tolerant rootstocks can mitigate the adverse effects of saline water irrigation on plant tomato productivity in arid regions like Saudi Arabia. This study investigates the efficacy of grafting tomatoes onto both novel and commercial rootstocks to enhance salinity tolerance and its impact on growth, physiological parameters, and yield in a soilless culture system. The experiment involved two water quality levels, 2 (S1) and 4 (S2) dS m−1, two growth media types, volcanic rock (M1) and sand (M2), and six grafting treatments: Tone Guitar F1 non-grafted (G1) (commercial scion), grafted onto itself (G2), Tone Guitar F1* Maxifort F1 (G3) (commercial rootstock), and grafting the scion onto three novel rootstocks, X-218 (G4), X-238 (G5), and Alawamiya365 (G6). Growth, physiology, photosynthetic pigments, and yield improved with lower salinity (2 dS m−1) in volcanic rock and with the grafting treatments (G2–G6) compared to the non-grafted treatment (G1). The best results were achieved with the S1M1G5 treatment, where yield increased by 53% compared to the lowest yield in non-grafted plants grown in sand under higher salinity (S2M2G1). All studied traits were adversely affected under high salinity (S2) in sandy media, with the G1 treatment resulting in the lowest values for these traits.

Evaluation of the nutrient elements profiling of cucumber plants fertigated by three different nutrient solutions in soil and soilless culture systems

Evaluation of the nutrient elements profiling of cucumber plants fertigated by three different nutrient solutions in soil and soilless culture systems

Experimental assessment of biostimulants on mung bean growth on a soilless culture system using superabsorbent pectin based hydrogel

Sustainable agriculture initiatives are needed to ensure the food security of the people all over the world. Soilless cultivation methods using hydrogels may give a revolutionary response as well as a more ecological and productive alternative to conventional farming. This study attempted extraction of pectin from the rind of albedo yellow passion fruit (Passiflora edulis var. flavicarpa Degener)and hydrogels from pectin and activated carbon was compared with pure pectin hydrogel; Pectin- Activated Carbon hydrogels (PAC) showed a microporous structure with excellent hydrophilicity and showed superior water holding capacity. Then the prepared hydrogels were examined with various instrumental techniques like FTIR, SEM, XRD, Raman, BET and rheological properties. In the BET analysis, PAC3 shows the highest surface area of 28.771 m2/g when compared to PAC0 at 15.063 m2/g. The germination experiments were performed using mung beans. This study provides an opportunity for the application of pectin hydrogels in agriculture field specifically for home garden or rooftop cultivation.

Comparison of the growth, fruit quality, and physiological characteristics of tomato nourished by three different nutrient solutions in soil and soilless culture systems

Comparison of the growth, fruit quality, and physiological characteristics of tomato nourished by three different nutrient solutions in soil and soilless culture systems

Silicon attenuates nutritional disorder of phosphorus in seedlings of Eucalyptus grandis × Eucalyptus urophylla

BackgroundNutritional disorders of phosphorus (P), due to deficiency or toxicity, reduce the development of Eucalyptus spp. seedlings. Phosphorus deficiency often results in stunted growth and reduced vigor, while phosphorus toxicity can lead to nutrient imbalances and decreased physiological function. These sensitivities highlight the need for precise management of P levels in cultivation practices. The use of the beneficial element silicon (Si) has shown promising results under nutritional stress; nevertheless, comprehensive studies on its effects on Eucalyptus spp. seedlings are still emerging. To further elucidate the role of Si under varying P conditions, an experiment was conducted with clonal seedlings of a hybrid Eucalyptus spp. (Eucalyptus grandis × Eucalyptus urophylla, A207) in a soilless cultivation system. Seedlings were propagated using the minicutting method in vermiculite-filled tubes, followed by treatment with a nutrient solution at three P concentrations: a deficient dose (0.1 mM), an adequate dose (1.0 mM) and an excessive dose (10 mM), with and without the addition of Si (2mM). This study assessed P and Si concentration, nutritional efficiency, oxidative metabolism, photosynthetic parameters, and dry matter production.ResultsSi supply increased phenolic compounds production and reduced electrolyte leakage in seedlings provided with 0.1 mM of P. On the other hand, Si favored quantum efficiency of photosystem II as well as chlorophyll a content in seedlings supplemented with 10 mM of P. In general, Si attenuates P nutritional disorder by reducing the oxidative stress, favoring the non-enzymatic antioxidant system and photosynthetic parameters in seedlings of Eucalyptus grandis × Eucalyptus urophylla.ConclusionThe results of this study indicate that Eucalyptus grandis × Eucalyptus urophylla seedlings are sensitive to P deficiency and toxicity and Si has shown a beneficial effect, attenuating P nutritional disorder by reducing the oxidative stress, favoring the non-enzymatic antioxidant system and photosynthetic parameters.

Design and evaluation of slow sand and UV filters for effective nutrient recycling in closed soilless cultivation

Nutrient and water use efficiency can be improved in soilless cultivation systems by recirculating the leachate. However, untreated leachate contains particulate matter that may clog drip emitters and root pathogens which can pose a threat to the crop health if reintroduced into the system. To address this issue, an ultraviolet (UV) filter was developed to complement the slow sand filter to enhance its treatment efficiency in removing root pathogens. The experiment was conducted during 2019 and 2020 at Punjab Agicultural University, Ludhiana, Punjab to assess the effectiveness of the UV filter in removing pathogens, specifically Dickey zeae and Xanthomonas, from the leachate in a closed soilless cultivation system. Pre and post-treatment measurements were made 40 days after transplanting (DAT) and 80 DAT to evaluate the efficiency of the UV filter. The results revealed that combined UV and slow sand filters substantially treated the raw leachate. At 40 DAT, the pathogen removal efficiency was 94.8%, while it was 92% at 80 DAT. The findings highlight the importance and effectiveness of using the UV filter as an additional treatment step in closed soilless cultivation systems with significant improvement in the overall removal efficiency of root pathogens from the leachate.

Selenium concentration and method of application modulate growth and development of bell pepper (Capsicum annuum L.)

Selenium (Se) is considered a beneficial element for plants. It plays a fundamental role in several physiological processes that influence their growth, development, and productivity. However, the influence of Se depends on both the concentration used and the method of application. It was hypothesized that low concentrations of Se stimulate plant growth and development, and foliar applications are more effective as a method of application. For that reason, the objective of the present investigation was to evaluate the effectiveness of 5, 10, 25, and 50 µM of Se applied radically and foliarly in bell pepper crop employed in a soilless cultivation system. The presence of Se by both application methods stimulated plant production, dry biomass accumulation, and photosynthetic pigment content, as well as leaf concentration of nitrogen (N) and potassium (K), except for calcium (Ca), and phosphorus (P) which were influenced by the application method and Se concentration factor, respectively. Fruit size was favored by the Se concentration factor while shelf life was favored by the application method. Se concentration in fruit dry matter varied as a function of Se concentration and application method, being more effective for human consumption by foliar application. This demonstrates the potential of Se as a beneficial element and reinforces the importance of proper management of both the concentration and method of Se application in agricultural crop production.

Zinc biofortification via fertigation using alternative zinc sources and concentration levels in pea, radish, and sunflower microgreens

Zinc (Zn) is a key micronutrient essential for human health, and its deficiency affects over 17 % of the global population. The consumption of Zn-biofortified foods is one strategy for addressing this malnutrition issue. Supplying Zn-enriched nutrient solutions via fertigation is a prominent method for enhancing the content of Zn in vegetable crops. Among vegetables, microgreens are considered a particularly suitable biofortification target crop due to their high nutrient density, swift growth rate, and low phytic acid content. However, there is limited knowledge on the optimal Zn sources and application rate for the biofortification of different microgreen species via fertigation. Therefore, this study aimed to examine the effects of alternative Zn sources (ZnSO4, ZnO, and Zn-EDTA) and application rates (0, 5, 10, and 15 mg/L of Zn) on yield components, mineral content, and phytochemical profile of pea, radish, and sunflower microgreens grown in a soilless cultivation system. Zn fertigation increased Zn content and the nutritional profile (flavonoids, total phenols, antioxidant activity, and ascorbic acid) of all three microgreen species. Microgreens fertigated with 15 mg/L ZnSO4 solution, increased Zn content nearly by a factor of 5, 13, and 6 in pea, radish, and sunflower, relative to their control not supplied with Zn (61.01, 50.26, and 65.87 mg/g DW), respectively. ZnSO4 was the most effective source of Zn, followed by ZnO and Zn-EDTA. Zn accumulation resulted in minimal or no fresh yield reduction. However, the concentration of other essential microminerals, like Fe, decreased with Zn accumulation in all three species. In conclusion, Zn biofortification via fertigation is effective in enriching microgreens with Zn, while also enhancing their nutritional profile. Nevertheless, selecting the proper Zn source and application rate is critical to achieving the target Zn concentration without reducing yield and/or the content of Fe and other minerals.

Exploration and Profiling of Potential Thermo-alkaliphilic Bacillus licheniformis and Burkholderia sp. from varied Soil of Delhi region, India and their Plant Growth-Promoting Traits

Soilless cultivation has emerged as a fundamental alternative for large-scale vegetable production because it generates high-quality yields and uses resources efficiently. While plant growth-promoting bacteria (PGPB) are known to enhance growth and physiological aspects in crops grown in soil, their application in soilless cultivation has been relatively less explored. This study aimed to isolate potential PGPBs from soil samples collected from five locations in and around the Delhi-National Capital Region (NCR), India, which were further screened for significant PGPB attributes. Among these, 51 isolated were selected for assessing the impact on Oryza sativa (rice) growth and yield grown on a hydroponic set. The results indicated that isolates AFSI16 and ACSI02 significantly improved the physiological parameters of the plants. For instance, treatment with AFSI16 showed a 23.27% increase in maximum fresh shoot mass, while ACSI02 resulted in a 46.8% increase in root fresh mass. Additionally, ACSI02 exhibited the highest shoot length (34.07%), whereas AFSI16 exhibited the longest root length (46.08%) in O.sativa. Treatment with AFSI16 also led to significant increases in total protein content (4.94%) and chlorophyll content (23.44%), while ACSI02 treatment showed a 13.48% increase in maximum carotenoid content in the leaves. The potential PGPBs were identified through 16S rRNA sequencing, as the two most effective strains, AFSI16 and ACSI02, belonged to thermo-alkaliphilic Bacillus licheniformis and Burkholderia sp., respectively. This study demonstrated the potential of these identified PGPB strains in enhancing crop performance, specifically in soilless cultivation systems.

Reduced Fertilization to Improve Sustainable Use of Resources and Preserve Postharvest Quality of Fresh-Cut Wild Rocket (Diplotaxis tenuifolia L.) in Soil-Bound and Soilless Cultivation.

Reducing fertilizer input is a goal for helping greenhouse farming to achieve higher sustainability in the production process while preserving overall crop performance and quality. Wild rocket plants were cultivated in a plastic greenhouse divided into two independent sectors, one for soil-bound (SbS) cultivation and another equipped for soilless (ScS) cultivation systems. In both SbS and ScS, the crop was subjected to treatments consisting of a high- and a low-input fertilization program (HF and LF treatment, respectively). Water use efficiency (WUE) and partial factor productivity (PFP) for nutrients (N, P, K, Ca, and Mg for ScS, and N for SbS) were measured. Rocket leaves, separated for the cultivation system and fertilization program and collected at different cuts during the growing cycle, were cold stored at 10 °C until 16 d. On each sampling day (at harvest and during storage), the sensory parameters, respiration rate, dry matter, color, electrolyte leakage, antioxidant activity, total phenols, total chlorophyll and ammonia content were evaluated. In ScS, the PFP for all nutrients supplied as fertilizers showed a significant increase with the LF treatment, with values higher than 30% recorded for N, K, and Ca. As for the postharvest performance, rocket leaves cultivated in ScS showed better qualitative traits than those cultivated in SbS, as suggested by the lower values of ammonia content and electrolyte leakage recorded at the end of storage period in samples grown in ScS. Moreover, in ScS, the data showed lower membrane damage in LF than HF rocket leaves. Finally, regarding total chlorophyll content, even if no effect of each treatment was recorded in SbS, rocket cultivated in ScS showed a better retention of this parameter by applying LF rather than HF treatment. In addition to this, a PLS model (R2 = 0.7) able to predict the cultivation system, using as a variable non-destructively measured total chlorophyll content, was implemented. Low fertilization input, both in SbS and in ScS, allowed satisfying production levels and more sustainable management of nutrients. LF treatment applied to ScS also had in positive effects on the postharvest quality of fresh-cut rocket leaves.