Effects of biostimulants in horticulture: Comparison
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The biostimulant segment is becoming increasingly important worldwide. One of the reasons for this is that fewer plant protection products are placed on the market in the European Union, and environmental sustainability also plays an important role in their use. Biostimulants are often used in several horticultural sectors, including ornamentals, to strengthen plants, achieve commercial standards, produce quality goods, increase plant vitality, and aid harvesting.

  • biostimulant
  • horticulture
  • Ornamental Plants
  • humic and fulvic acids
  • abiotic stress tolerance
  • seaweed extracts
  • ornamental

1. Introduction

Biostimulants can be defined as small amounts of organic or inorganic matter that promote the growth and development of plants in a way that they would not be able to perform without the addition of these compounds. They can also be referred to as ‘positive growth regulators’ or ‘metabolic enhancers’ [1]. The term ‘plant biostimulant’ was first used by Zhang and Schmidt [2], and the industry based on it began to evolve, as did the materials and technologies used. Calvo defined in 2014 [3] that all substances and microorganisms that are beneficial to the plant are considered biostimulants. A year later, in 2015, Du Jardin [4] mentions that the definition of biostimulants is based on what is not a biostimulant rather than what is. For example, fertilizers and pesticides increase plant yields but are not biostimulants.
In the United States, the Coalition of Biostimulants defines biostimulants as substances, including microorganisms, which, when applied to a plant, seeds, soil, or growing media, enhance the nutrient uptake capacity of plants and are beneficial to plant development. Biostimulants are also defined as non-plant nutrients and, therefore, cannot be characterized by nutrient claims [5]. Although they affect growth and development, they also increase resistance to abiotic stress [4]. In 2016, the European Commission classified biostimulants in the CE category, according to which they are fertilizer products that help the growth and development of the plant regardless of the amount applied [6]. In 2018, as defined by the Council of the European Union as an amendment to the definition, they should have one of the effects on the plant rhizosphere, in addition to those described above as follows: (i) more efficient nutrient use, (ii) tolerance to abiotic stress, or (iii) effect on crop quality and (iv) availability of confined nutrients in soil or rhizosphere [7].
Recently, the agricultural sector has faced the challenge of increasing productivity by feeding a growing global population, mainly by increasing resource efficiency while reducing adverse impacts on ecosystems and the human body [8]. One way to reduce fertilizer use without compromising plant nutrition is to increase nutrient uptake by plants using biostimulants [9]. Their use has become common in agricultural and horticultural practices [10]. Their effects are still largely unknown today, but they usually have a positive effect on plants [11]. In its broader definition, substances categorized as biofertilizers or biopesticides also fall into the category [12]. The term ‘biostimulants’ often includes natural stimulants, including phenols, salicylic acid, humic and fulvic acids, or protein hydrolases [4]. Their positive effects on horticultural production are mainly due to bioactive compounds that stimulate plant growth, such as phytohormones, amino acids, and nutrients [9]. Biostimulant compositions may be mono- or multicomponent, but synergistic effects of several different components have been observed. Several groups of biostimulants have been distinguished according to their mode of application (soil, foliage), the material of their production (plant, animal), or the process of their formation (hydrolysis, fermentation, extraction) [13]. These compounds help plants grow and develop in a number of ways [14]. Based on the work of Abbott et al. [15], biological modifiers can be divided into the following three main types: groups of biostimulants, organic substances, and microbial inoculants. Within this grouping system, biostimulants include amino acids, chitosan, seaweed extracts, and humic substances.
If the mechanism of action of biostimulants is largely unknown, biostimulants can only be regulated by demonstrating their safety and efficacy and determining a broad mechanism of action (Table 1) [16]. The development of new molecular biotechnology methods will soon help to understand the mechanisms and even possible modes of action of biostimulants [17]. Some studies have shown that biostimulants have no negative effects on the environment or human health due to the low biological toxicity of their components, their rapid degradation in the environment, their low mobility in food, and their low application rate. Their use can be very important in improving agricultural sustainability as they can promote increased production with lower environmental impact [18].
Tw
Table 1. Proposed biostimulant categories [16].

 

Filatov, 1951b

Ikrina and Kolbin, 2004

Kauffman et al., 2007

Du Jardin, 2012

Calvo et al., 2014

Halpern et al., 2015

Du Jardin, 2015

Torre et al., 2016

1

Carboxylic fatty acids (oxalic acid and succiric acid)

Microorganisms (bacteria, fungi)

Humic substances

Humic substances

Microbial inoculants

Humic substances

Humic and fulvic acids

Humic substances

2

Carboxylic fatty hydroxyl acids (malic and tartaric acids)

Plant materials (land, freshwater and marine)

Hormone containing products (seaweed extracts)

Complex organic materials

Humic acids

Protein hydrolysate and amino acid formulations

Protein hydrolysates and other N-containing compounds

Seaweed extracts

3

Unsaturated fatty acids, aromatic and phenolic acids (cinnamic and hydroxycinnamic acids, coumarin)

Sea shellfish, animals, bees

Amino acid containing products

Beneficial chemical elements

Fulvic acids

Seaweed extract

Seaweed extracts and botanicals

Hydrolyzed proteins and amino acids

4

Phenolic aromatic acids containing several benzene rings linked via carbon atoms (humic acids)

Humate- and humus-containing substances

-

Inorganic salts (such as phosphite)

Protein hydrolysates and amino acids

Plant-growth-promoting microorganism (including mycorrhizal fungi)

Chitosan and other biopolymers

Inorganic salts

5

-

Vegetable oils

-

Seaweed extracts

Seaweed extracts

-

Inorganic compounds

Microorganisms

6

-

Natural minerals

-

Chitin and chitosan derivatives

-

-

Beneficial fungi

-

7

-

Water (activated, degassed, thermal)

-

Free amino acids and other N-containing substances

-

-

Beneficial bacteria

-

8

-

Resins

-

 

-

-

-

-

9

-

Other raw materials (oil and petroleum fraction, shale substance

-

-

-

-

-

-

Twenty years ago, in 2002, relatively little research was conducted to document the effects of most biostimulants on crop production or to demonstrate their potential effects on soil processes [19]. Today, all this has changed, and the research and application of biostimulants are evolving at a rapid pace. The demand for sustainable agricultural practices continues to grow with the exclusion of synthetic fertilizers and pesticides [20]. Currently, the legislation also restricts the use of mineral fertilizers and pesticides in the European Union. Thus, the reduced use of chemicals is forced, either by parallel application or by partial replacement with formulations that can increase the effectiveness of conventional treatment [21,22]. New EU rules have forced Member States to amend or withdraw authorizations for products used in plant protection that contain active substances such as auxin (indole-3-butyric acid, IBA) [23]. Due to an increased environmental awareness, the use of synthetic chemicals in agriculture and horticulture to ensure optimal yields is less favorable. The European Union has an EU directive to limit the use of nitrates (91/676/EEC) and a directive banning all persistent, bioaccumulative, or toxic plant protection products (2009/128/EC) [24]. Based on EU regulation 2019/1009, biostimulants and other bio-based yield enhancers are also playing an increasingly important role in EU regulation [25]. In the future, a solution must be developed to reduce the use of chemicals and provide an alternative for farmers [26]. Unlike conventional fertilizers or pesticides, biostimulants are unique in that a single substance can affect crop growth and development in multiple ways based on both timing and location of application [27]. Their physiological effects occur after entry into plant tissues and cells, where they are involved in plant metabolism, signal transduction, and hormonal regulation of growth and development [28]. Biostimulants can be used to improve the environmental and economic sustainability of the horticultural sector with environmentally friendly biostimulants. They provide assistance in crop production, increasing cultivation potential and tolerance to abiotic stress [1]. Plant biostimulants are generally applied to high-value plants, mainly greenhouse plants, fruit trees, outdoor vegetables, flowers, and other ornamentals, to increase yield and product quality in a sustainable manner [29]. Many horticultural companies are investing in the development of new biostimulant products and the development of the most effective bioactive molecules capable of eliciting specific plant responses to abiotic stresses [30]. Modern agriculture is paying increasing attention to more sustainable, organic farming systems. Their positive effects on horticultural cultivation are mainly due to bioactive compounds that promote plant growth, such as phytohormones, amino acids, and nutrients [9,31,32]. Reducing the demand for and/or increasing the efficiency of chemicals used in agriculture is crucial due to climate change [33]. Biostimulants of natural origin can play an important role in this respect, as they increase yields in a sustainable way and at a relatively low cost. When placing EU-marked biostimulant products on the market, manufacturers must ensure that they have been manufactured in accordance with the following requirements set out in the European Commission Regulation (2016) [6]: they must draw up the technical documentation and carry out the appropriate conformity assessment procedure.
Plant biostimulants are currently years agoconsidered a full-fledged class of agricultural inputs and are considered an extremely attractive business opportunity for major players in the agro-industry [19]. Recent decades have seen tremendous growth in the use of biostimulants in agriculture. It was estimated in 2014 that revenue from biostimulants could increase to USD 2 billion [3], win 2002th revenue already projected at GBP 2.66 billion in 2022 [20], and otherela projections suggest it could reach USD 3.68 billion in 2022 [21]. Plant bively little research wostimulants also play an important role in improving world nutrition. The development of biostimulants from by-products paves the way for the recycling of waste, bringing benefits to producers, the food industry, traders, as well as condusumers [22]. According ted o the Marketsandmarkets.com (2017) [21] database, Euro document the effects of most pe is the largest LPG market with 34% of the world market share, followed by the North American and Asia-Pacific biostimulant markets, which account for roughly 23% of the global market, respectively. The main factors driving the rapid growth of the biostimulant market are related to the following: (i) the increasing availability of new biostimulants on crop products that meet specific agronomic needs; (ii) the need to promote more efficient and effective use of synthetic chemicals and mineral fertilizers; (iii) the increasing frequency of adverse environmental conditions in terms of yield growth and productivity [23]. As the regulatory system for the use of biostimulan or to demonstrate their pts in the European Union and non-EU countries is not uniform, there is a disproportionate share of small-scale production between producers in each country. It would be necessary to standardize this in the future in order to create a level playing field [17].

2. Groups of Biostimulants

2.1. Industrial By-Products: Protein Hydrolysates and Chitosans

Several types of raw organic matential effects on soil processrials containing biostimulants or biostimulant components from industrial waste have been shown to be effective in both agriculture and horticulture. These include vermicompost, composted municipal waste, sewage sludge, protein hydrolyzate, and chitin/chitosan derivatives [1922]. The use oday, all this has chaf environmentally friendly and sustainable ornamental horticultural technologies with renewable resources has attracted worldwide interest. One such renewable resource is vermicompost [24]. Vermicompost is an orged, and anic matter processed by earthworms. Its production technologies have been widely used to reduce the amount of plant organic waste, manure, paper, food, and sewage sludge [25]. In the case of plants of Amaranthus hybridus L., a significant increasearch and a in protein, carbohydrate, and chlorophyll content was observed with carcininolide, vermicompost leachate, and eckol [26]. Seaweed extracts and leachate from vermicompost stimulate growth and plirotect plants from adverse stress conditions [27]. Amino acids ation of biosnd peptide mixtures can be prepared by chemical and enzymatic protein hydrolysis from agro-industrial by-products, plant sources, and materials of animal origin (e.g., collagen, epithelial tissues) [12]. Plant hydrolysates contaimulaning amino acids and peptides have several positive effects on the yield of various horticultural plants [28]. This effect is related to the upre evolving at a rapid pace. The demgulation of metabolites involved in plant growth processes and the induction of hormone-like activities. These, in turn, affect plant growth and development [29].
Chitosans can also be prepared for sustainable agriby extracting the cell walls of molds. Chitin and chitosan are natural compounds that are biodegradable and non-toxic. They are extremely remarkable for enhancing crop yield [30], preserving crop qultality [31], and contributing to the efficiency of agri-enviralonmental sustainability [32]. Chitosan is a deacetylated form of chitin biopractices continues to grow with the exclusolymer that is produced naturally and industrially. Poly- and oligomers of varying, regulated sizes are used in the food, cosmetics, medical, and agricultural sectors [33]. Chiton of san treatment stimulates the rate of photosynthetic fertilizers and pesticidesis, closure of the stoma through ABA synthesis, enhances antioxidant enzymes through nitric oxide and hydrogen peroxide signaling pathways, and stimulates the production of organic acids, sugars, amino acids, and other metabolites required for osmosis to facilitate adaptation under stress [2034]. Chitosan has been sturrentldied several times as a plant growth regulator and a stress tolerance inducer [35][36]. Synthetic cytokinin could also be replaced by it [37], which could conthe legiribute to the development of sustainable agriculture [38].

2.2. Humic and Fulvic Acids

Fulvic acidsl (FAs) improve the structure ation also rnd fertility of soils with heterogeneous textures and play a crucial role in increasing crop production [39]. Humic substances are natricts the useurally occurring end-products resulting from the decomposition of mineral fertilizers and pesticides croorganisms such as bacteria and fungi, and the chemical decomposition of animal and plant residues in the soil. Humic acid and fulvic acids combine to convert minerals into organic compounds that can be digested very easily by plants [40]. The main effecthe European Unions of humic substances are usually the improvement of root growth and morphological properties, the increase in nutrient uptake and utilization efficiency, and the better yield [41]. The us, the reducee of fulvic acid (FA) on foliage increased the iron uptake and growth of lettuce plants (Lactuca sativa L.) under usecadmium stress [42]. Soaking of onion plants (Allium cepa L.) in fulvic acid increased vegetative development and yield, among othemrs [43]. The use of fulvic als is forced, ecids is an effective solution for crops produced in contaminated industrial areas, such as wheat [44]. In plants of Lepidium sativum, the use of high concentrather by paions of humic and fulvic acids reduced chlorine and cadmium uptake [45]. Humic acid is the most common natural polelymeric substance worldwide [46], which improves nutrient uptake [47]. Humic substances can also be prepliared from leonardites [48]. For example, humic substation or by partialnces (HLSs) obtained from lignin-rich agro-industrial residues isolated by alkaline oxidative hydrolysis have been shown to act as biostimulants for the germination and early development of maize (Zea mays L.) [49]. Humic acid is also involved in photosynthesis, amino acids, careplacement witbohydrates, protein content, nucleic acid synthesis, and enzyme activities [50] and enhances formendogenous auxin signaling in root development [51], bult used at higher concentrations tcauses rooting problems [52].

2.3. Algae Extracts

Anthropogenic climat can increasee change, namely, climate change caused by human activities, is causing problems in agricultural systems [53]. Seaweed exthracts are effectiveness of conventional treatmentderived from the extraction of several macroalgal species, leading to the production of complex mixtures of biologically active compounds depending on the extraction method [2119][22]. Various methods are currently used for this purpose. New EUextraction rules have forced Member States to amend or withdraw authorizatitechnologies are available, such as ultrasonic-assisted extraction (UAE), enzyme-assisted extraction (EAE), supercritical fluid extraction (SFU), microwave-assisted extraction (MAE), and pressure fluid extraction (PLE). Biological compounds offer the advantage of extraction without influencing their activities [54]. The use of marins for prode algae extracts from marine macroalgae due to their beneficial properties began in the mid-2000s [55]. The algae extracts are widely known as substanctes used in to reduce abiotic stress and increase plant protection that contain ductivity. The marine algae extracts are derived from the extraction of several macroalgal species, leading to the production of complex mixtures of biologically active compounds depending on the extraction method [19]. Macroalgae are also effective substances sucbiostimulants on plants grown under stress conditions [28].
Using VOSView bibliographic as auanalysis software, Rodrigues et al. [56] examin (indole-3-bed the titles and abstracts of professional articles (Figure 1). The figure shows tyric acid, IBA)he most common words related to the topic of biostimulants. The colors indicate the year numbers. Although [23].the Dfrue to an increaseit and vegetable sectors were examined, the result was that one of the most researched areas was ‘algae extract’ [56].
Agronomy 12 01043 g001 550
Figure 1. A network of the most commonly used terms in the field of biostimulants [56].
They are largely made efrom brown seaweeds such as Ascophyllum nodosumEcklonia maxima, anvMacrocystis pyrifera and contain pronmentamoter hormones or trace elements such as Fe, Cu, Zn, and Mn [57]. In addition to Ascophyllum nodosum, other brown algae awsuch as Fucus spp., Laminaria spp., Sargassum spp., and Turbinaria spp. aren usessd as biofertilizers in agriculture [58], as the useare the species Macrocystis pyrifera and Durvillea potatorum [59]. Microf synthetic chalgae biostimulants elicit signaling pathways that provide systemic resistance [60]. Recently, aqueous and alkaline extracts fromicals a variety of commercially available algae have been used in agriculture and horticulture to enal systems for foliar spraying, soil tillage, or often a combination of both [61]. In 2017, nearly 47 companies worldwide are cure optimrrently involved in the production of extracts from Ascophytum nodosum for agricul tural and horticultural applications [10]Ascophyllum nodosum is a temperate seaweed found in the Atlantic and Arctic that has been extensively studields is ld for its properties, including promoting plant growth [62]. The poss fible triggering and disease-suppressing effects of Ascophytum nodosum extract were investigated. Spraying Ascophyllum extract on greenhouse-grableown carrots significantly reduced the incidence of Alternaria and Botrytis [63]. TIt also plays a role in the Europecontrol of powdery mildew (Podosphaera aphanis) in strawberry (Fragaria ssp.) cultivation [64]. The Uanthocyanion has an EU directive to limit n content in the peel of apples treated with seaweed extract was significantly higher than that of the control, highlighting the potential effect of these substances on the synthesis of secondary metabolites in apples [65]. In the case of container-grown citrus fruits, Ascophyllum nodosum increases the of ndrought stress resistance of the plant [66]. The extract also itncrates (91/676/EEC)eased phosphorus uptake and salt stress tolerance in Arabidopsis thaliana L. [67] and decrea dirsed oxidative stress [68]. In the ctivultivation of Glycine max (L.), Merill banalso increases macronutrient uptake in plants [69], and thing all persis enhances drought tolerance by altering physiological properties and gene expression [70]. After the use of an agent containing Ascophyllum nodosum, the accumulationt, bioa of transcripts from plant protection genes was rapidly increased, and transcript levels remained high for 96 h after treatment [71]. The algae extracts also affect morphological properties. The Ascophyllum seaweed extract umsed in Chrysanthemum ssp. cultivative, or toion had a significant effect on stem height and diameter as well as root dry matter content [72]Ascophyllum nodosum and Ecklonia maxima in seaweed extracts in potatoes (Solanum tuberosum L.) had only a small effect pon the quality of potato tubers [73]. The effects of algant protection products (2009/128/EC)e extract are particularly pronounced on plant species that have difficulty germinating, rooting, and flowering, or on plants whose growth rate is slower or more difficult to grow in greenhouses and under climatic conditions other than their origin [2474]. BIt can ased on EUlso be used effectively in viticulture [75]. Dureging the propagation of Robinia pseudoacacia L. by cuttings, alation 2019/1009,so used as an ornamental tree, the microalgae extract increased the number of shoots and roots formed on the cuttings [76].
The microalgae biostimulants and biotherfertilizers can be used in crop production to increase the sustainability of agriculture [77]. They can be consiodered a rich source of metabolites in agricultural production [60][78], providing several macro- and microelements for plants [79]. However, the results are not uniform in all cases. Rouphael et al. [80] effectively used algal containing biostimulased nts on spinach plants and found that all agents had a positive effect on yield enhancers are also playing an inand chlorophyll content. The treated plants also showed higher photosynthetic activity. The use of biostimulants may also be beneficial for tomato plants when the plants are grown under stressful conditions, as they have been shown to be effective in alleviating drought and nitrogen deprivation stress [81].

2.4. PGPR and PGPB

Plant growth-promoting Rhizobacteria (PGPR) is a community of soil bactereasingia, one group of which is plant growth-promoting bacteria (PGPB) [82]. All PGPR/PGPB inoculants are culytured bacteria. One of the most important role in EU regfeatures of inoculant production is proper fermentation to produce a large population of bacteria that are later formed into a product [2583]. In the past, a futurespecific species or strain was used in PGPR/PGPB research, and this is still true in many experimental and commercial applications of Azospirillum spp. and Bacillus spp.-based products. In laboratory use, analytical solution must ingredients are used for small-scale fermentation studies, and industrial manufacturers of products use fewer purified ingredients to save costs [84]. Plant growth-promoting bacte ria (PGPB) affect plant cell processes in various ways [85]. Previous analyses of PGPBs combined with theveloped to r restoration of heavy metal contamination in the soil have been performed on a few agricultural and horticultural crops [86]. Popular bacteria useduce as biostimulants include species such as Arthrobacter spp., Acinetobacter spp., Enterobacter spp., Ochrobactrum spp., Pseudomonas spp., Rhodococcus spp., and Bacillus spp. [87]. PGPB relieves salinity stress in plants by providing nutrients, maintaining he use oigh potassium and sodium ratios, increasing osmolite accumulation, enhancing photosynthesis and antioxidant enzyme activity [88]. In the case of maize, the applichemicalation of PGPB through the soil increased the yield and the dry matter content of the seed by 92%. The results suggest that the use of PGPB as a new cultivation practice may contribute to the sustainable growth, productivity, and quality of cereals [87] and processed tomatoes [89]. In ornamental plant cultivation (Handroanthus impetiginosus (Mart. ex DC.)), Rummelibacillus strains function as PGPBs, which also have good salt tolerance [90]. PGPBs also in acrease the efficiency of the cultivation of orchids such as Cattleya guttata and Zygpopetalum Mackayi [91]. It can also play a significanternat role in the cultivation of the annual ornamental Petunia × hybrida [92] because it promotes plant deve for farmeelopment and flowering parameters [2693]. PGPRs Unlikare also very common in ornamental plant production, such as in the cultivation of Ranunculus asiaticus L. [94]. In the case of Ocimum basilicum L., also used conventionas an annual ornamental PGPRs, also affect morphological parameters and essential oil content [95] and may also pl feay a role in the cultivation of annual ornamental Osteospermum hybrida [96]. These rhizobactilizers or peria also improve the morphological properties of spring bulbous ornamental plants [97]. They alsto increase the tolerance of Camellia japonica to salt stress, which ides, biosts also used as an ornamental evergreen shrub, thus greatly reducing cultivation costs [98]. They increase the tendency of root formulantation in individuals of the ornamental foliage plant Ficus benjamina L. [99]. They may also play are uniqu role in the reproduction of rare and endangered species such as Chlorophytum borivilianum [100]. PGPRs also enhance in that a the color intensity of the upper leaves of ornamental flowering pot plants like Euphorbia pulcherrima Willd., which is ingts main decorative value [101].

2.5. Fungal Inoculants

Selected substance can affect cropmicrobial strains used as active ingredients in biopesticides in agricultural management practices (e.g., IPM, Integrated Pest Management) are known for their ability to defend against phytopathogens, promote plant growth and dev, and/or induce disease resistance [102]Trichoderma has belcopment in multime important as a microbial plant biostimulant in horticulture [103]. The species of the genus Trichoderma are also use ways based on botd in various industries, mainly in the production of enzymes, antibiotics, and other metabolites, but also in the production of biofuels. Currently, Trichoderma has entered timing and location of applicationhe genomic era, and some of the genomic sequences are publicly available, meaning they can be used for human use to an even greater extent than before. However, further studies are needed to increase the efficiency and safety of the use of these fungi [27104]. The Trichoderma biostimulants enhance plant nutr pition, growth, and stress response. Moreover, Trichoderma-induced changes in gene expression are an integral part of physioltostimulation. Recent proteomic and genetic data suggest that Trichoderma activates mitogen-activated protein kinase 6, transcription factors, and DNA processingical effe proteins, which are promising targets for more efficient products [105]Trichoderma-based biostimulants used in Lactuca sativa L. and Eruca sativa L. increased yields [106]Passiflora caerulea L., which is also ur after entry into plased as an ornamental plant, developed larger leaves as a result of treatment, and the chlorophyll content of the leaves was also higher [107]. In t tissuhe cultivation of annual ornamentals such as Callistephus chinensis (L.) NeesSalvia splendens Sellow ex Roemer and ceJA Schultes, Zinnia elegans Jacq., and Tagetes patula, it was also successful [108]. In woody evergreen ornamental plants, wit is also a suitable biostimulant, such as for Olea europea L., also used as an ore they arnamental tree, as it enhances abiotic stress tolerance [109].

3. Abiotic and Biotic Stress and the Response of Ornamental Plants to Biostimulant Treatment

Global climate chanvolved in plant ge and the associated unfavorable abiotic stress conditions such as drought, salinity, heavy metals, and extreme temperatures greatly affect plant growth and development. This also indirectly influences crop yield and crop quality as well as the sustainability of agriculture [110]. Plants have to cope with various environmentabolisl pressures throughout their lives [111]. Under the current scenario of rapidly changing climate change, signal transduction, and hormonal rcrops are more often exposed to the stress of abiotic and biotic origins. They are more affected by unpredictable and extreme climatic events that cause and exacerbate changes in the growing season, plant physiology, and plant health hazards [112]. Global climate changulation of growth and developmente may lead to complex combinations of different stressors, of which the interaction between the pathogens and drought stress can have a significant impact on growth and yield [28113]. Biostimulants have also cbeen proposed as an agronomic tool to counteract abiotic stress [114]. Plants be used to imprare unable to move and must endure abiotic stressors such as drought, salinity, and extreme temperatures [115][116]. Plants have develovped mechanisms that sense these environmental and economic suchallenges, transmit stress signals within cells and between cells and tissues, and make appropriate modifications to their developmental mechanisms for survival and proliferation [117]. Various phytainability oohormones are known to play a protective role in plants exposed to environmental stress, and their synthesis and accumulation are increasingly regulated under environmental stress [115]. One of the main goals of horticultural sectcultivation is to reduce these stress effects.
Recent studies have shown that plants r with environmentally friendespond to abiotic stresses within seconds, engaging in a number of different metabolic and molecular networks, and altering their stoma opening in a short period of time [118]. Abiotic stress leads to altered biosy biostimulnthetic capacity and nutrient uptake, which can inhibit plant growth. This phenomenon is also documented in a number of studies on model plants. They provide assistance in cConsequently, research to understand responses to abiotic stress has come to the fore in the last decade and has led to the discovery of a number of signaling pathways that contain large numbers of genes, proteins, and post-translational modifications [119]. Abiotic stress affects the phytop produhormonal balance of plants, which has a direct effect on stress adaptation mechanisms such as stoma closure and carbon distribution [27]. As a result of their research, Nemhauser et al. [120] explain that the cron, increasinsstalk between different hormonal signaling processes is significant. The effects of abscisic acid, gibberellin, auxin, ethylene, cytokinin, brassinosteroid, and jasmine on Arabidopsis seedlings were studied. Hepler [121] concluded that Ca2+ is a crucial regulativation potor for the growth and development in plants, with research on the subject since the 1960s. To this day, new experiments are being initiated to suggest that Ca2+ is a secontial and tolerance to adary messenger in plant cell development. One of the more modern ways to do this is to use natural plant biostimulants to improve the resistance of plants to an abiotic environmental stress [153]. PlMant y active compounds found in biostimulants are generallythat support plant stress tolerance and productivity under adverse growth conditions are metabolites or intermediates that can affect nutritional quality [111].
The use of biostimulapplied to hignts may be a promising strategy to reduce the adverse effects of osmotic stress [122]. Th-ve alue plants, mainly grccumulation of reactive oxygen species is toxic to cells and leads to cell damage, resulting in a reduced germination and seedling growth [123]. Biostimulants are known to inducenhouse plants, fruit trees, the ROS detoxifying enzyme system and induce/contain non-enzymatic antioxidant compounds that promote ROS detoxification and prevent their accumulation in germinating seeds at the cellular and subcellular levels [124]. Bioutdoor vegetables,stimulants of microbial origin also have a role to play in overcoming biotic stress [125]. fMicrobialowers, and other o biostimulants can promote the growth of ornamentals, plants (e.g., Zinnia elegans and Petunia × hybrida [126][127] during productoion [128] and improve yield performancree under abiotic stress [129]. Water se yieltress can also have a negative impact on photosynthetic parameters and plant health in the long run [130]. Plants that are unable to maintain their health and quand lity under stressful conditions become unmarketable at retail [131]. The use of stimulatory bacteria in ornamental production quality in a sustainable mannmay be suitable to increase plant stress tolerance in water-scarce conditions. Recent research has shown that the use of plant growth-promoting bacteria increases the size and flowering of plants during greenhouse cultivation under abiotic stress [29132] also hybrids [131].
The Mbeneficiany horticultural cl effect of PGPB in reducing the susceptibility of plants to pathogenic infections occurs not only through microbial antagonism but also through a mechanism that enhances the defenses of plants, the so-called “induced systemic resistance” (ISR) [133].
The use of biostimpanies are investing iulants also induces a number of plant responses, including increased tolerance to abiotic stress, nutrient utilization efficiency, and organ growth and morphogenesis [134]. Experiments the development of new biostimulant prodon the biotic and abiotic stress have shown the beneficial effects of biostimulants. One of the first responses observed in plants exposed to salt stress is a decrease in shoot length, shoot and root weight, and chlorophyll content. The accumulation of proline was affected by the concentration of NaCl, while polyphenols were not affected by the increase in salinity. However, with the use of microalgae, no harmful increase in these parameters was observed with NaCl [135][136]. In Arabidopsis thaliana plants, the use of seaweed extracts and the developmen was also effective in cold stress. The treated plants regenerated more rapidly, showed greater membrane integrity, and suffered 70% less chlorophyll damage after freezing [137]Ascophyllum nodosum, as a seaweed extract, increased the of fresh and dry weight of spinach (Spinacia oleracea L.) in plants under droughe mot stress, with some detrimental effects on nutritional value [138]. The seaweed extract eapplied to lettuce (Lactuca sativa L.) seedlings increased cotyledon growth [139]. Although some commercial Ascophyllum nodosum extracts have been effective in enhancing plant growth under abioatic stress conditions, they may be less effective molecules capable of eliciting sunder biotic or stress-free conditions, and vice versa. The salt stress can be manipulated using panchagavya and positively regulates the physiological, biochemical, and gene expression responses in salt-sensitive and tolerant rice cultivars. Autophagy and programmed cell death, along with salinity, were regulated and helped to adapt to tolerance to stressful situations [140]. Another important abiotic strecific plss factor is drought. The accumulation of osmotic compounds such as proline is one of the most common plant responses too drought stress [141]. The drought-tolerabiotic stressent plants show different adaptation mechanisms to overcome drought stress, including morphological, physiological, and biochemical modifications. These responses include increasing the root/shoot ratio, reducing growth, changing leaf anatomy, and reducing leaf size and total leaf area to limit water loss and guarantee photosynthesis [30142]. MAnother example of the beneficial effect of a biostimulant was odbserved in Petunia spp., Viola tricolor, and Cosmos spp., which had bettern agric performance when grown under water-scarce conditions using extracts of Ascophyllum nodosum [143]. Hydrolysates solublture e in bio-waste also increased the rate of Hibiscus spp. photosynthetic activity and gas payexchange when exposed to water scarcity [144]. According to some researchers, the posincreasing attention to more susttive effects of different biostimulants include the following: greater biomass accumulation, increased flowering, and finally, the production of growth-stimulating hormones such as gibberellins and cytokines [3]. Fluctuatinable, organic farmg water availability is also an abiotic stress for plants. The application of some bacteria increased the plant size in both Petunia hybrida and Pelargonium × hortorum cultivars and ingcreased the flower systems. Their positive effects on horticnumbers after recovery from water stress compared to control water-stressed plants. In addition, the use of bacteria increased the fluorescence parameters of chlorophyll, including the quantum yield and efficiency of photosystem II (PSII) and the rate of electron transport (ETR), while reducing the rate of electrolyte leakage during water application and regeneration [145]. The use of biostimultural cultivation are ants is a novel and eco-sustainable agricultural practice that can not only improve the water use efficiency of sensitive and tolerant ornamentals but also provide high yields with inadequate irrigation [146].
The effect of biostimulainly due to nts on physiological, anatomical, and genetic changes in plants is closely related to the role of biostimulants in the regulation of stress response.
Metabolomioactive compoundcs, a multidisciplinary ‘omics’ science, offers unique opportunities to predictively decode the mode of action of biostimulants on crops and to identify markers that transcribe the effects of biostimulants [147].
Significant progress has been mote plant growth,ade in recent years on many fronts of stress signaling research, particularly in understanding downstream signaling events. These have culminated in the activation of genes responsive to stress and nutrient restriction, cell homeostasis, and growth adaptation [117]. The recent advances in undersuch as phytohormones, amintanding the molecular mechanisms underlying plant responses to abiotic stress emphasize the multilevel nature of plants; several processes are involved, including sensing, signaling, transcription, transcript processing, translation, and post-translational protein modifications [116]. Recent studies have shown acids, and nutrientsthat many epigenetic factors are involved in abiotic stress responses and various modifications of chromatin change when plants are exposed to a stressful environment [9148][31][32]. Redgucing the demand forlating bioactive compounds and metabolites (by modifying gene expression, signaling, and synthetic pathways) in plants and/or symbionts may promote plant–symbion association and performance [149]. Among the upregulated gend/or inces, the expression of Bv_PHT2; 1 and Bv_GLN1 induced a twofold change in Leonardite-based biostimulants [150]. The protein hydrolyzate biostimulant treatment hasing the efficiency of chemicals used in agriculture altered the expression and amounts of several genes and proteins involved in redox homeostasis, stress response, glycolysis, the tricarboxylic acid cycle, the pentose phosphate pathway, and the metabolic pathways of carbohydrates, amino acids, and lipids. Furthermore, the metabolic processes of phytohormones and secondary metabolites, especially phenylpropanoids, flavonoids, and terpenoids, as well as mechanisms involved in transport and cytoskeletal rearrangement, have been stimulated. The treatment of rice plants with a seaweed biostimulant induces resistance to Magnaporthe oryzae infection, pos crucsibly by inducing defense-related genes and enzymes, as transcript levels of various defense genes such as OsPR-1 and PAL-6 are altered [151]. In the plants of Solanum lycopersicum L., tannin-bal due to climate changsed biostimulants upregulated 285 genes, most of which were correlated with root development and salt stress tolerance. The 171 downregulated genes were mainly involved in nutrient uptake [33152]. For Biostimulantsexample, the use of peptone can have a positive effect on the hormonal balance and antioxidant system of water-stressed plants in an economically important species [153]. Investigation of natural origin can play an important role in this respegene expression may provide evidence for regulatory mechanisms of seed germination and biochemical processes regulated by biostimulants. The biostimulant seed treatments can induce changes in gene expression and modulate metabolic fluxes, allowing better seed germination and dynamic seedling growth. The application of biostimulants to seeds has been reported to regulate hormone biosynthetic genes, improving seed germination and seedling growth. Some studies have shown that the biostimulant seed treatment may regulate metabolic or stress-responsive genes [122] and may also affect leaf tissue structure [154].
Biostimulants have, in as they inmany cases and cultures, also promoted the efficiency of photosynthesis and increase yieldd the amount of chlorophyll. In Chrysanthemum sp., in a sustainable way and at a relatively low costddition to morphological parameters (stem diameter, fresh weight of shoots and roots, dry weight of shoots and roots, leaf area, flower diameter), net photosynthesis rate, chlorophyll fluorescence, and chrysanthemum chloroplast structure were affected by humic acid compared to nitrogen-phosphorus-potassium fertilizer [155]. WThen placing EU-mark translocation of assimilates was also intensified under the effect of auxin-containing microalgae-derived biostimulant s in Pelargonium peltatum [156]. Humic acids can also products on the sitively influence oxidative stress-related processes as well as increase the intensity of gas exchange [157], mediarkette metabolic processes in the plant [158], and also imaprove the morphological characteristics of root growth [159]. In Azalea × kurume plants, humic acid affected the induction of roots during in vitro culture [52]. In the case of Anthirrinum majus L., the use of a biostimulant of animal origin also had a positive effectu on leaf gas exchange parers must ensure that they have been ameters. The biostimulant significantly affected photosynthesis, the rate of evaporation, the conduction of the stoma, and the use of arbuscular mycorrhizal fungi increased the water stress tolerance in the plant [160].
The anatomicanl structure of the rooting of Rosa ‘Hufrdactured in accordancel’ cuttings was influenced by plant-derived biostimulants. As a result of the microalgae extract, the xylem cells thickened, which promoted stem strength, and the plants treated with the following microalgae extract reached the highest rooting value [161]. Under thequire influence of plant-derived biostimulants, the phloem tissues of roses also thicken [162].

4. Effects and Application of Biostimulants in Ornamental Horticulture

Ornamental plant products set out in the European Commission Regulation (2016)ion is one of the fastest-growing areas in the horticultural sector. It is one of the most dynamic agricultural sectors, especially in the cultivation of potted ornamental plants, which is showing an increasing trend on the international market worldwide [6163]:. they must draw up the technical documentation and carry outIt is characterized by constant renewal, new species, colors and uses, technologies and varieties that appear and disappear in quick succession. Following the 2008 global economic crisis, ornamental crop production has become a sector with difficulties in the recovery. Today, however, it is playing an increasingly important role. Ornamental plants are also having an increasing role in urban environments, such as in the purification of airborne pollutants [164]. In recent years, he appropriowever, the world is going through far-reaching processes. World ornamental plant exports already reached USD 9.4 billion in 2014 [165]. The ornamente conformity assessal plant trade has become a leading sector in previously uncharacteristic countries such as Brazil [166] and Thailand [165]. The development pof the sectorocedure goes hand in hand with the economic development of developing countries [167].

2. The Role of Biostimulants in Ornamental Plant Production

4.1. The Role of Biostimulants in Ornamental Plant Production

There is a growing interest in plant biostimulants, driven by the growing interest of growers in natural materials and beneficial microorganisms that can sustainably increase the productivity of vegetables and ornamentals. The protein hydrolysates and arbuscular mycorrhizal fungi are widely used in greenhouse plant cultivation, mainly due to their improving effects on plant nutrient uptake, growth, yield, and fruit quality, as well as the tolerance of plants to abiotic stressors [34168]. Disease treatment with biostimulants has received attention for their natural origin, efficacy, and low or non-existent toxicity [35169]. The excellent aesthetic quality of the product and the timing of the harvest are essential for ornamental market competitiveness. Therefore, ornamental horticultural products require a high level of investment in agrochemicals and energy use without a holistic approach and sustainability [1]. By using biostimulants alone or in combination, a significant growth rate and yield can be achieved in ornamentals in solid media. However, biostimulants should be used with caution as an overdose may have adverse effects [36170]. This is especially true for humic acids [37171]. Wild species such as  Hypericum  sp. can also be successfully produced using biostimulants [38172], as can endangered species such as  Comanthera mucugensis  native to Brazil [39173]. Not only is the biostimulant of great importance to wild plant species, but it is also becoming increasingly important to cultivated varieties. The ornamental plants sown from seed are particularly important [40174][41175][42176][43177][44178], such as  Gladiolus grandiflorus  L. [4524][46179][47180][48181]. The cultivation of orchids produced by micropropagation was also greatly facilitated by the use of biostimulants [49182].
Biostimulants can also play a major role in breeding. It has been shown that the use of biostimulants in plant breeding can alter the activity of enzymes and affect their antioxidant properties. The lycopene, ascorbic acid, and phenolic compounds have antioxidant properties. Reactive oxygen molecules such as OH, O2, and H2O2  are inactivated by antioxidant compounds (e.g., phenols, ascorbic acid) and enzymes (e.g., catalase, peroxidase, superoxide dismutase) [50183]. H2O2  generated by chloroplasts acts as a retrograde signal that enters the nucleus directly from the chloroplast, avoiding the cytosol and eliciting a transcriptional response [51184]. The biosynthetic pathway of phenylpropanoid is activated under abiotic stress conditions (drought, heavy metals, salinity, high/low temperature, and ultraviolet radiation), resulting in the accumulation of various phenolic compounds capable of binding harmful reactive oxygen species, among others [52185]. Nutrient restriction or exposure to abiotic stress can limit growth and lead to excessive excitation of the photosynthetic electron transport chain and the formation of potentially harmful oxygen forms. The timely detection of stress leads to modulation of plant growth and activation of defense and acclimatization pathways. They act either on certain plant organs or the whole plant [53119]. The effects of stress are usually associated with certain physiological mechanisms of stressed growth, such as the synthesis of protective plant biochemicals in response to stress. Many of these, which are generated during plant primary or secondary metabolism, function as functional compounds not only in plants but also in other organisms [54111].

3. The Role of Biostimulants in the Propagation of Ornamental Plants

4.2. The Role of Biostimulants in the Propagation of Ornamental Plants

Vegetative propagation is still an important propagation method in horticulture [55186][56187], and this propagation method makes horticulture even more efficient [57188]. However, biostimulants are effective tools for optimizing the propagation efficiency of vegetative cuttings; however, their optimal application rates are often species-specific [58189] and also depend on the location of cuttings on the shoot [59190]. While many significant advances have been made in vegetative propagation, the economic loss due to the insufficient rooting efficiency remains a burden for the propagation industry, and further work is needed to identify biostimulants that promote rooting [60191]. There are species, such as  Abies gracilis  Kom., whose vegetative propagation does not occur without biostimulants [61192]. Willow bark extract reduces the time required for additional root and shoot formation in chrysanthemum and lavender [58189], so it is recommended for semi-woody and woody plants, as a similar effect can be achieved with hormone-containing  Aloe vera  extract in plant groups [58189][62193]. In the case of  Cornus alba  L., biostimulants also increased the rooting rate in cuttings [56187]. In the case of  Rosa gallica  ‘Tuscany Superb’, it has been shown that biostimulants can replace indole-3-butyric acid hormone preparations during the rooting of cuttings [63194]. The humic acids can enhance the rooting of cuttings [23157]. The reduction of the chlorophyll content in leaves was not inhibited by microalgae preparations [64195].
Biostimulants are also important in sexual propagation. Relieving environmental stress on seed germination and early seedling growth is also an important goal for seed biologists. Some biostimulants may also protect seeds by enhancing the antioxidant compounds such as vitamin C and thiol, both of which are involved in stress tolerance instead of regulating enzymatic antioxidants [65122]. Biostimulants show biotic stress tolerance, so the potential and precise mechanism of action of biostimulants in seed germination and plant growth in relieving biotic stress must be recognized [66196].  Ascophyllum nodosum  algae extract promotes the growth and development of seedlings of  Helianthus annuus  L., also used as an annual ornamental bedding plant, and reduces seedling production costs [67197]. Certain seaweed extracts, humic substances, and microbial inoculants play a role in the hormonal metabolism stage, increasing the germination rate [68198].  Ascophyllum nodosum  brown seaweed and seaweed-derived products are widely used as nutrient supplements, biofertilizers, and biostimulants in horticultural plant systems, thus also increasing germination capacity in plants of  Tagetes erecta  L. [42176]. In the case of  Lavandula angustifolia  Mill., seed germination is lengthy and difficult, but the use of biostimulants can also increase the germination percentage and germination vigor [69199]. Biostimulants for rooting are also effective in  Bellis perennis  L. and  Viola × wittrockiana  Gams, but the use of biostimulants with fungicides for germination would further increase the efficiency [70200]. In  Inula viscosa  individuals, algae preparations reduced  Sphaerotheca pannosa  var.  rosae  infection [7197]. In  Tagetes erecta  L., the germination capacity of the seeds was increased by the applied biostimulant [40174] and the height of the seedlings was also increased [28201]. For  Tagetes patula  L. and  Callistephus chinensis  L., several biostimulants reduced germination and increased it for  Viola  ×  wittrockiana  [70200]. The use of  Ascophyllum nodosum  also makes germination and seedling cultivation more efficient [67197], especially in the case of ornamental peppers (Capsicum annuum  L.).
Biostimulants also play an important role in the production and propagation of bulbous plants. Soaking  Eucomis bicolor  Baker bulbs in the chitosan solution before planting stimulated the growth, flowering, and yield of the bulbs. The use of chitosan in appropriate concentrations had a positive effect on the number of leaves per plant, the relative chlorophyll content of the leaves, and the number of bulbs per plant. Chitosan is multidirectional, positively affects plant growth, and can be used as a potential biostimulant [72202]. In addition to chitosan, phenolic compounds isolated from seaweed  Ecklonia maxima  also increased bulb size and active surface area in individuals of the species [73203]. Chitosan is also a very effective group of biostimulants in micropropagated orchid cultivation, as it has promising biocompatibility and biodegradability characteristics and offers a holistic biostimulating alternative in the commercial propagation of orchids [49182]. In the orchid  Cattleya maxima  Lindl., it also has a positive effect on development when used in combination with coconut water [74204]. Microbial substances are also effective in  Cymbidium  sp. Sw. orchid micropropagation [75205]. Significant results have also been obtained in the flower, seed, and bulb propagation of  Crocus sativus  L. using biostimulants [76206].

4. Effect of Biostimulants on Plant Growth and Development

4.3. Effect of Biostimulants on Plant Growth and Development

In the case of early-grown annual ornamental plants (Begonia semperflorens  Link. Et Otto), biostimulants promote plant growth at the initial low temperature of cultivation. In woody plants, such as  Rosa  sp., in the case of micro-propagation and cuttings, the rooting of plants can also be promoted [41175]; thus, using biostimulants to make rose cuttings environmentally friendly [77207]. In the case of annual ornamental seedlings, the weight of the above-ground parts can also be increased by using biostimulants [40174][78208], so when planting seedlings of  Tagetes patula  L. outdoors, regarding growth and development [43177], Dudaš and Šestan [44178] did not observe a significant change in the seedlings compared to the untreated groups, but with microalgae preparations, the leaves of the plants did not fall off [79209]. In the case of  Portulaca grandiflora  L., the germination percentage was also significantly improved due to the use of microalgae biostimulants [80210]. The fermented protein-free alfalfa biostimulant also increases the vegetative weight of plants and influences tissue structure and chlorophyll content in the cultivation of annual ornamental plants [81211][82212][83213]. Humic acids also promote faster seedling growth in  Salvia splendens  L. [84214]. Supplementation of humic acids with organic and fertilizer increased plant height and flower yield of  Polianthes tuberosa  L. [85215] and  Dendrobium nobile  Lindl. [86216]. Spraying and watering with biostimulants has intensified vegetative growth [87217]. Chitosan increased the average number of roots and induced random root induction; however, root elongation was reduced in the presence of chitosan during in vitro propagation of  Ipomoea purpurea  (L.) Roth. The root elongation inhibitory effect of chitosan becomes clearer in the presence of an oligomeric mixture. The use of chitosan oligomers instead of polymers may be an environmentally friendly and efficient alternative to synthetic cytokinins in horticultural cultivation [8837]. In ornamental plant cultivation, the flower is one of the main ornamental values [89218]. In the case of  Gerbera jamesonii  L., seaweed extract increased the number of inflorescences and also had a beneficial effect on growth [90219]. The depolymerized gellan also increased flowering and brought earlier flowering in greenhouse cultivation for  Rudbeckia hirta  L. and  Salvia splendens  L. and can therefore be considered an innovative biostimulant [91220]. The use of protein hydrolysates as biostimulants as a leaf spray has helped to achieve extra quality plants and this practice can be used to grow petunias commercially under sustainable greenhouse conditions [92221], as well as in  Anthirrinum majus  L. [93222], which is a major cut flower in the ornamental plant trade [94160]. Ornamental grasses have created a dynamic sector of floriculture where a wide range of new varieties is introduced each year. Market competition forces producers to follow procedures from the outset that guarantee the acquisition of the best quality product [95223]. One of the unique directions of ornamental plant testing is green area management. Thanks to the success of biostimulants in fruit and vegetable production, the industry also places great emphasis on turfgrass varieties. There are significant business opportunities in this sector due to the area and pesticide reduction regulations. In ornamental grasses (Lolium perenne  L.), biostimulants have been shown to displace the effects of fertilizers [96224]. Most biostimulants increase the content of photosynthetic pigments (chlorophyll and carotenoids) and decrease the content of polyphenols and antioxidant radicals [97225].
Due to the growing role of biostimulants in the horticultural sector, their effect when combined with fertilizers is also of interest. In  Salvia hispanica  L., the application of biostimulants and the recommended fertilizer doses also resulted in significantly higher essential oil content and vegetative yield than the application of fertilizer alone [98226]. These results may be of interest to growers who want to improve the quality of their ornamental plants by using products that are easy to handle and environmentally friendly [80210].

5. Post-Harvest Treatment of Ornamental Plants with the Use of Biostimulants

4.4. Post-Harvest Treatment of Ornamental Plants with the Use of Biostimulants

The marketability of ornamental plants is based on their important visual properties such as growth, habit, longevity, and quality, the latter being influenced by parameters such as the number of flowers and buds, flower size and color, leaf color and shape, and absence of pests and pathogens [99227]. In ornamental crop production, harvesting can be very diverse, and most operations are variety-specific.  Gladiolus  sp. L. is still one of the most popular ornamental cut bulbs worldwide. However, in the case of cultivation as a cut flower, the length of vase life after harvest is a big problem [100228]. In the case of  Gladiolus grandiflorus  L. bulb cultivation, the bulb yield from the humic acid-treated stock was the highest [46179] and the number of flowers harvested per unit area was also, so humic acid is a suitable biostimulant in gladiolus production [47180][48181].  Moringa  leaf extract is also very beneficial as its use has increased physiological properties and vase life [101229]. In  Chrysanthemum  cv. Ratlam Selection, the vase life of plants was also significantly increased by banana extracts used as biostimulants, and humic acid preparations increased the number of inflorescences [102230], as described for  Polianthes tuberosa  cv. Prajwal [103231] and  Gerbera jamesonii  Hook [104232] as well as  Lilium orientale  [10547]. In addition to the cultivation of cut flowers, the production of plants is also of great importance, where the role of biostimulants is also increasing. In Hemerocallis spp. and Hosta spp., the number of vegetative propagules has also been increased during cultivation with seaweed abstracts compared to retardants [106233]. In the cultivation of Calathea insignis, humic acid can be used in combination with biochar to replace peat [10547]. In addition to Calathea, in Gladiolus grandifloras, another very popular species, it is very effective in improving morphological properties (flower number, flower size, flower diameter), but it is worth combining it with PGPB [4524]. Biostimulants are also used in many crops in the cultivation of annual and biennial ornamental plants. By adding rhizobacteria that stimulate plant growth to the medium of  Petunia  ×  hybrida,  Impatiens walleriana, and  Viola  ×  wittrockiana, the plant size increased and thus they became more commercially suitable. In addition, nutrient uptake and tissue nutrient concentrations also increased [107234]. In the case of  Tagetes erecta  L., biostimulants of microbial origin (Azotobacter, Azospirillum,  PSB) also increased the plant height, number of branches per plant, average flower weight, number of flowers per plant, flower yield per plant (g), and flower yield per hectare (t).
This entry is adapted from 10.3390/agronomy12051043

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