Post-harvest treatment based on the exposure of peach fruits to the temperature change can be categorized as refrigeration (i.e., cooling and/or storage at low temperature) or heating (i.e., thermal processing at high temperature).
Cooling and/or cold storage is one of the simplest methods for extending the shelf life of fruits with minimal quality change through inhibitory effects on not only the enzymatic activities related to the maturation but also microbial infectious metabolism [
94,
95,
96]. Since fruit rot and microbial growth are mainly caused by the degree and mode of temperature fluctuation, previous research focused on the discovery of determinant factors (e.g., the condition of raw materials, storage temperature and time) for maintaining fruit quality and novel operational methods of temperature control (e.g., hydrocooling). Ceccarelli et al. [
75] explored the influence of fruit maturity categorized as I
AD (index of maturity defined as a measure of flesh and skin chlorophyll content) and the period of refrigeration on the quality factor and aromatic characteristics of peaches; although chilling injury occurred when fruits were stored for over 4 weeks, the relationship between harvest maturity stages (immature, mature, and ripe) and storage time could be estimated to determine the time required for desirable quality changes during storage (e.g., aroma development, and ripening). In the case of the operational method of cooling, the impact of the decrease in respiration rate and the related decrease in carotenoid content by hydrocooling (i.e., dipping of fruits in H
2O at low temperature; 1 °C for 1 h) on storability was evaluated through research by Caprioli et al. [
76], and the results of their comparative analysis confirmed the remarkable efficacy of hydrocooling with various types of gas treatment (1-methylcyclopropene (1-MCP), carbon dioxide, and nitrogen).
To apply thermal post-harvest technologies to peach fruit, hot air and hot water treatments have been adopted as applicable methods operated by air circulation and dipping in solution, respectively. Both hot air and hot water treatments can contribute to not only the improvement of fruit quality (e.g., firmness, ripening, and decay) but also the prevention of chilling injury during cold storage by inhibiting the loss of membrane integrity and the accumulation of ROS [
97,
98,
99]. However, when tested on the same peach fruit samples, the comparison of hot air and hot water as post-harvest treatment technologies demonstrated that hot water had a higher efficacy than hot air. Huan et al. [
77] showed the differences between the heat transfer methods (hot water and hot air) in regard to the efficacy against chilling injury (higher efficiency on the heat transmission of hot water treatment, which is useful for the inhibition of internal browning compared to hot air treatment) and antioxidant activity (enhancement of AsA-GSH metabolisms by hot water treatment, but not by hot air treatment). The effects of hot water treatment were also assessed at room temperature to understand the response of peach fruit during ripening after treatment. Zhang et al. [
78] conducted a proteomic analysis of peach fruit treated with hot water (48 °C, 10 min) followed by storage at 25 °C and showed the distinct heat-shock protein expression linked to the resistance to stress responses or self-defense capability and the activation of multiple antioxidant metabolic pathways (e.g., AsA-GSH). The intervention effect of hot water treatment as an effective decontamination technology on peach fruit artificially inoculated with fungi (e.g.,
Monilinia sp.) was also assessed at room temperature [
79] and low temperature [
80]. Liu et al. [
79] revealed the mode of action for hot water treatment against the post-harvest decay caused by brown rot fungi (
M. fructicola) during the exposure to room temperature by both direct antifungal effects (the dysfunction of mitochondria and inhibition of spore germination of
M. fructicola) and the host defense mechanism (induction of chitinase, β-1,3-glucanase, and phenylalanine ammonia lyase enzymes).
M. laxa, capable of germinating at low temperatures, was also adopted as a target fungus inactivated by hot water treatment (48 °C, 12 min) of peach fruit by Jemric et al. [
80], and a decrease in microbial deterioration could also be achieved during cold storage (0 °C, 90% RH, 20 days).
Light-based antimicrobial photoinactivation has been applied in the food industry for the maintenance of quality, especially for fresh-cut fruits and vegetables that cannot be processed with heat [
100]. The irradiation of fruits with light can also affect various physiological metabolic pathways related to growth, development, ripening, softening, stress-response, and disease tolerance [
101]. Both visible light and ultraviolet light (UV) are expected to achieve decontamination and to modulate metabolism, but UV treatment has been preferred due to the probability of inducing ripening (e.g., synthesis of ethylene) and the lower decontamination effects of visible light [
102]. The post-harvest effects of light irradiation are known to be wavelength-dependent within the area of UV (categorized as UV-A (315–400 nm), UV-B (280–315 nm), and UV-C (100–280 nm)) [
103,
104,
105]. Previous research regarding the application of UV irradiation to harvested peaches has been reported as a singular treatment of UV-B [
88] or UV-C [
87], and the combined treatment of UV-B with UV-C [
89].
Santin et al. [
88] analyzed changes in plant secondary metabolism through non-targeted fruit metabolomics after a low level of UV-B irradiation (2.3134 W/m
2, 60 min, 24 °C), and showed noteworthy metabolomic changes in most phenolics according to the storage time after treatment (e.g., the decrease and accumulation of phenolics after 24 h and 36 h storage, respectively), emphasizing the importance of time after UV-B irradiation as the key determining factor of the efficacy [
88]. The transcriptome-based investigation of the effects of UV-C (4 kJ/m
2, 30 min, 10 °C) irradiation on the control of fruit metabolism associated with softening and senescence (cell wall, antioxidant, secondary metabolism, lipid, and energy) during storage was also conducted by Kan et al. [
87] and revealed the upregulation of genes linked to defense systems with the activation of antioxidation enzymes and the downregulation of genes inducing undesirable quality deterioration (e.g., ethylene biosynthesis, oxidative stress, lipid peroxidation, and cell wall decomposition). In the case of combined treatment (UV-B + UV-C), Abdipour et al. [
89] demonstrated a relatively lower effect of UV-B than UV-C by the direct comparison of the effects of UV irradiation with different wavelengths on the storability of the same peach samples, but the combined treatment can be considered a strategy to complement the limited effects of UV-B and to increase the overall effects, improving fruit quality parameters (TSS, firmness, total phenolic compounds, TA, vitamin C content, and acidity).
4.2. Chemical Treatments
Using chemical agents that can enhance the quality and safety of fruits by controlling fruit maturation (e.g., naturally occurring compounds extracted from growing plants; putrescine, spermidine) and decontamination (e.g., bactericidal and/or fungicidal substances) has been regarded as an efficient post-harvest treatment method. Treatment strategies can be categorized as liquid (solution) and gas (vaporized materials) phases of the chemical agents according to the application methods, as shown in Table 4.
4.2.1. Spraying or Dipping Treatment Methods Using Solutions of Chemical Agents
Treatment solutions containing active chemical agents can be mainly applied to fruits by spraying or dipping. Dipping treatment enables the even exposure of fruits to chemical agents, and thus is likely to be preferable as the post-harvest treatment to fruits rather than spraying treatment.
Spraying Treatment
Citric acid spraying can enhance the stability of fruit quality factors (firmness, TA, and TSS) during room temperature storage, and the considerable reduction of decay incidence is likely due to the potential antifungal capability of citric acid [
108].
Glucose oxidase (GOx) is a natural anti-browning and antimicrobial agent that can be used as an alternative to synthetic chemicals [
109]. Batool et al. [
110] immobilized GOx by using zinc oxide nanoparticles (ZnONPs) to improve not only the stability but also the activity of the enzyme, and GOx/ZnONP bioconjugation spray resulted in the maintenance of the physiological appearance of peach fruits and a decrease in undesirable quality changes of peach fruits (e.g., firmness, and TSS). These effects occurred through the expected mechanisms as follows: (1) antioxidant (i.e., scavenging oxygen) and antimicrobial effects; and (2) formation of H
2O
2 layer to slow fruit metabolism associated with ripening and to protect the fruit from fungal contamination.
Spraying essential oils (EOs) on the surface of fruits has been adopted as the representative decontamination treatment against pathogenic and/or spoilage bacteria and fungi [
111,
112,
113]. In the case of peaches, research by Elshafie et al. [
114] on antifungal effects of the major constituents in Greek oregano (
Origanum vulgare L. ssp.
hirtum) EO revealed that thymol and carvacrol showed strong efficacy against fruit pathogenic fungi (
Monilinia spp.;
M. laxa,
M. fructigena, and
M. fructicola).
Dipping Treatment
EO is one of the most popular antifungal agents and has been generally applied directly to food products by spraying or dipping methods. Dipping peaches in EOs showed antifungal effects against fruit pathogens equivalent to those of commercial fungicide products, highlighting the value of EOs as natural antifungals that are feasible alternatives to synthetic fungicides; however, the species-dependent efficacy from each source of EOs indicates the importance of identifying the spectrum of EOs to be used [
115]. However, the peculiar fragrance of EOs and relatively high cost compared with synthetic chemical antifungals used for fruits have been regarded as the major limitations [
116,
117]. Thus, the combined treatment of EO with other antifungal agents is expected to improve the overall effects on the product quality as a countermeasure for those limitations. Rahimi et al. [
118] reported that dipping treatment with a solution of EO and chitosan considerably prevented fungal decay with desirable effects on sensory characteristics as well.
Glycine betaine (GB) can act as an osmotic adjustment substance to enhance the tolerance of fruits against cold stress factors by preventing membrane damage [
119]. Shan et al. [
120] evaluated the effects of exogenous GB treatment from the perspective of reducing the chilling injury of cold-stored peaches; their findings suggested that the key mechanism is an increase in the contents of endogenous substances involved in protective responses to cold stresses (GB, g-aminobutyric acid (GABA), and proline) through the induction of relevant enzymes (betaine aldehyde hydrogenase (BADH), glutamate decarboxylase (GAD), D 1 -pyrroline-5-carboxylate synthetase (P5CS), and ornithine d-aminotransferase (OAT)).
Exogenous melatonin treatment extends the shelf life of peach fruits through the activation of antioxidant enzymes capable of enzymatic ROS control during both room temperature [
121] and cold storage [
122]. Gao et al. [
121] reported that dipping peaches in a melatonin solution can maintain fruit quality (e.g., firmness and decay incidence) and decrease weight loss, with the key mechanism being the activation of antioxidant enzymes (SOD, POD, CAT, and APX). Research by Cao et al. [
122] also showed an increase in the activity of antioxidant enzymes (POD, SOD, and CAT) in peaches during cold storage, and suggested that antioxidant systems were activated by the upregulated transcription of genes involved in the production of not only those enzymes but also reductants (AsA and GSH), serving as the mode of action of the increased tolerance of peaches against cold stress.
Putrescine, a poly-amine substance widely used as an antiaging compound for fruit skin, can contribute to the control of post-harvest loss of the quality and nutrition of peaches by preventing chilling injuries and the breakdown of biochemical compounds (e.g., phenolic compounds, vitamin C, and organic acids), respectively [
123].
Endogenous GABA is involved in the defense system against cold stress and the effects of exogenous GABA treatment as post-harvest interventions of chilling injuries were reported as the result of the accumulation of endogenous GABA with proline linked to stress adaptation to the cold environment. Shang et al. [
124] reported those effects on peaches treated with 10 min of dipping in GABA solution; although, the effects were not concentration-dependent (i.e., 5 mM was the most effective treatment concentration rather than the highest treatment concentration in this study (10 mM)).
Salicylic acid is a phenolic compound that plays a role in the regulation of the ripening and growth of fruits. The effects of salicylic acid dipping treatment as the post-harvest intervention against the quality change of peach fruits during cold storage have also been consistently reported, with in-depth examinations indicating that the major mechanisms of these effects are both the activation of vital antioxidant enzymes (SOD, POD, and CAT) and the inhibition of the browning enzyme (PPO) [
125,
126].
CaCl
2 has been reported as one of the most common post-harvest treatment agents that can stabilize cellular membranes and delay senescence by inhibiting enzymes responsible for the deterioration of products [
127]. The dipping of peaches in 6% CaCl
2 solution for 10 min showed a delay in spoilage and various undesirable quality changes (decrease in firmness, acidity, and reduction of sugar content) accompanied by minimized PME activity to ensure the long-term storage (3 weeks under ambient temperature and 3 days under cold temperature as storage and post-storage conditions, respectively) of fruits in an edible state, which was also validated by the palatability test [
128].
The direct validation of antifungal effects has been conducted by using peaches artificially inoculated with pathogenic or spoilage fungi and a case study of the applicability test for peach fruits has been reported with the following agents: yeast saccharides (YS) and benzo-thiadiazole-7-carbothioic acid S-methyl ester (BTH) [
129,
130]. YS from the cell wall can induce the defense responses of products due to their antifungal activities (activation of chitinase and β-1,3-glucanase, which can degrade chitin and β-1,3-glucan in the cell wall of fungi, respectively) with enhanced phenolic synthesis (higher PAL and POD activities) and these activities were linked to the role of YS as a trigger for increasing endogenous nitric oxide (NO) levels of the product [
129]. However, according to research by Yu et al. [
129], optimizing the treatment conditions of dipping products in YS based on endogenous NO levels is necessary because those effects are not treatment concentration-dependent: treatment with 0.5 mg/L YS was more effective (higher NO levels and lower decay) than treatment with 0.1 or 1.0 mg/L YS. For BTH treatment, the expected mechanisms of antifungal effects against
P. expansum in the product are the production of ROS followed by the strengthening of systemic acquired resistance through the activation of host defense enzymes (e.g., PAL, PPO, and POD) [
130].
Fruit surface can be coated by dipping in the solution of nanoparticles, which are nontoxic and available for the targeted localization. Calcium nanoparticles combined with ascorbic acid (9 mM/L) suppressed the incidence of chilling injury during the cold storage of peach fruits with a stable preservation of skin color and moisture [
131]. Gad and Ibrahim [
132] suggested nano-chitosan as a coating agent, which allowed the maintenance of fruit quality (e.g., lower weight loss, a decrease of decay incidence, and higher firmness) of peaches, and showed better effects obtained from a specific treatment condition (400 ppm) than the maximum concentration tested in this study (800 ppm) to highlight the importance on the exploration of the optimal condition. Since chitosan nanoparticles are effective and eco-friendly, the enhancement of marketability and storability of peach fruits is expected [
132].
Films and coatings applied to fruits and vegetables with edible agents (e.g., gum) by dipping can protect foods from environmental stress factors (e.g., moisture migration, microbial contamination, light exposure, and oxidation), which can result in product quality changes [
133]. Peach-gum coating (i.e., dipping in 1–10% gum solution) was suggested as a novel strategy for the prevention of ageing, which can result in the softening of the products, and the mechanism of this effect was revealed by transcriptomic analysis to be the downregulation of genes related to the deterioration of product quality (e.g., ethylene synthesis and cell wall degradation) [
134].
Sequential Dipping and Spraying Treatments
The combined treatment of dipping followed by the spraying of antifungal agents can be adopted as the post-harvest sanitation strategy with durable fruit decontamination ability. The effects of the dipping treatment of near-neutral (pH = 6.3–6.5) electrolyzed oxidizing water (NEO water), which inactivates brown rot fungi (
M. fructicola) to mitigate the potential infection on the surface of peaches (i.e., reducing the incidence and severity of brown rot), was improved by the combined treatment of daily spraying of NEO water after NEO dip [
32]. The use of electrolyzed water as the post-harvest antifungal treatment has been regarded as practical and has commercial traits due to its economic feasibility (e.g., low cost of raw materials and the maintenance of electrolyzed water generators) [
135].
4.2.2. Gas Treatment of Vaporized Chemical Agents
Volatile organic compounds (VOCs) produced by microorganisms have been used for post-harvest pathogen control and Zhou et al. [
136] showed that the fumigation of benzothiazole as a VOC (from
Bacillus subtilis), which is known as an antifungal agent against
M. fructicola, can be used not only for the decontamination of pathogenic fungi but also for the activation of antioxidant enzymes.
Fumigation of NO can prevent the quality change of peaches during storage through the reduction of ethylene production and/or the improvement of antioxidant capacity supported by higher activities of antioxidant enzymes (e.g., CAT and SOD) [
137,
138,
139]. NO can also reduce the activity of LOX and 1-aminocyclopropane-1-carboxylic acid (ACC) oxidase through nitrosation to inhibit membrane lipid peroxidation and the ethylene biosynthesis pathway, respectively [
138]. Since controversial results regarding the effects of NO fumigation on product quality factors (e.g., color, TA, or TSS) were also observed, optimization of treatment conditions based on various quality factors is also required [
137,
138]. In the case of changes in the lipid composition associated with ion leakage and membrane integrity, the most desirable effects were achieved by treatment with an intermediate concentration (10 μL/L), whereas opposite effects according to the excessive exposure of peaches to fumigated NO were observed at the highest concentration (15 μL/L), highlighting the importance of determining the optimum conditions [
139]. Mechanisms for the beneficial effects of NO treatment during ripening were also revealed by proteomic analysis as follows: (1) induction of antioxidant enzymes (SOD, enzymes of the AsA-GSH cycle); (2) decrease in ethylene production by the production of complex 1-aminocyclopropane-1-carboxylic acid oxidase (ACO–NO–ACC) supported by the upregulation of S-adenosylmethionine synthetase (SAMS) to promote the generation of the precursor of ACC (S-adenosylmethionine (SAM)); (3) the reduction of ATP supply generated by substrate oxidation by the application of alternative pathways for energy production (TCA cycle and glycolysis) through the regulation of cytochrome c oxidase synthesis with electron transport and oxygen consumption; (4) suppression of the degradation of the cell wall by upregulation of proteins associated with both the loss of Ca
2+ ions and the structural components of the cell wall; and (5) the induction of defense capacity by upregulating the heat-shock protein 70 (HSP70) [
140].
Peach fruits can be exposed to volatile EOs in a gas state as the post-harvest treatment for the control of fungi responsible for the deterioration of products (e.g.,
B. cinerea and
Alternaria alternata) [
141,
142]. However, the requirement of high EO concentrations to achieve the suppression of brown rot and
Rhizopus rot limits their application in the food industry from the perspective of marketability due to relatively higher cost of EOs as natural agents compared that of conventional gaseous fumigants as synthetic chemical agents; furthermore, EOs have potential phototoxicity [
141]. Thus, the encapsulation of EOs and the combined treatment with another decontamination technology can be adopted as the countermeasure for those limitations of EO fumigation treatment [
142]. Cyclodextrin-based (CD-based) microencapsulation could protect EOs from environmental factors that decrease their stability (e.g., temperature, light, and oxygen) and the simultaneous treatment with 1-MCP could contribute to the maintenance of fruit quality (e.g., firmness, acidity, and decay incidence) through its inhibitory effects against ethylene releases.
1-MCP is an ethylene-antagonizing compound controlling endogenous and exogenous ethylene to prevent the senescence of fruits, and the ephemeral microcirculation of gaseous post-harvest agents during the storage of peach fruits showed effective preservative efficacies. Du et al. [
143] sequentially treated peach fruits fumigated with 1-MCP with ozone during cold storage (8 ppm O
3 at 0 °C for 45 days) and reported the effects on storability (reduction of the decay rate, reduction of MDA content, the maintenance of fruit quality (firmness, SSC, TA, and color)).
4.3. Biological Treatments
Fungal diseases in peach fruits are usually caused by latent infection via wounds during handling in fields, processing, and storage [
144,
145]. Antagonists are microorganisms that control pathogens by colonization on fruit surfaces or flesh exposed by the wound (i.e., competitive exclusion) and resource competition for nutrients [
146]. Moreover, previous research regarding the inoculation of antagonists on peaches also showed an increase in the activities of antioxidant enzymes (e.g., APX, CAT, PAL, POD, and SOD) as an indirect effect of post-harvest treatments [
147,
148]. Since the antagonists used on fruits have been validated as safe for consumption, there is no concern about the residue, which is not the case for the chemical treatment technologies using toxic fungicides [
149]. Major examples of antagonists reported as applicable for peach fruits are as follows:
Pichia caribbica [
147],
B. subtilis [
148],
Cryptococcus laurentii [
150], and
Aureobasidium pullulans [
151]. The function of antagonism can be diverse according to the determinant factors including region, cultivar, and environment (
Table 5).
Rapid growth on peaches can be a key characteristic of antagonists from the perspective of colonization competition. Xu et al. [
147] revealed the competitive growth of a fast-growing antagonist (
P. caribbica) against a fungal pathogen (
R. stolonifera), which can also grow rapidly in the flesh of peaches by penetration of the wound, and showed the effects of biocontrol capability by decreasing the level of fungal decay (lower disease incidence and lesion diameter) during room temperature storage.
The identification of post-harvest pathogens isolated from stone fruits and the subsequent characterization of their ability to cause decay in fresh fruit can indicate the microbial strain that should be targeted for control [
152,
153]. Zhang et al. [
148] isolated peach-decaying fungal strains (
Alternaria tenuis and
B. cinerea, which showed 100% and 92.33% disease incidence for fresh peach fruits, respectively) and revealed competitive inhibition as the antagonistic mechanism of
B. subtilis by co-culture with those pathogens on peach wounds under room temperature storage. This study also showed that ca. 7 log CFU/mL antagonist suspension achieved the highest inhibitory effects against pathogenic fungal growth compared to other concentrations (from 5 to 9 log CFU/mL), suggesting the importance of the specific concentration optimized for each type of antagonist.
Since the changes in physicochemical and/or organoleptic characteristics (e.g., odor, flavor, and color) from the results of the use of synthetic fungicides on fruits have been regarded as one of the major obstacles for the commercialization of chemical post-harvest treatment technologies, antagonists can be an alternative that does not result in quality changes after treatment [
146,
154]. Zhang et al. [
150] showed the broad spectrum of treatment concentration-dependent inhibitory effects of
C. laurentii (6–9 log CFU/mL) against fungal decay, such as gray mold (
B. cinerea), blue mold (
P. expansum), and
Rhizopus rot (
R. stolonifer) during room temperature storage (at 25 °C up to 5 days) without changes in other undesirable quality parameters.
Although most co-culture growth experiments of antagonist pathogens have been conducted at room temperature within a few days due to the limited growth range of the antagonist and short shelf life of peach fruits [
147,
148,
150], antagonists active at low temperatures are also needed for the preservation of fruits during long-term storage under refrigeration conditions.
A. pullulans is a well-known cold-tolerant antagonist that can be used to control fungi decaying the fruit during cold storage [
155,
156,
157,
158]. Zhang et al. [
151] demonstrated the antifungal effects of
A. pullulans PL 5 treatment of peach fruit in regards to the reduction of
M. laxa incidence and the diameter of decay and showed that the mechanisms were both direct (competition during the co-culture of antagonist pathogens) and indirect (activation of enzymes governing the host defense (chitinase and β-1,3-glucanase)).
4.4. Combined Treatments
Many previous studies conducted to enhance the quality of peach fruits combined multiple post-harvest technologies categorized as physical (e.g., heating and irradiation), chemical (e.g., dipping in treatment solution and spraying or fumigating solution), and biological (e.g., co-culture of antagonistic organisms) treatments. The major aim of the combination of technologies is to achieve a greater effect than the sum of individual technologies (i.e., synergistic effect) and/or to complement the limitation of each technology with perspectives on the intervention mechanism of quality changes in peaches. The findings of studies on the development of the combination method of technologies and the establishment of optimal treatment conditions highlight novel effects that were unexpected based on the results of the application of individual technologies for peach fruit post-harvest treatments. Since the combination of technologies results in antagonistic effects (i.e., a lower effect than the sum of individual technologies or the inhibition of the intended effects by the interaction among the combined technologies), the exploration of adequate treatment concentrations is also needed to avoid inefficiency. Table 6 summarizes the findings of the previous research focused on combined treatment methods applied for the post-harvest quality and safety control of peach fruits.
4.4.1. Combination of Physical and Chemical Treatment
Since there are concerns about the toxicity and environmental pollution derived from the excessive use of chemical post-harvest agents, the combination of physical treatment technologies has been attempted to reduce the treatment concentration of agents [
159,
160]. In the case of peach fruits, salicylic acid treatment combined with ultrasonication or thermal pre-treatment are representative examples [
161,
162]. Ultrasound treatment for fresh fruits and vegetables has been used to clean surfaces and to inactivate microbial contaminants with the disruption of cells; however, direct antimicrobial efficacy is likely to be insufficient to achieve a reduction in fungal decay, and thus the combination with other decontamination technology is generally needed [
163]. Yang et al. [
161] combined salicylic acid (dipping in solution (0.05 mM)) and ultrasonication at 20 °C for 10 min followed by room temperature storage (20 °C, 6 days) of peach fruits infected with blue mold (
P. expansum); all treatments (both singular and combined) did not affect the quality factors (weight loss, firmness, TSS, and vitamin C content), but the beneficial effects from the singular salicylic acid treatment (activation of enzymes governing antioxidant and host defense mechanisms and decrease of the fungal decay) were synergistically improved by the combined treatment with ultrasonication; although, individual ultrasound treatment did not influence those effects. The sequential approach of thermal pre-treatment before the application of chemical agents has also been adopted as a combined treatment strategy for post-harvest preservative processing [
164]. According to the research by Cao et al. [
162], exposure to heat (hot air at 38 °C, 12 h) prior to salicylic acid treatment (dipping in salicylic acid 1 mM at 20 °C for 5 min) is expected to induce the expression of heat-shock proteins related to fruit tolerance, and thus showed desirable effects on internal browning as an indicator of cold stress response capability, antioxidant activities, and polyamine levels during long-term cold storage (0 °C, 35 days).
Radical irradiation has been widely used for the extension of the shelf life of vegetables and fruits due to its cold nature and strong decontamination effects [
165]. Edible coating with polysaccharides can preserve the quality parameters of fruits by inhibiting fungal growth on the coated surface [
166,
167,
168]. As reported by Hussain et al. [
169], gamma irradiation (1.2 kGy) of peach fruits coated with carboxymethyl cellulose (1%) can improve the effects on the inhibition of fungal infection, the prevention of quality changes (firmness, TSS, and TA), and the delay of ripening or senescence during cold storage.
4.4.2. Combination of Physical and Biological Treatment
Although it is difficult to predict the effect of commonly used fungicide products through only physical or biological treatment, the support of antifungal biocontrol agents in combination with physical treatments (e.g., heat treatment) has achieved desirable pathogen control efficacies for fruits [
170,
171]. Biocontrol agents are generally ineffective against the micro-organisms infecting fruits prior to the application of those agents, and thus the complementation of the antifungal efficacy by support from physical treatment is needed. Microwave treatment enables the rapid heating of food products to efficiently inactivate the microbial cause of decay of fruits and vegetables [
172,
173]. Zhang et al. [
170] suggested the biocontrol strategy of the inoculation of an antagonist (
C. laurentii) into infected peach fruit (
R. stolonifera) after microwave heating (2450 MHz, 2 min) for fungal inactivation, and the persistent protective effects of the antagonist were also validated by the decrease in infected wounds on fruits without quality changes (firmness, TA, and TSS). Zhang et al. [
171] also showed that the exposure of peach fruit to heated air (37 °C, 48 h) before the application of the antagonist (
C. laurentii) also ensured its active competitive effects against fungal contaminants causing the decay of peaches (decrease in the ratio of infected wounds by 22.5% and 5% for the infectious disease caused by
P. expansum and
R. stolonifer, respectively) without remarkable differences in physicochemical characteristics of fruits (TSS, TA, and vitamin C content).
4.4.3. Combination of Chemical and Biological Treatment
Since biological control using antagonists is generally not as effective as the direct application of disinfectants from the perspective of immediate killing effects, antagonists for peaches have been combined with organic or inorganic additives (e.g., antifungal effects and/or plant growth regulators) to complement the limited effects of antagonists [
37,
174].
Zhang et al. [
174] used antagonist suspensions (
Rhodotorula glutinis; 8 log cells/mL) amended with salicylic acid (100 μg/mL) for 30 s of dipping treatment before artificial inoculation with gray mold (
Botrytis cinerea) on peaches, and showed that limited effects of individual treatment with salicylic acid or an antagonist (
R. glutinis) in reducing the lesion diameter could be significantly improved by the combined treatment without impairing the quality of wounded fruits (TSS, TA, ascorbic acid content, and firmness) [
174].
The antagonist
Bacillus spp. can protect the fruit surface by producing extracellular polysaccharides (e.g., glycocalyx) in biofilm as a physical barrier against the colonization of fungal pathogens, and this biofilm-forming ability can be supported by Eos. Arrebola et al. [
37] designed combined treatment technologies between post-harvest spraying of an antagonist on peach fruits followed by packaging with the delivery system of EOs (e.g., thymol and lemongrass oil) and showed a broad spectrum of the disease control, including gray mold (
B. cinerea), blue mold (
P. expansum), and
Rhizopus rot (
R. stolonifer). This combined treatment technology can also reduce the burden of the application concentration of EO, which is known to have a potential phytotoxic effect causing the browning of fruits and an unpleasant odor [
37,
113].
5. Conclusions
This review provides comprehensive information based on the findings from studies regarding pre- and post-harvest treatment strategies optimized for peach fruits to extend the durable intake. Since peaches are vulnerable to environmental stresses under room temperature, most relevant studies aim to ensure fruit quality during long-term cold storage. Recent research has mainly focused on the development of new technologies and the design of novel combined treatment, whereas the in-depth study of pre- and post-harvest processes previously reported as applicable for stone fruits to optimize operational conditions for peaches should also be consistently conducted due to the diversity in the efficacies of treatment methods according to various determinant factors (e.g., a cultivar of fruits, processing environments, storage temperature, and time). Major implications from the analysis of the literature can be summarized as follows: (1) the discovery of side-effects from the overuse of treatment agents (chemical and biological technologies) or severe treatment conditions (physical technology) highlights the importance of the determination of the adequate criteria for the limitation of operational conditions; (2) since the result of the combined treatment is generally unexpectable (e.g., synergistic, additive, and antagonistic effects), the establishment of strategies which can harmonize both the efficacy and efficiency should be followed; and (3) pre-harvest treatment technologies generally aim to achieve sustentative effects allowing the improvement in the stability of fruit quality during the long-term cold storage, and thus the combined (sequential) treatment with subsequent post-harvest treatment is expected to enhance overall efficacies. This focused review suggests practical information for the design of advanced pre- and post-harvest treatments for peach fruits based on insights into advantages and disadvantages of currently reported technologies. As a future perspective on the research area in peaches, the quality control system based on the technologies in the Fourth Industrial Revolution era is expected to be integrated into pre- and post-harvest treatment strategies for peach fruit by sensing the fruit quality, strict pre-harvest quality control in smart farms, and web cloud-based precise quality management during the storage and/or distribution. The sensor-based analysis of the changes in the fruit quality factor can be a promising countermeasure for undesirable antagonistic effects derived from the combined treatment of pre- and post-harvest technologies described in this study.