The application of the scratching technique has the same effect on Pleurotus spp.?

Vieira Junior, Wagner Gonçalves; Alberti, María Melisa; Pardo-Giménez, Arturo; Iossi, Matheus Rodrigo; Dias, Eustáquio Souza; Zied, Diego Cunha

doi:10.1590/1678-4324-2023220736

Abstract

The present work evaluated the agronomic behavior of species and varieties of Pleurotus submitted or not to the scratching technique. The cultivated species/varieties were Pleurotus ostreatus and Pleurotus ostreatus var. Florida, and Pleurotus djamor, where half of the treatments were scratched before the first and second flushes, while the rest were only scratched before the second flush. Yield (%), biological efficiency (%), weight of mushroom (g) and number of mushrooms (uni) were evaluated. It was observed that scratching harmed the mushroom weight for P. ostreatus, where the treatment without scratching produced significantly higher values, in the first harvest flush. On the other hand, scratching favored yield and the number of mushrooms for P. djamor. When the species are compared, it is noted that P. ostreatus obtained a lower yield, which was also reflected in the biological efficiency. P. djamor stood out with a large number of mushrooms, statistically higher than the other species, on the other hand, producing mushrooms of low weight of mushroom. The use of the scratched technique is not recommended for the conditions used in the work, due to the increase in labor and loss of mushroom weight.

Keywords:
oyster mushroom; yield; screening of mushroom quality; mycelium breaking; cultivation technique

HIGHLIGHTS

• The use of the scratching technique was studied in Pleurotus spp.

• The scratching increases the number of Pleurotus djamor mushrooms.

• The use of scratching is selective for different species of Pleurotus.

INTRODUCTION

Brazil is one of the largest agricultural producers in the world, its sector has been growing in recent years and the expectation is that its production will continue to increase. The growth combined with the viability of intensive systems has provided the availability of lignocellulosic agricultural waste, which promotes environmental concerns, but also stimulates good business opportunities that generate economic or energy value [¹1 Santos RRD, Guarnieri P, Brisola M. [Reverse logistics of waste from agrosilvopastoral and agroindustrial activities: a systematic literature review]. Rev em Agronegocio e Meio Ambient. 2018 Apr/June;11(2):573-97.].

In most cases, however, these agricultural wastes are not treated or reused [²2 Viana LG, Cruz OS. [Reuse of agro-industrial waste]. In: IV Congresso Baiana de Engenharia Sanitária e Ambiental; 2016 Jul 13-16, Cruz das Almas, Bahia, Brazil: p. 1-3.]. The availability of nutrients in these materials provides suitable conditions for the microorganism’s growth, such as edible mushrooms [³3 Sadh PK, Duhan S, Duhan JS. Agro-industrial wastes and their utilization using solid state fermentation: a review. Bioresour Bioprocess. 2018 Jan;5(1):1-15.]. Using these wastes to mushrooms production through locally available technologies is a solution to turning them into a food source.

Since Pleurotus spp. can develop in tropical climates, besides being simple to produce and compatible with lignocellulosic substrates [⁴4 Muthangya M, Hashim SO, Amana JM, Mshandete AM, Kivaisi AK. Optimization of Pleurotus mushroom cultivation on saline sisal solid waste. World Appl Sci J. 2013 May;23(9):1146-50.], their production potential is very high. This fact contributed to the increase in world production, occupying the second place of the most cultivated genus in the world, representing about 19% of total global production [⁵5 Royse DJ, Baars J, Tan Q. Current overview of mushroom production in the world. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Ltd, 2017. p. 5-13.].

Pleurotus species have been adapted for cultivation in small spaces and require a short growth time compared to other mushrooms [⁶6 Debnath S, Saha R, Das P, Saha AK. Cultivation and medicinal properties of wild edible Pleurotus ostreatus of Tripura, Northeast India. Vegetos. 2019 June;32(3):238-46.,⁷7 Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46.]. Cultivation methods are using sterilized substrate, stored in plastic bags [⁸8 Ita V, Angeles M, Antonio C, Dolores M, Huerta Lara M, Romero-Arenas O. [Wild Reed (Arundo donax) as an alternative substrate in the production of Pleurotus ostreatus]. Scientia Fungorum. 2018 June;48:15-22.,⁹9 Adewoyin AG, Ayandele AA. Comparative study of yield performance and nutrient composition of the edible mushroom Pleurotus pulmonarius, cultivated on different substrates. Afr J Plant Sci. 2018 Aug;12(8):148-54.] or glass or plastic pots [¹⁰10 Shnyreva AA, Kozhevnikova EY, Barkov AV, Shnyreva AV. Solid-state cultivation of edible oyster mushrooms, Pleurotus spp. under laboratory conditions. Adv Microbiol. 2017 Feb;7(2):125-36.,¹¹11 Yamauchi M, Sakamoto M, Yamada M, Hara H, Taib S.M, Rezania S, et al. Cultivation of oyster mushroom (Pleurotus ostreatus) on fermented moso bamboo sawdust. J King Saud Univ Sci. 2019 Oct;31(4):490-4.].

The rapid colonization of the substrate by Pleurotus mycelium is an important characteristic in controlling contamination [⁷7 Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46.], but excessive mycelial formation in the upper part of the substrate is common in species of this genus, reducing the gas exchange capacity due to reduction of pores, which consequently impairs mushroom yields [¹²12 Doroški A, Klaus A, Režek Jambrak A, Djekic I. Food Waste Originated Material as an Alternative Substrate Used for the Cultivation of Oyster Mushroom (Pleurotus ostreatus): A Review. Sustainability. 2022 Sept;14(19):12509.,¹³13 Prasad S, Rathore H, Sharma S, Tiwari G. Yield and proximate composition of Pleurotus florida cultivated on wheat straw supplemented with perennial grasses. Indian J. Agric. Sci. 2018 Jan;88:91-4.]. The absence of aeration in the substrate decreases the O2 concentration, initiating the fermentation process that converts nitrogen into ammonia, interrupting mycelial growth [¹⁴14 Choi KW. Shelf cultivation of oyster mushroom with emphasis on substrate fermentation. Gush, R, editor. In Mushroom Growers’ Handbook 1. Oyster Mushrooms Cultivation. Part II: Oyster Mushrooms. MushWorld, Korea; 2018. p. 153-165.], as well as inhibiting the activity of hydrolytic enzymes, responsible for this process [¹⁵15 Gowthaman MK, Krishna C, Moo-Young M. Fungal solid state fermentation-an overview. Appl .Mycol biotechnol. 2001 Sept;1:305-52.]. The cultivation of Pleurotus species still does not have concrete alternatives to solve this problem, exposing the need for studies aimed at adapting or creating technologies for this purpose.

The scratching technique is commonly used in some mushroom species to promote substrate gas exchange, this method consists of the mechanical removal of the first layer of mycelium together with the upper part of the aged, colonized substrate for uniform fruiting. The scratched surface is then lightly sprayed with water to stimulate formation of fruitbodies [¹⁶16 Yamanaka K. Cultivation of mushrooms in plastic bottles and small bags. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Lta, 2017. p. 309-338.]. Although the application of this technique has also been reported in other species, such as Calocybe indica, Flamulina velutipes, Hypsizygus marmoreus and Pholiota nameko [¹⁶16 Yamanaka K. Cultivation of mushrooms in plastic bottles and small bags. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Lta, 2017. p. 309-338.,¹⁷17 Pani BK. Effect of age and quantity of spawn on milky mushroom production. Asian J Exp Biol Sci. 2011;2(4), 769-71.], no studies were found that report whether this practice involving species, varieties and application time, has some benefit on agronomic behavior. Thus, the aim of this work was to evaluate the effects of the scratching technique on the performance of Pleurotus spp.

MATERIAL AND METHODS

The experiment was carried out at the Centro de Estudo em Cogumelos of the Faculdade de Ciências Agrárias e Tecnológicas (FCAT/UNESP), Câmpus Dracena. The design was in completely randomized blocks, in a 3x2 factorial scheme, with 7 replications. The first factor corresponded to different species and varieties of Pleurotus (P. ostreatus, P. ostreatus var. Florida and P. djamor), and the second factor was the application or not of the scratching technique.

The substrate for production was prepared using: eucalyptus sawdust (75%), wheat bran (10%), cottonseed bran (10%) and soybean meal (5%). This formulation was hydrated with water until reaching 70% moisture and 2% calcium carbonate was added. The substrate was placed in plastic bags made of high-density polyethylene containing 500 g (length 26cm, width 10cm and height 19cm), then autoclaved at 121°C for 4 hours.

The inoculums were prepared following the methodology proposed by Vieira Junior and co-authors [¹⁸18 Vieira Junior WG, Centeio Cardoso RV, Fernandes Â, Ferreira ICFR, Barros L, Pardo-Giménez A, et al. Influence of strains and environmental cultivation conditions on the bioconversion of ergosterol and vitamin D2 in the sun mushroom. J Sci Food Agric. 2022 June;102(4):1699-706.], using sorghum seeds that were boiled at 100°C for 30 minutes and then added with 2% limestone. To spawn poduction, the following steps were used: selection of mushroom and production of subculture; parent spawn; and finally grain spawn. The bags with the substrate were inoculated with 15g of inoculum (3% wet substrate) in a laminar flow chamber and then incubated for 18 days at 26 ± 2 °C. The strains used, POS 18/01 (Pleurotus ostreatus), POF 16/01 (Pleurotus ostreatus var. Florida) and PDJ 19/01 (Pleurotus djamor) were obtained from different growers from São Paulo and Paraná States (Brazil) and are deposited in the public collection of the Centro de Estudos em Cogumelos.

After incubation, the half of the bags were cut from their top surface, then the scratching technique was applied before the first and second flushes, where through the use of a spoon ~1 cm of the aged mycelium and substrate layer was removed (Figure 1).

Figure 1
(A) Before scratching; (B) scratching; (C) primordium formation in the first flush after scratching done at 18 days after inoculation; and finally (D) mushrooms at harvest point after scratching done at 18 days after inoculation.

On the other half of the bags, the scratching technique was applied before the second flush. Subsequently, the bags were taken to cultivation rooms with a temperature of 21± 2ºC, relative humidity of 75 ± 5%, CO₂ < 1200 ppm and 150-200 lux illumination, for fruiting [⁷7 Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46.,¹⁹19 Raman J, Jang KY, Oh YL, Oh M, Im JH, Lakshmanan H, et al. Cultivation and nutritional value of prominent Pleurotus spp.: An overview. Mycobiology. 2021 Nov;49(1):1-14.]. The mushrooms were harvested twice a day, weighed and counted for analysis of production parameters [²⁰20 Zakil FA, Isa RM, Sueb MSM, Isha R. Growth performance and mineral analysis of Pleurotus ostreatus (oyster mushroom) cultivated on spent mushroom medium mixed with rubber tree sawdust. Mater Today: Proc. 2022 Apr;57:1329-37.]. Figure 2 shows the timeline of the entire crop, starting with the autoclaving of the substrate until the last day of harvest.

Figure 2
Crop period schedule.

The agronomic behavior was evaluated through: i) yield, calculated through the fresh mass of mushrooms (g) divided by the weight of the initial wet substrate (g) x 100, expressed in percentage; ii) mushroom number, expressed in unit(s); iii) weight of mushrooms, calculated through the total fresh weight divided by the number of mushrooms, expressed in grams; and iv) biological efficiency, calculated through the fresh weight of mushrooms by the dry weight of the initial substrate x 100, expressed in percentage [²¹21 Okwulehie IC, Okwuowulu EO, Ezeh CG, Ikechukwu GC. Yield potentials, nutritional and mycochemical properties of fruit-bodies of Pleurotus ostreatus var. florida, grown on Andropogon gayanus straw; supplemented with Anthonotha macrophylla. Int J Mod Biol Res. 2017 Mar;5:24-31., ²²22 Albertia MM, Cunha MLO, Mendes DW, Vieira Junior WG, Zied DC. Tecnologic Development on Pleurotus Cultivation: Specific Practices Used in Brazil. Braz Arch Biol Technol. 2021 Dec;64:e21200198.].

Data were submitted to analysis of variance and when significant, Tukey's mean comparison test was applied, both at 5% probability. For analysis and preparation of the heat map through the Euclidean distance, Pearson correlation and dispersion analysis, the R 4.1.0 software (R Foundation for Statistical Computing, Vienna, Austria) was used.

RESULTS

The species P. djamor and P. ostreatus var. Florida had two production flushes, with a total cycle of 39 and 42 days, respectively. P. ostreatus had only one production flush, with a total production cycle of 33 days. In order to verify the isolated action of the scratching technique, Table 1 presents the agronomic parameters only for the first flush, where the technique was applied in the half of the production bags. The other half of production bags were not applied scratching technique before the 1st flush.

The influence of the technique was significant in the species/varieties studied, being statistically affected the number of mushrooms for P. djamor (38.5 with and 23.8 u without scratching) and weight of mushroom for P. ostreatus (4.5 with and 5.8 g without). The species with the highest yield and biological efficiency was P. ostreatus var. Florida, with of 8.3% and 27.7% using the scratching technique (Table 1).

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Table 1
Agronomic behavior of the first flush with and without scratching technique.

The highest total yield was obtained by P. ostreatus var. Florida (13.2 with scratching before 1st and 2nd flushes and 12.8% without scratching before 2nd flush) and the lowest by P. ostreatus (6.2% with scratching before 1st and 2nd flushes and 6.08% without scratching before 2nd flush). P. djamor presented the highest number of mushrooms and the species P. ostreatus the lowest, the weight of mushroom behaved in an inverse way, through mushrooms with greater weight for P. ostreatus and lesser for P. djamor (Table 2).

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Table 2
Agronomic behavior of different of Pleurotus with the application of the scratching technique at different times of cultivation.

Means with different letters (lowercase between lines and capital letters between columns) differed by Tukey's test at 5% probability. Absence of letters, there was no statistical difference.

Significant differences in yield using the scratching technique were only observed in P. djamor species, with 11.1%. Higher values were also found in the number of mushrooms and biological efficiency for P. djamor. In P. ostreatus the technique affected the weight of mushroom.

To demonstrate the similarity between the treatments and the correlation between the variables, a heat map was constructed (Figure 3). By Ward's method (left grouping), the P. ostreatus was separately from the other species, due to differences in their agronomic behavior (shade of different colors, ranging from 1.5 to -1.0). This indicates that the research conditions (substrate formulation or management of environmental variables) were not efficient for P. ostreatus.

Figure 3
Heat map based on mean Euclidean distance and Ward's hierarchical clustering method, in the cultivation of Pleurotus. In the upper part, it indicates grouping in relation to agronomic parameters. On the left side, grouping according to species/varieties and scratching technique. The color scale represents the values of agronomic parameters, being intense red color represents high value, and intense blue color represents low value, where: POS (Pleurotus ostreatus), POF (Pleurotus ostreatus var. Florida) and PDJ (Pleurotus djamor), submitted (ws) or not (wos) to scratching technique. Agronomic parameters indicated by mean mushroom weight (Mmw), number of mushrooms (Nmush), yield (Yield) and biological efficiency (Bioef).

Another important point refers to the Euclidean distance of the clusters on the left, which the furthest being P. djamor and the closest being P. ostreatus var. Florida, which denotes the great influence of the scratching technique for P. djamor and the smallest influence for P. ostreatus var. Florida, in relation to the values of yield, number and weight of mushroom, and biological efficiency obtained (agronomic behavior).

In relation to the above grouping, from the analyzed variables (yield, number and weight of mushroom, and biological efficiency), it is evident that the mushroom number, productivity and biological efficiency are dependent, while in another direction was the mushroom weight, showing a negative Pearson correlation (r = -0,928), as shown in Figure 4.

Figure 4
Scatter plot and Pearson's correlation coefficient matrix for comparisons between agronomic behavior data Pleurotus species/varieties, where: Numush: number of mushrooms, Mmw: weight of mushroom, and Bioef: biological efficiency. *Indicate statistical difference (p<0.05), ** difference with negative correlation, and *** difference with positive correlation.

According to Figure 5, it can be noted that for P. ostreatus var Florida, scratching done before the first flush tended to increase the yield in this flush, decreasing it in the second. On the other hand, P. djamor with scratching just done before the second flush reduced the yield in this flush. The scratching technique does not change the precocity in the studied species/varieties.

Figure 5
Yield of Pleurotus according to harvest flushes, with scratching done in the first and second flush and scratching done only in the second flush.

DISCUSSION

Oliveira and Naozuka [²³23 Oliveira AP, Naozuka J. Preliminary results on the feasibility of producing selenium-enriched pink (Pleurotus djamor) and white (Pleurotus ostreatus) oyster mushrooms: Bioaccumulation, bioaccessibility, and Se-proteins distribution. Microchem J. 2019 Mar;145:1143-50.], studying P. ostreatus and P. djamor in sugarcane bagasse-based substrate, obtained 21 and 26% of biological efficiency, respectively, which is in agreement with the results of this research, since that P. djamor showed biological efficiency superior to P. ostreatus in both treatments, with and without application of scratching. Likewise, Atila [²⁴24 Atila F. Evaluation of suitability of various agro-wastes for productivity of Pleurotus djamor, Pleurotus citrinopileatus and Pleurotus eryngii mushrooms. J Exp Agric Int. 2017 Sept;11(5):1-11.] obtained yield and biological efficiency with values even higher than those found in this research cultivating P. djamor, which highlights the importance of using lignocellulosic residues, such as sawdust, for oyster cultivation.

Among the species studied, P. ostreatus had the lowest biological efficiency, with 20.85% and 20.28% for the treatment with and without scratching in only one flush. These values are considered low, since Curvetto and coauthors [²⁵25 Curvetto NR, Figlas D, Devalis R, Delmastro S. Growth and productivity of different Pleurotus ostreatus strains on sunflower seed hulls supplemented with N-NH4+ and/or Mn (II). Bioresour Technol. 2002 Sept;84(2):171-6.] reached values of biological efficiency between 37.2% and 73.6%. P. ostreatus has the ability to adapt to different temperatures, being able to be cultivated between 20 and 25ºC [⁷7 Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46.], so this factor was not limiting in the yield of the species in this work, where the cultivation was conducted at 21± 2ºC.

On the other hand, it is observed that P. ostreatus demands low temperatures for fruiting induction, ranging from 10 to 15ºC [²⁶26 Marino RH, Eira AFD, Kuramae EE, Queiroz EC. Morphomolecular characterization of Pleurotus ostreatus (Jacq. Fr.) Kummer strains in relation to luminosity and temperature of frutification. Sci Agric. 2003 June;60(3):531-5.,²⁷27 Owaid MN, Abed AM, Nassar BM, 2015. Recycling cardboard wastes to produce blue oyster mushroom Pleurotus ostreatus in Iraq. Emir J Food Agric. 2015 April;27(7):537-41.], unlike the other species, where induction occurs between 18 and 25ºC (P. djamor) and around 26±5ºC for P. ostreatus var. Florida [⁷7 Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46., ²⁸28 Zied DC, Pardo-Giménez A, de Oliveira GA, Carrasco J, Zeraik ML. Study of waste products as supplements in the production and quality of Pleurotus ostreatus var. Florida. Indian J Microbiol. 2019 Apr;59(3):328-35.]. In this case, the absence of ideal conditions for induction of primordia may be reduced the efficiency of P. ostreatus in these cultivation conditions, since the temperature remained stable.

P. ostreatus and P. djamor species have a common method of substrate treatment, which is autoclaving and larger range of fruiting temperatures. On the other hand, P. ostreatus var. Florida has different treatment methods, and a smaller temperature variation (Table 3). So, the first factor that appears to influence Pleurotus yields is the substrate formulation process, and second the cultivation conditions. The number of flushes and production time is also important factor that be considerate due biological efficiency influence.

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Table 3
Comparison between biological efficiency of Pleurotus spp. according to the cultivation conditions.

Regarding the number of mushrooms, Shubhra and Jaitly [³⁰30 Shubhra S, Jaitly AK. Morphological and biochemical characterization of different oyster mushroom (Pleurotus spp.). J Phytol. 2011 May;3(8):18-20.] studying P. ostreatus var. Florida and P. djamor in wheat straw, produced 6.33 and 8.67 mushrooms per 0.5 kg of substrate, values below those found by this research, demonstrating that it is possible to produce a high number of mushrooms using the scratching technique. Shubhra and Jaitly [³⁰30 Shubhra S, Jaitly AK. Morphological and biochemical characterization of different oyster mushroom (Pleurotus spp.). J Phytol. 2011 May;3(8):18-20.], cultivating P. ostreatus var. Florida in wheat straw, obtained mushroom greater than that of P. djamor, similar our results.

Victor and Ifeanyi [³²32 Victor WC, Ifeanyi W. The Effect of nutrient concentration on the yield of mushroom (Pleurotus ostreatus). Greener J Agric Sci. 2013 Jun;3(6):437-44.], producing P. ostreatus in sawdust supplemented with 10% wheat bran, similar to the formulation studied here, reached a yield of 10%. Yamauchi and coauthors [¹¹11 Yamauchi M, Sakamoto M, Yamada M, Hara H, Taib S.M, Rezania S, et al. Cultivation of oyster mushroom (Pleurotus ostreatus) on fermented moso bamboo sawdust. J King Saud Univ Sci. 2019 Oct;31(4):490-4.] cultivating P. ostreatus on bamboo sawdust and rice bran, applied the scratching technique on opened substrate bags, with the aim of breaking the surface layer of mycelium. Although the authors did not compare the application or not of scratching, they reached high values of mushroom number (33.6 mushrooms/0.6 kg of substrate) and productivity (97.9 g/0.6 kg of substrate).

Taking into account that the first flush is usually the most productive for this genus, the results of this research follow the results obtained by Atila [²⁴24 Atila F. Evaluation of suitability of various agro-wastes for productivity of Pleurotus djamor, Pleurotus citrinopileatus and Pleurotus eryngii mushrooms. J Exp Agric Int. 2017 Sept;11(5):1-11.], Ashraf and coauthors [³³33 Ashraf J, Ali MA, Ahmad W, Ayyyub CM, Shafi J. Effect of different substrate supplements on oyster mushroom (Pleurotus spp.) production. Food Sci Technol. 2013; 1(3):44-51.], Obodai and Vowotor [²⁹29 Obodai M, Vowotor KA. Performance of different strains of Pleurotus species under Ghanaian conditions. Afr J Food Sci. 2002; 7(3):98-100.], and Ali and coauthors [³⁴34 Ali N, Khairudin H, Mohamed M, Hassan O. Cultivation of Pleurotus ostreatus on oil palm fronds mixed with rubber tree sawdust. Chem Eng Trans. 2018 May;63:547-52.], where all had the highest yield in the first flush and lower in the subsequent flush.

One of the biggest costs in mushroom production is labor. Araújo and coauthors [³⁵35 Araújo WJ, Costa AF, Alves ER, Bragato LS, Vieira LP, Costa H, et al. [Analysis of production costs of Champignon in Domingos Martins, ES]. In: Costa AF, editor. Custos na Agricultura da Região Serrana do Espírito Santo. Editora Pedro & João, 2020. p. 105-23.] found that 10.03% of the cost for the production of substrate in the production of Agaricus bisporus is related to labor, and in cultivation this percentage rises to 56.29%. In this sense, proposing another process in the production chain requires an expressive response in yields, which justify its addition. Therefore, no significant increases in yield were observed for the species of P. ostreatus and P. ostreatus var. Florida that supports the use of the scratching technique. In the same way, the species of P. djamor obtained a short increase in productivity (1.63%), which does not allow the use of the technique, even due to the increase in the number of mushrooms that reflects a lower weight of mushroom, which affects the commercial value [³⁶36 Tsing A. Sorting out commodities:How capitalist value is made through gifts. J Ethnogr Theory. 2013 Apr; 3(1):21-43.,³⁷37 Rosendo ECFG. [Contribution to the study of the application of high hydrostatic pressure technology in the conservation of the mushroom Pleurotus ostreatus]. [Dissertation]. Bragança: Instituto Politécnico, Escola Superior Agrária de Bragança (Portugal); 2014. 134 p.] and harvest time.

As already discussed, different materials in the formulation of substrates can provide higher or lower yields (Table 3). It is important to point out that a better agronomic behavior can be achieved through the adoption of other technologies and cultivation characteristics, highlighting the importance of future studies on the scratching technique in Pleurotus that address other conditions and cultivation techniques.

CONCLUSION

The effectiveness of the scratching technique can be selective for different species/varieties of Pleurotus, been P. djamor higher yields and P. ostreatus had losses in weight of mushrooms. The technique is not indicated for the species studied here, as it promotes an increase in labor during cultivation and, on the other hand, offers little or no gain in yield.

REFERENCES

¹
Santos RRD, Guarnieri P, Brisola M. [Reverse logistics of waste from agrosilvopastoral and agroindustrial activities: a systematic literature review]. Rev em Agronegocio e Meio Ambient. 2018 Apr/June;11(2):573-97.
²
Viana LG, Cruz OS. [Reuse of agro-industrial waste]. In: IV Congresso Baiana de Engenharia Sanitária e Ambiental; 2016 Jul 13-16, Cruz das Almas, Bahia, Brazil: p. 1-3.
³
Sadh PK, Duhan S, Duhan JS. Agro-industrial wastes and their utilization using solid state fermentation: a review. Bioresour Bioprocess. 2018 Jan;5(1):1-15.
⁴
Muthangya M, Hashim SO, Amana JM, Mshandete AM, Kivaisi AK. Optimization of Pleurotus mushroom cultivation on saline sisal solid waste. World Appl Sci J. 2013 May;23(9):1146-50.
⁵
Royse DJ, Baars J, Tan Q. Current overview of mushroom production in the world. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Ltd, 2017. p. 5-13.
⁶
Debnath S, Saha R, Das P, Saha AK. Cultivation and medicinal properties of wild edible Pleurotus ostreatus of Tripura, Northeast India. Vegetos. 2019 June;32(3):238-46.
⁷
Bellettini MB, Fiorda FA, Maieves HA, Teixeira GL, Ávila S, Hornung PS, et al. Factors affecting mushroom Pleurotus spp. Saudi J Biol Sci. 2019 Apr;26(4):633-46.
⁸
Ita V, Angeles M, Antonio C, Dolores M, Huerta Lara M, Romero-Arenas O. [Wild Reed (Arundo donax) as an alternative substrate in the production of Pleurotus ostreatus]. Scientia Fungorum. 2018 June;48:15-22.
⁹
Adewoyin AG, Ayandele AA. Comparative study of yield performance and nutrient composition of the edible mushroom Pleurotus pulmonarius, cultivated on different substrates. Afr J Plant Sci. 2018 Aug;12(8):148-54.
¹⁰
Shnyreva AA, Kozhevnikova EY, Barkov AV, Shnyreva AV. Solid-state cultivation of edible oyster mushrooms, Pleurotus spp. under laboratory conditions. Adv Microbiol. 2017 Feb;7(2):125-36.
¹¹
Yamauchi M, Sakamoto M, Yamada M, Hara H, Taib S.M, Rezania S, et al. Cultivation of oyster mushroom (Pleurotus ostreatus) on fermented moso bamboo sawdust. J King Saud Univ Sci. 2019 Oct;31(4):490-4.
¹²
Doroški A, Klaus A, Režek Jambrak A, Djekic I. Food Waste Originated Material as an Alternative Substrate Used for the Cultivation of Oyster Mushroom (Pleurotus ostreatus): A Review. Sustainability. 2022 Sept;14(19):12509.
¹³
Prasad S, Rathore H, Sharma S, Tiwari G. Yield and proximate composition of Pleurotus florida cultivated on wheat straw supplemented with perennial grasses. Indian J. Agric. Sci. 2018 Jan;88:91-4.
¹⁴
Choi KW. Shelf cultivation of oyster mushroom with emphasis on substrate fermentation. Gush, R, editor. In Mushroom Growers’ Handbook 1. Oyster Mushrooms Cultivation. Part II: Oyster Mushrooms. MushWorld, Korea; 2018. p. 153-165.
¹⁵
Gowthaman MK, Krishna C, Moo-Young M. Fungal solid state fermentation-an overview. Appl .Mycol biotechnol. 2001 Sept;1:305-52.
¹⁶
Yamanaka K. Cultivation of mushrooms in plastic bottles and small bags. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Lta, 2017. p. 309-338.
¹⁷
Pani BK. Effect of age and quantity of spawn on milky mushroom production. Asian J Exp Biol Sci. 2011;2(4), 769-71.
¹⁸
Vieira Junior WG, Centeio Cardoso RV, Fernandes Â, Ferreira ICFR, Barros L, Pardo-Giménez A, et al. Influence of strains and environmental cultivation conditions on the bioconversion of ergosterol and vitamin D2 in the sun mushroom. J Sci Food Agric. 2022 June;102(4):1699-706.
¹⁹
Raman J, Jang KY, Oh YL, Oh M, Im JH, Lakshmanan H, et al. Cultivation and nutritional value of prominent Pleurotus spp.: An overview. Mycobiology. 2021 Nov;49(1):1-14.
²⁰
Zakil FA, Isa RM, Sueb MSM, Isha R. Growth performance and mineral analysis of Pleurotus ostreatus (oyster mushroom) cultivated on spent mushroom medium mixed with rubber tree sawdust. Mater Today: Proc. 2022 Apr;57:1329-37.
²¹
Okwulehie IC, Okwuowulu EO, Ezeh CG, Ikechukwu GC. Yield potentials, nutritional and mycochemical properties of fruit-bodies of Pleurotus ostreatus var. florida, grown on Andropogon gayanus straw; supplemented with Anthonotha macrophylla. Int J Mod Biol Res. 2017 Mar;5:24-31.
²²
Albertia MM, Cunha MLO, Mendes DW, Vieira Junior WG, Zied DC. Tecnologic Development on Pleurotus Cultivation: Specific Practices Used in Brazil. Braz Arch Biol Technol. 2021 Dec;64:e21200198.
²³
Oliveira AP, Naozuka J. Preliminary results on the feasibility of producing selenium-enriched pink (Pleurotus djamor) and white (Pleurotus ostreatus) oyster mushrooms: Bioaccumulation, bioaccessibility, and Se-proteins distribution. Microchem J. 2019 Mar;145:1143-50.
²⁴
Atila F. Evaluation of suitability of various agro-wastes for productivity of Pleurotus djamor, Pleurotus citrinopileatus and Pleurotus eryngii mushrooms. J Exp Agric Int. 2017 Sept;11(5):1-11.
²⁵
Curvetto NR, Figlas D, Devalis R, Delmastro S. Growth and productivity of different Pleurotus ostreatus strains on sunflower seed hulls supplemented with N-NH4+ and/or Mn (II). Bioresour Technol. 2002 Sept;84(2):171-6.
²⁶
Marino RH, Eira AFD, Kuramae EE, Queiroz EC. Morphomolecular characterization of Pleurotus ostreatus (Jacq. Fr.) Kummer strains in relation to luminosity and temperature of frutification. Sci Agric. 2003 June;60(3):531-5.
²⁷
Owaid MN, Abed AM, Nassar BM, 2015. Recycling cardboard wastes to produce blue oyster mushroom Pleurotus ostreatus in Iraq. Emir J Food Agric. 2015 April;27(7):537-41.
²⁸
Zied DC, Pardo-Giménez A, de Oliveira GA, Carrasco J, Zeraik ML. Study of waste products as supplements in the production and quality of Pleurotus ostreatus var. Florida. Indian J Microbiol. 2019 Apr;59(3):328-35.
²⁹
Obodai M, Vowotor KA. Performance of different strains of Pleurotus species under Ghanaian conditions. Afr J Food Sci. 2002; 7(3):98-100.
³⁰
Shubhra S, Jaitly AK. Morphological and biochemical characterization of different oyster mushroom (Pleurotus spp.). J Phytol. 2011 May;3(8):18-20.
³¹
Hasan MT, Khatun MHA, Sajib MAM, Rahman M, Rahman MS, Roy M, et al. Effect of wheat bran supplement with sugarcane bagasse on growth, yield and proximate composition of Pink Oyster Mushroom (Pleurotus djamor). Am J Food Technol. 2015 Jul;3:150-7.
³²
Victor WC, Ifeanyi W. The Effect of nutrient concentration on the yield of mushroom (Pleurotus ostreatus). Greener J Agric Sci. 2013 Jun;3(6):437-44.
³³
Ashraf J, Ali MA, Ahmad W, Ayyyub CM, Shafi J. Effect of different substrate supplements on oyster mushroom (Pleurotus spp.) production. Food Sci Technol. 2013; 1(3):44-51.
³⁴
Ali N, Khairudin H, Mohamed M, Hassan O. Cultivation of Pleurotus ostreatus on oil palm fronds mixed with rubber tree sawdust. Chem Eng Trans. 2018 May;63:547-52.
³⁵
Araújo WJ, Costa AF, Alves ER, Bragato LS, Vieira LP, Costa H, et al. [Analysis of production costs of Champignon in Domingos Martins, ES]. In: Costa AF, editor. Custos na Agricultura da Região Serrana do Espírito Santo. Editora Pedro & João, 2020. p. 105-23.
³⁶
Tsing A. Sorting out commodities:How capitalist value is made through gifts. J Ethnogr Theory. 2013 Apr; 3(1):21-43.
³⁷
Rosendo ECFG. [Contribution to the study of the application of high hydrostatic pressure technology in the conservation of the mushroom Pleurotus ostreatus]. [Dissertation]. Bragança: Instituto Politécnico, Escola Superior Agrária de Bragança (Portugal); 2014. 134 p.

Funding:

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

Edited by

Editor-in-Chief:

Bill Jorge Costa

Associate Editor:

Ana Cláudia Barana

Publication Dates

Publication in this collection
03 July 2023
Date of issue
2023

History

Received
29 Sept 2022
Accepted
07 Mar 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[11] ¹¹
Yamauchi M, Sakamoto M, Yamada M, Hara H, Taib S.M, Rezania S, et al. Cultivation of oyster mushroom (Pleurotus ostreatus) on fermented moso bamboo sawdust. J King Saud Univ Sci. 2019 Oct;31(4):490-4.

[12] ¹²
Doroški A, Klaus A, Režek Jambrak A, Djekic I. Food Waste Originated Material as an Alternative Substrate Used for the Cultivation of Oyster Mushroom (Pleurotus ostreatus): A Review. Sustainability. 2022 Sept;14(19):12509.

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Prasad S, Rathore H, Sharma S, Tiwari G. Yield and proximate composition of Pleurotus florida cultivated on wheat straw supplemented with perennial grasses. Indian J. Agric. Sci. 2018 Jan;88:91-4.

[14] ¹⁴
Choi KW. Shelf cultivation of oyster mushroom with emphasis on substrate fermentation. Gush, R, editor. In Mushroom Growers’ Handbook 1. Oyster Mushrooms Cultivation. Part II: Oyster Mushrooms. MushWorld, Korea; 2018. p. 153-165.

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[16] ¹⁶
Yamanaka K. Cultivation of mushrooms in plastic bottles and small bags. In: Zied DC, Pardo-Giménez A, editors. Edible and medicinal mushrooms: technology and applications. John Wiley & Sons Lta, 2017. p. 309-338.

[17] ¹⁷
Pani BK. Effect of age and quantity of spawn on milky mushroom production. Asian J Exp Biol Sci. 2011;2(4), 769-71.

[18] ¹⁸
Vieira Junior WG, Centeio Cardoso RV, Fernandes Â, Ferreira ICFR, Barros L, Pardo-Giménez A, et al. Influence of strains and environmental cultivation conditions on the bioconversion of ergosterol and vitamin D2 in the sun mushroom. J Sci Food Agric. 2022 June;102(4):1699-706.

[19] ¹⁹
Raman J, Jang KY, Oh YL, Oh M, Im JH, Lakshmanan H, et al. Cultivation and nutritional value of prominent Pleurotus spp.: An overview. Mycobiology. 2021 Nov;49(1):1-14.

[20] ²⁰
Zakil FA, Isa RM, Sueb MSM, Isha R. Growth performance and mineral analysis of Pleurotus ostreatus (oyster mushroom) cultivated on spent mushroom medium mixed with rubber tree sawdust. Mater Today: Proc. 2022 Apr;57:1329-37.

[21] ²¹
Okwulehie IC, Okwuowulu EO, Ezeh CG, Ikechukwu GC. Yield potentials, nutritional and mycochemical properties of fruit-bodies of Pleurotus ostreatus var. florida, grown on Andropogon gayanus straw; supplemented with Anthonotha macrophylla. Int J Mod Biol Res. 2017 Mar;5:24-31.

[22] ²²
Albertia MM, Cunha MLO, Mendes DW, Vieira Junior WG, Zied DC. Tecnologic Development on Pleurotus Cultivation: Specific Practices Used in Brazil. Braz Arch Biol Technol. 2021 Dec;64:e21200198.

[23] ²³
Oliveira AP, Naozuka J. Preliminary results on the feasibility of producing selenium-enriched pink (Pleurotus djamor) and white (Pleurotus ostreatus) oyster mushrooms: Bioaccumulation, bioaccessibility, and Se-proteins distribution. Microchem J. 2019 Mar;145:1143-50.

[24] ²⁴
Atila F. Evaluation of suitability of various agro-wastes for productivity of Pleurotus djamor, Pleurotus citrinopileatus and Pleurotus eryngii mushrooms. J Exp Agric Int. 2017 Sept;11(5):1-11.

[25] ²⁵
Curvetto NR, Figlas D, Devalis R, Delmastro S. Growth and productivity of different Pleurotus ostreatus strains on sunflower seed hulls supplemented with N-NH4+ and/or Mn (II). Bioresour Technol. 2002 Sept;84(2):171-6.

[26] ²⁶
Marino RH, Eira AFD, Kuramae EE, Queiroz EC. Morphomolecular characterization of Pleurotus ostreatus (Jacq. Fr.) Kummer strains in relation to luminosity and temperature of frutification. Sci Agric. 2003 June;60(3):531-5.

[27] ²⁷
Owaid MN, Abed AM, Nassar BM, 2015. Recycling cardboard wastes to produce blue oyster mushroom Pleurotus ostreatus in Iraq. Emir J Food Agric. 2015 April;27(7):537-41.

[28] ²⁸
Zied DC, Pardo-Giménez A, de Oliveira GA, Carrasco J, Zeraik ML. Study of waste products as supplements in the production and quality of Pleurotus ostreatus var. Florida. Indian J Microbiol. 2019 Apr;59(3):328-35.

[29] ²⁹
Obodai M, Vowotor KA. Performance of different strains of Pleurotus species under Ghanaian conditions. Afr J Food Sci. 2002; 7(3):98-100.

[30] ³⁰
Shubhra S, Jaitly AK. Morphological and biochemical characterization of different oyster mushroom (Pleurotus spp.). J Phytol. 2011 May;3(8):18-20.

[31] ³¹
Hasan MT, Khatun MHA, Sajib MAM, Rahman M, Rahman MS, Roy M, et al. Effect of wheat bran supplement with sugarcane bagasse on growth, yield and proximate composition of Pink Oyster Mushroom (Pleurotus djamor). Am J Food Technol. 2015 Jul;3:150-7.

[32] ³²
Victor WC, Ifeanyi W. The Effect of nutrient concentration on the yield of mushroom (Pleurotus ostreatus). Greener J Agric Sci. 2013 Jun;3(6):437-44.

[33] ³³
Ashraf J, Ali MA, Ahmad W, Ayyyub CM, Shafi J. Effect of different substrate supplements on oyster mushroom (Pleurotus spp.) production. Food Sci Technol. 2013; 1(3):44-51.

[34] ³⁴
Ali N, Khairudin H, Mohamed M, Hassan O. Cultivation of Pleurotus ostreatus on oil palm fronds mixed with rubber tree sawdust. Chem Eng Trans. 2018 May;63:547-52.

[35] ³⁵
Araújo WJ, Costa AF, Alves ER, Bragato LS, Vieira LP, Costa H, et al. [Analysis of production costs of Champignon in Domingos Martins, ES]. In: Costa AF, editor. Custos na Agricultura da Região Serrana do Espírito Santo. Editora Pedro & João, 2020. p. 105-23.

[36] ³⁶
Tsing A. Sorting out commodities:How capitalist value is made through gifts. J Ethnogr Theory. 2013 Apr; 3(1):21-43.

[37] ³⁷
Rosendo ECFG. [Contribution to the study of the application of high hydrostatic pressure technology in the conservation of the mushroom Pleurotus ostreatus]. [Dissertation]. Bragança: Instituto Politécnico, Escola Superior Agrária de Bragança (Portugal); 2014. 134 p.

	Species/varieties
Scratching	P. ostreatus	P. ostreatus var. Florida	P. djamor
Yield (%)
With	6.2 b	8.3 a	6.6 b
Without	6.0	7.4	6.5
CV (%)	18.43
Number of mushroom (u)
With	7.2 b	8.1 b	38.5 a A
Without	5.2 b	6.7 b	23.8 a B
CV (%)	48.89
Weight of mushroom (g)
With	4.55 a B	5.25 a	1.07 b
Without	5.80 a A	5.65 a	1.54 b
CV (%)	20.19
Biological efficiency (%)
With	20.85 b	27.71 a	22.28 b
Without	20.28	24.76	22.26
CV (%)	18.43

	Species/varieties
Scratching	P. ostreatus	P. ostreatus var. Florida	P. djamor
Yield (%)
1^st and 2^nd flush	6.25 c	13.2 a	11.17 b A
2^nd flush	6.08 c	12.8 a	9.54 b B
CV (%)	14.37
Number of mushroom (u)
1^st and 2^nd flush	7.28 c	18.71 b	50.71 a A
2^nd flush	5.28 c	18.57 b	29.71 a B
CV (%)	37.78
Weight of mushroom (g)
1^st and 2^nd flush	4.55 a B	3.61 b	1.24 c
2^nd flush	5.80 a A	3.47 b	1.72 c
CV (%)	19.68
Biological efficiency (%)
1^st and 2^nd flush	20.85 c	44.00 a	37.23 b A
2^nd flush	20.28 c	42.66 a	31.80 b B
CV (%)	14.37

References	Base substrate	Substrate treatment	Biological	Number	Cultivation conditions
			efficiency (%)	of flushes	Temp (°C)	MSTR (%)
Pleurotus ostreatus
This Work	Eucalyptus sawdust	Autoclaving	20.85*	1	21 ± 2	75 ± 5
[²³23 Oliveira AP, Naozuka J. Preliminary results on the feasibility of producing selenium-enriched pink (Pleurotus djamor) and white (Pleurotus ostreatus) oyster mushrooms: Bioaccumulation, bioaccessibility, and Se-proteins distribution. Microchem J. 2019 Mar;145:1143-50.]	Sugarcane bagasse	Autoclaving	21	1	24 ± 1	80
[¹¹11 Yamauchi M, Sakamoto M, Yamada M, Hara H, Taib S.M, Rezania S, et al. Cultivation of oyster mushroom (Pleurotus ostreatus) on fermented moso bamboo sawdust. J King Saud Univ Sci. 2019 Oct;31(4):490-4.]	Bamboo sawdust	Autoclaving	44.09	-	14 ± 1	90 ± 5
[²⁹29 Obodai M, Vowotor KA. Performance of different strains of Pleurotus species under Ghanaian conditions. Afr J Food Sci. 2002; 7(3):98-100.]	T. scleroxylon sawdust	Autoclaving	50.93	6	28 ± 3	90 ± 5
Pleurotus ostreatus var. Florida
This Work	Eucalyptus sawdust	Autoclaving	43.33*	2	21 ± 2	75 ± 5
[³⁰30 Shubhra S, Jaitly AK. Morphological and biochemical characterization of different oyster mushroom (Pleurotus spp.). J Phytol. 2011 May;3(8):18-20.]	Wheat straw	Chemical disinfection	13	5	25 ± 3	77.5 ± 2.5
[²⁵25 Curvetto NR, Figlas D, Devalis R, Delmastro S. Growth and productivity of different Pleurotus ostreatus strains on sunflower seed hulls supplemented with N-NH4+ and/or Mn (II). Bioresour Technol. 2002 Sept;84(2):171-6.]	B. dictyoneura	Pasteurization	138.7	4	26 ± 5	80 ± 10
[²¹21 Okwulehie IC, Okwuowulu EO, Ezeh CG, Ikechukwu GC. Yield potentials, nutritional and mycochemical properties of fruit-bodies of Pleurotus ostreatus var. florida, grown on Andropogon gayanus straw; supplemented with Anthonotha macrophylla. Int J Mod Biol Res. 2017 Mar;5:24-31.]	Andropogon straw	Pasteurization	12.3	3	-	-
Pleurotus djamor
This Work	Eucalyptus sawdust	Autoclaving	37.23*	2	21 ± 2	75 ± 5
[²³23 Oliveira AP, Naozuka J. Preliminary results on the feasibility of producing selenium-enriched pink (Pleurotus djamor) and white (Pleurotus ostreatus) oyster mushrooms: Bioaccumulation, bioaccessibility, and Se-proteins distribution. Microchem J. 2019 Mar;145:1143-50.]	Sugarcane bagasse	Autoclaving	26	1	24 ± 1	80
[²⁴24 Atila F. Evaluation of suitability of various agro-wastes for productivity of Pleurotus djamor, Pleurotus citrinopileatus and Pleurotus eryngii mushrooms. J Exp Agric Int. 2017 Sept;11(5):1-11.]	Stem of Phaseolus	Autoclaving	78.2	3	17 ± 1	85
[³¹31 Hasan MT, Khatun MHA, Sajib MAM, Rahman M, Rahman MS, Roy M, et al. Effect of wheat bran supplement with sugarcane bagasse on growth, yield and proximate composition of Pink Oyster Mushroom (Pleurotus djamor). Am J Food Technol. 2015 Jul;3:150-7.]	Sugarcane bagasse	Autoclaving	50.59	5	25 ± 3	77.5 ± 2.5

Brasil

Brasil

The application of the scratching technique has the same effect on Pleurotus spp.?

Abstract

HIGHLIGHTS

INTRODUCTION

MATERIAL AND METHODS

RESULTS

DISCUSSION

CONCLUSION

REFERENCES

Funding:

Edited by

Editor-in-Chief:

Associate Editor:

Publication Dates

History