Mussel seashells (Mytilus chilensis) from the shellfish industry located in Dalcahue (Chiloé Island, Chile) were classified as seashells with organic matter (W-OM) and without organic matter (Wo-OM) waste products after removal of their meat. The seashells were cleaned by washing with potable water and, subsequently, dried in a tray dryer (Model 30-1060, Memmert GmbH + Co. KG, Schwabach, DEU) for 12 to 20 hours at 50 °C, until a moisture content of 1 to 20% w/w was attained. A hammer mill (Model M0LTN0H11, Plaspak, Santiago, Chile) with a fine sieve (1.7 mm opening) was used to grind seashells. The dried and ground seashells were packed in hermetically sealed bags.

Food waste (coffee bean (CB), banana peels (BP), and wood ashes (WA)) were prepared. The N, P, and K sources were CB, WA, and BP, respectively. The CB and BP were dried in a tray dryer (Model 30-1060, Memmert GmbH + Co. KG, Schwabach, DEU) from 12 to 20 h at 50 °C. The BP was ground with a hammer mill (Model M0LTN0H11, Plaspak, Santiago, CL) using a fine sieve (1.7 mm opening). The WA was sieved (mesh opening of 2 mm) to remove impurities. Subsequently, CB, BP, and WA were packed in hermetically sealed bags. The fertilizer preparation considered the incorporation of seashells, CB, BP, and WA, as part of its ingredients. The seashell type was evaluated in three treatments: i ) W-OM, ii ) Wo-OM, and iii ) a mixture of equal mass of W-OM and Wo-OM (50:50). The CB, BP, and WA ingredients were fixed variables. For each treatment, 10 g seashells, 10 g CB, 14 g BP, and 3 g WA constituted the applied dose, which allowed adjusting N (19 mg kg^-1), P (98.7 mg kg^-1), and K (61.6 mg kg^-1) levels by mass balance. The NPK dose adjusted coincides with the average fertility level (N, <108 mg kg^-1; P, 9 mg kg^-1; K, from 45 to 112 mg kg^-1) for crop soils recommended by El-Seedy and Saeed (2019).

The studied soil was of alluvial type from Buchupureo, Commune of Cobquecura, Ñuble Region, Chile, and was collected at a depth of 20 cm and transported in plastic containers according to Carvajal-Mena et al. (2023). Stones and impurities were extracted by sieving soil with a 2 mm aperture sieve. The soil sample was considered a control (alluvial soil without added fertilizer) and a blank (leaf soil formulated from plant and forestry waste).

Lettuce plants (Lactuca sativa L., var. Longifolia) also known as romaine lettuce were grown in pots (n=12). The plants were sown in October 2022, transplanted and applied the previously specified fertilizer dose at a surface level around the stem in November 2022, and then lettuce leaves were harvested at the end of February 2023. Water was applied every two days around the stem to moisten and infiltrate the applied fertilizer. The average air temperature was ranged between 7.3±1.8 and 19.1±2.6 °C.

The average air humidity was 77.6±2.7%. The average daylight was approximately 14.1±0.6 h. The lettuce plants had a control (lettuce plant in alluvial soil without added fertilizer) and a blank (lettuce plant in leaf soil).

Soil pH was measured directly with a digital soil meter (PH328, SMART SENSOR, Fujian, CN).

The N level (mg kg^-1) was measured using a soil nutrient sensor (Chengdu Sentec Technology Co., Sichuan, CN). The digital soil meter and soil nutrient sensor showed an accuracy of ±0.2 pH and ±2%, respectively. The pH and N levels were based on the electrical conductivity measurement of steel electrodes, which were immersed in wet soil (69.2±6.2% wet basis), and the variability in electrical conductivity is expressed as pH value or N level (Carvajal-Mena et al. 2023). Measurements were performed in triplicate.

The leaf chlorophyll and N levels were measured using a ZYS-4N Portable Plant Nutrition Test Analyzer Machine (WANT Balance Instrument Co., Changzhou, CN). The chlorophyll measurement principle was based on the quantitative evaluation of the intensity of the green color of the leaf from 650 to 940 nm, where accuracy was ±1 SPAD unit (Cunha et al. 2015). According to the equipment manufacturer, the determination of nitrogen level was based on a statistical model due to the high linear correlation between chlorophyll and N level, with an accuracy of ±5%. Measurements were performed in triplicate.

The procedure for measuring vitamin C content in lettuce leaves was based on the spectrophotometric method using the reagent 2,6-dichlorophenolindophenol (Anal Parimal and Shuchi Desai 2019). A 2 g lettuce sample was crushed in a mortar with 20 mL of 0.4% w/v oxalic acid. The homogenate was filtered two times with Wathman grade 41 filter paper. 9 mL of distilled water (blank sample) was added to the filtered sample (1 mL). Then, 9 mL of 0.0012% w/v 2,6-dichlorophenolindophenol was added to 1 mL of the filtered sample. The absorbance readings were obtained on a GENESYS 10S UV-Vis spectrophotometer (Thermo Scientific, Shanghai, CN) at 520 nm and 22 °C at room temperature. Measurements were performed in triplicate and expressed as mg ascorbic acid per 100 g fresh weight of lettuce leaves.

All results were analyzed with Statgraphics Centurion XVI statistical software (Statistical Graphics Corp., Herdon, VA, USA). The results were calculated as the mean value ± standard deviation and reported as plots displaying the estimated trends. Significant differences between the mean values (P≤0.05) were determined using Tukey´s test.

The lettuce is grown in soil with a pH range from 6.0 to 6.5, for ideal growth and to decrease root infections (Nkosi and Msimango 2022). However, many agricultural soils in Chile and specifically on the Ñuble Coast have pH values lower than 6.0 (Carvajal-Mena et al. 2023), which limits their use for growing vegetables.

Figure 1 shows the effect of seashell type (W-OM, Wo-OM, and 50:50 treatments) on soil pH. The W-OM and 50:50 treatments showed an increasing trend of soil pH from pH values less than 6.5 (acidic range) to close to a neutral pH range (7.0±0.5) during the period analyzed. Similarly, other studies have reported higher pH values in paddy soils with organic matter content and/or calcium carbonate (Zhao et al. 2014). In general, the decomposition of organic matter leads to the production of more organic acids, thus lowering pH (Hong et al. 2019). However, organic acids produce calcium salts when it reacts with calcium carbonate (Luai et al. 2020), and, such salts, as calcium lactate, act as an antacid agent contributing to the pH upturn. The Wo-OM treatment showed a constant trend, probably due to the buffering capacity of the calcium carbonate contained in the seashells and the absence of organic matter (Ng et al. 2022). On the other hand, the blank and control treatments exhibited a decreasing trend in soil pH; in the first case, as leaf soil is an organic medium, the soil pH could decrease when it comes into contact with irrigation water, due to the soluble organic acids it contains (Adeleke et al. 2017), and, in the second case, the alluvial soil of the area under study was made up of rocks with acid reaction, such as, granites and siliceous sandstones, which give soils with pH between 4.8 and 5.6 (Li and Shi 2020).

Figure 1

Soil nitrogen is a nutrient with great impact on natural ecosystems and its decrease can cause acidification, nutrient imbalance, and loss of biodiversity, affecting the quality and yield of cultivated vegetables (Blanco and Martínez 2019).

Figure 2 shows the effect of W-OM, Wo-OM and 50:50 treatments on soil N level, which was approximately 9 mg kg^-1, during the 35 days analyzed. Considering that during fertilizer preparation, the N level incorporated into soil was adjusted to 19 mg kg^-1 and, given that the coffee bean (CB) waste had a severe heat treatment applied during its house preparation, therefore, it could be suggested that not all the nitrogen was available for the plant, probably, due to a protein denaturation in CB (Mazzafera et al. 2019). Additionally, given the low absorption of N, root differentiation and expression of nitrate transporters could have been affected, altering plant quality (Singh et al. 2022). Visually, this was verified because a lower number of shortened plants was found (n=3), that is, a greater leaf opening was observed in the plants (n=9), which promoted leaf dehydration (Blanco and Martínez 2019). For its part, the control treatment showed a low N level (5.8±0.1 mg kg^-1), which allowed the improvement of N in the soil with the W-OM, Wo-OM, and 50:50 treatments. The blank treatment showed the highest N level, 102.6±9.2 mg kg^-1, which can be explained because the leaf soil was formulated by plant and forestry waste, which represent the largest nitrogen reserve in the soil and most of this nitrogen can be available to the plant.

Figure 2

Nitrogen is the nutrient responsible for the green pigmentation of vegetables and plays a key role in the leaf´s growth, size, and quality (Ncama and Sithole 2022; Albadwawi et al. 2022).

Figure 3 shows the effect of W-OM, Wo-OM, and 50:50 treatments on leaves N level, which exhibited an increase with time for all treatments, although the highest N level was observed in the leaves of blank treatment. Karam et al. (2002) suggest that the N level in the leaf for an ideal chlorophyll content, is the one that avoids toxicity or lack of nutrients to the plants. Therefore, the lettuce leaf plants could have exhibited a lower sensitivity to the nitrogen source incorporated into the soil because a weak appearance was observed in their leaves.

Figure 3

Chlorophyll is a natural and active pigment responsible for transforming light energy into chemical energy, used in plant growth (Chowdhury et al. 2021).

Figure 4 shows the effect of W-OM, Wo-OM, and 50:50 treatments on leaves chlorophyll content. An increase in chlorophyll was observed in the lettuce leaves for all treatments during the study period. These findings were consistent with a study carried out by Santos et al. (2016), which reported similar trends of chlorophyll production in lettuce leaves cultivated with a compost of natural origin. Bassi et al. (2018) reported that total chlorophyll content increases under high nitrogen supply. However, except for the blank treatment, the low nitrogen levels reported in Figure 4, could be related to the degree of nitrogen availability in the soil from coffee bean waste sources.

Figure 4

The vitamin C is an indicator of the nutritional value of vegetables (Medina-Lozano et al. 2021). Figure 5 shows the effect of W-OM, Wo-OM, and 50:50 treatments on the vitamin C content of lettuce leaves. It was observed that the addition of seashells improved the vitamin C content when compared to the blank treatment based on leaf soil. Specifically, the plants grown in the soil without organic matter (Wo-OM) showed a high vitamin C content (51.0±3.6 mg 100 g^-1). It was observed that the organic matter content of seashells (W-OM) contributed significantly to reducing the vitamin C content in the lettuce leaves. Although, the vitamin C content in the plants from the W-OM (25.8±1.0 mg 100 g^-1) and 50:50 (37.0±3.0 mg 100 g^-1) soils were that of the plants from leaf soil (24.6±1.7 mg 100 g^-1).

Figure 5

These findings suggest that the addition of seashells without organic matter (Wo-OM) to the lettuce plants has a positive effect on the vitamin C content (51.0±3.6 mg 100 g^-1), but the presence of organic matter in the seashells could reduce the vitamin C content. Lee and Kader (2000) confirm these findings and indicate that the organic waste derived from meat (as the organic matter of seashells) represents an additional nitrogen source, whose excess could partially inhibit vitamin C production in plants because the excess nitrogen increases the concentration of NO₃, a known inhibitor of vitamin C production in vegetables.