Next Article in Journal
The Effect of Bioclimatic Covariates on Ensemble Machine Learning Prediction of Total Soil Carbon in the Pannonian Biogeoregion
Previous Article in Journal
A Review of Plastic Film Mulching on Water, Heat, Nitrogen Balance, and Crop Growth in Farmland in China
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Agronomy
Volume 13
Issue 10
10.3390/agronomy13102517
agronomy-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Systematic Review of Technology in Aeroponics: Introducing the Technology Adoption and Integration in Sustainable Agriculture Model

by
Juan Garzón
1,*,
Luis Montes
1,
Jorge Garzón
1 and
Georgios Lampropoulos
2
1
Faculty of Engineering, Universidad Católica de Oriente, Rionegro 54040, Colombia
2
Department of Information and Electronic Engineering, International Hellenic University, 57001 Thermi, Greece
*
Author to whom correspondence should be addressed.
Agronomy 2023, 13(10), 2517; https://doi.org/10.3390/agronomy13102517
Submission received: 26 August 2023 / Revised: 23 September 2023 / Accepted: 25 September 2023 / Published: 29 September 2023
Browse Figures
Review Reports Versions Notes

Abstract

:
Aeroponics is a soilless agricultural technique that grows plants by misting their roots with a nutrient-rich solution. Technology has transformed aeroponics by providing it with benefits such as the control of environmental factors, automated nutrient delivery, and the monitoring of plant health. This paper presents a systematic review of 47 studies to identify the status and tendencies in the usage of technology in aeroponics as well as the main opportunities and challenges. Furthermore, this paper introduces the Technology Adoption and Integration in Sustainable Agriculture (TAISA) model. TAISA is a model that identifies the degree of technology integration in any sustainable agriculture system to determine how technology affects production and quality. The systematic review indicates that the most common technology in aeroponics is sensing technology and Industry 4.0. These technologies have brought multiple benefits such as sustainability and time efficiency. Conversely, the studies highlighted technical complexity and power dependency as the main challenges in technology-assisted aeroponics. Finally, the TAISA model reveals that technology has primarily been employed in creating new processes that are only possible to implement with the help of technology. Therefore, we conclude that technology use has taken root in aeroponics and can be promoted to improve sustainable agriculture.

1. Introduction

The global population is constantly increasing, which implies the need to increase food production. As food production increases, the planet’s sustainability is at risk, as a greater use of energy, water, and soil resources is required. In the same way, the overuse of land and intensive farming practices can lead to soil erosion, nutrient depletion, and a loss of soil fertility, which can reduce the productivity of the land over time [1]. To alleviate this situation, the Food and Agriculture Organization, FAO (2017) [2], proposed implementing sustainable agriculture techniques, such as aquaponics, hydroponics, and aeroponics. These are soilless-based techniques that use technology to improve food production efficiency without risking the planet’s sustainability [3,4]. Aquaponics refers to producing fish and plants using water tanks and hydroponic systems. Hydroponics refers to growing plants using a water-based nutrient solution instead of soil, and aeroponics refers to growing plants in the air or a mist environment. Aquaponics is the most popular technique when there is a need to produce fish and plants. Conversely, if there is no interest in producing fish, hydroponics is very popular if sufficient water resources are available. Finally, if there is no interest in producing fish, and the water resources are insufficient, aeroponics is the technique to implement [5].

1.1. Aeroponics

Aeroponics is a method of growing plants in a soil-free environment where the plant roots are suspended in air and are misted with a nutrient-rich water solution [6]. Aeroponic systems typically use pumps, timers, and spray nozzles to deliver a highly oxygenated mist of water and nutrients to the plant roots. The mist is delivered at timed intervals, allowing the roots to absorb nutrients and water.
Aeroponics offers several advantages over traditional soil-based agriculture, including faster growth rates, higher crop yields, and more efficient use of resources [7,8]. The soil-free environment also reduces the risk of soil-borne diseases and pests, allowing for a more sustainable and environmentally friendly approach to agriculture [9]. On the other hand, its main challenges are high initial setup costs, maintenance requirements, and a high level of technical expertise requirements [10].
Aeroponics is a relatively new technology, but it has already been successfully used to grow a wide range of crops, including lettuce, tomatoes, and strawberries [11]. One of the main advantages technology has provided to aeroponics is that plants can be grown throughout the year, as environmental conditions such as humidity, temperature, airflow, and light intensity can be artificially controlled using specific tools and systems [12,13].

1.2. Technology in Aeroponics

Technology plays a crucial role in the success of aeroponics, enabling the precise control of environmental factors, water conservation, space optimization, and pest and disease control, all of which contribute to improved food production. Additionally, by leveraging technology, aeroponics can produce high-quality, nutrient-rich crops with a reduced environmental footprint compared to traditional farming methods [8]. According to previous studies [5,13,14], technology-assisted aeroponic systems include one or more of the following groups of technologies: sensors, Industry 4.0-related technologies, dispenser-related technology, and renewable energy technologies.
One of the primary applications of technology in aeroponics is using sensors to monitor environmental conditions [15]. For example, sensors provide real-time monitoring of environmental conditions (e.g., temperature, humidity, and nutrient levels), which allows farmers to make data-driven decisions about adjusting conditions to optimize plant growth [16]. This can include adjusting nutrient levels, controlling temperature and humidity, and monitoring plant health. Moreover, sensors can be integrated with automated control systems to adjust environmental conditions to address the changing conditions [17]. This reduces the risk of human error and ensures that environmental conditions are continuously optimized for plant growth. Additionally, sensors can detect issues such as nutrient deficiencies, pests, and diseases before they become visible to the human eye [11]. This early detection can help prevent crop loss and ensure that plants are healthy and productive.
Another technological alternative that has gained relevance in aeroponics is Industry 4.0. It refers to the fourth industrial revolution, characterized by the integration of advanced technologies such as the Internet of Things (IoT), Artificial Intelligence (AI), and data analytics to create smart production processes [18]. In aeroponics, Industry 4.0 technologies are becoming increasingly important as they offer a range of benefits for optimizing plant growth and improving efficiency [11]. For example, IoT can be used to automate various tasks, such as nutrient delivery, environmental control, and pest management [19]. This reduces the need for human intervention and ensures that plants receive the optimal conditions for growth at all times. On the other hand, AI can be used to detect plant diseases early on by analyzing images of plants and identifying symptoms that may not be visible to the naked eye [20]. This can help farmers take prompt action to prevent the spread of diseases and maintain healthy crops. Similarly, data analytics can be implemented to analyze vast amounts of data on plant growth, weather patterns, and nutrient levels to accurately predict the ideal conditions for plant growth [21]. This can help farmers optimize their aeroponic systems and achieve better yields.
Dispenser-related technology is also essential to aeroponic systems, as dispensers deliver nutrients and water to plants [22]. This includes atomizers, sprayers, nebulizers, ultrasonic dispersion, water pumps, and centrifugal pumps that are automatically controlled according to the needs detected by the sensors. Dispenser technology allows for the precise dosing of nutrients and water to plants [23]. This ensures that the plants receive the optimal amount of nutrients and water, which is critical for their growth and development. Moreover, dispenser technology can be automated to deliver nutrients and water at set intervals or based on real-time sensor data [24]. This reduces the need for manual labor and ensures that the plants receive consistent care. Additionally, it allows for the customization of nutrient and water delivery based on the specific needs of each plant [25], thus ensuring that each plant receives the optimal conditions for growth and development.
Another group of technologies that make aeroponics a sustainable technique is related to renewable energy. Alternative energy sources, such as solar or wind power, can be used to power aeroponic systems, providing a range of benefits for reducing energy consumption and improving sustainability [17]. This reduces the reliance on grid power, which can be expensive and environmentally damaging. Renewable energy also helps reduce energy costs associated with running an aeroponic system [26], which makes it more affordable for growers to operate and maintain their systems. Additionally, alternative energy sources are typically cleaner and more sustainable than traditional ones [27], making them a more environmentally friendly choice for aeroponic growers.

1.3. Related Work

Some literature review studies have analyzed the uses of different technologies on the whole panorama of sustainable agriculture. For example, the study by Abbasi et al. [11] investigated the emerging trends of digital technologies in sustainable agriculture techniques. The review included 148 empirical studies to identify the extent of digital technology adoption, service type, technology readiness level, and farming type (hydroponics, aquaponics, and aeroponics). Out of the total sample, only three studies were related to aeroponics, whereby the study did not draw any conclusion on this type of sustainable agricultural technique. Similarly, the study by Fussy and Papenbrock [28] compared soil and soilless cultivation techniques (aquaponics, hydroponics, and aeroponics). The study concludes that implementing technological developments related to monitoring and automation gives the advantage to soilless techniques, making them much more profitable, well-organized, effective, secure, and nature-friendly. Finally, the study by Basso and Antle [29] investigated the affordances of digital technologies such as sensors, robotics, AI, and data analytics as key developments to secure sustainable food production. The study argues that while complex climate changes put food production at risk, digital technologies are key to controlling such changes and achieving truly sustainable agriculture. However, as well as with the other studies, this one also did not specify any conclusions about the impact of technology on aeroponics.
On the other hand, many empirical studies have reported how the use of specific technologies helps aeroponics improve food production [23,30], how aeroponics technology uses natural resources efficiently [31,32], and what specific technologies are implemented in aeroponic systems [15,33]. However, to the best of our knowledge, no systematic review has been conducted to identify the whole panorama of the use of technology in aeroponics. A systematic review of technology use in aeroponics is important because it can identify research gaps, evaluate existing evidence, provide guidance for practitioners, and I form policy and decision-making. Moreover, it can help advance technology and optimize plant growth while ensuring that researchers and policymakers have access to the best available evidence.

1.4. Purpose of the Study

Aiming to fill the literature gap, the purpose of this study is twofold. First, we conduct a systematic literature review to identify the status and tendencies in the usage of technology in aeroponics, as well as the main opportunities and challenges in the field. Second, we propose a model to identify the level of technology integration to determine how technology affects production and quality. Specifically, the study answers the following research questions:
  • What are the trends regarding the use of technology in aeroponic systems?
  • What are the main advantages that technology integration can bring to aeroponic systems compared to conventional agriculture systems?
  • What are the main challenges that technology integration can bring to aeroponic systems compared to conventional agriculture systems?
  • What has been the purpose of technology integration in aeroponics?
In the context of this study, technology integration refers to incorporating sensors, Industry 4.0-related technologies, dispenser-related technology, and renewable energy technologies, to improve the aeroponic system. To identify the trends regarding technology usage in aeroponic systems (1), we consider the type of technology implemented, the type of cultivated product, the country of the research, the publisher of the study, and the publication date. Advantages of aeroponic systems (2) refer to positive outcomes compared to conventional agriculture systems. In contrast, disadvantages (3) refer to negative outcomes encountered in aeroponic systems. Finally, to establish the purpose of technology integration in aeroponics (4), we propose a model to assess the level of technology use in a sustainable agriculture system. This model is based on the Substitution, Augmentation, Modification, and Redefinition (SAMR) model and helps identify the purpose of integrating technology into the system.

2. The Model

2.1. Theoretical Foundation

The proposed model is based on the SAMR educational framework. Initially developed by Dr. Ruben Puentedura in 2006, this model was proposed to analyze and evaluate technology integration in the classroom [34]. The primary purpose of the SAMR model is to help teachers and instructional designers understand how technology can transform teaching and learning experiences. It provides a framework for categorizing different levels of technology integration, ranging from basic substitution to more advanced redefinition. At the “substitution” level, technology is used as a direct substitute for traditional pedagogical tools without any significant functional changes. At the “augmentation” level, technology enhances the learning process by providing additional functionalities. At the “modification” level, technology allows for significantly redesigning the learning task. Finally, at the “redefinition” level, technology creates entirely new learning experiences, transforming the learning task into something previously unimaginable without technology [35]. While the SAMR model is primarily designed to analyze and evaluate the integration of technology in education, it could also be adapted to be applied in other fields.

2.2. The Proposed Model

In this study, we introduced the Technology Adoption and Integration in Sustainable Agriculture (TAISA) model. TAISA is a framework to assess and evaluate the level of technology integration in the context of sustainable agriculture. It focuses on understanding how technology is adopted and integrated into farming practices to promote sustainable and environmentally friendly approaches. It promotes innovation, efficiency, and collaboration, leading to advancements in agriculture techniques and the potential for sustainable and optimized crop production. Therefore, the TAISA model can help assess how technology is being utilized to enhance and transform the overall cultivation process.

2.2.1. Definition of the Levels of Technology Integration

The TAISA model evaluates the level of technology integration using a four-point rating scale: Limited, Basic, Moderate, and Advanced. Figure 1 summarizes the significance of each level, and subsequently, we present a general description and some specific examples.
Limited Integration: Technology plays a minimal role in sustainable agriculture practices. There is little evidence of technology being used to enhance production and sustainability efforts; instead, it replaces existing tools without any advancement in the process. Traditional farming methods are predominantly employed, with a limited adoption of innovative technologies or digital tools that promote sustainable food production. For example, when using electric water pumps for water and nutrition irrigation, the technology does not enhance the process; it only replaces manual irrigation.
Basic Integration: Technology is somewhat integrated into sustainable agriculture practices. There are instances where technology is utilized to support sustainability goals, but it is not consistently applied or fully leveraged. Some digital tools or precision farming techniques may be used to optimize resource management or monitor environmental impact, but their adoption is limited. However, there is evidence of technology improving efficiency or effectiveness in certain areas. For example, weather monitoring systems are utilized to make informed irrigation decisions in some areas but not systematically across the entire farm. In this case, technology improves the process but does not fundamentally change it.
Moderate Integration: Technology is reasonably integrated into sustainable agriculture practices and is consistently used to enhance sustainability efforts and achieve desired outcomes. Digital tools, precision farming techniques, and smart agricultural systems are employed to optimize resource use, monitor and reduce environmental impact, and promote sustainable practices. There is evidence of technology being applied effectively, resulting in improved efficiency and effectiveness. However, there are still some areas where technology could be further leveraged. For example, automated irrigation systems are employed, utilizing soil moisture sensors and weather data to optimize water use efficiency and reduce waste. In this case, technology modifies the process and enhances sustainable production.
Advanced Integration: The technology is fully integrated into sustainable agriculture practices and is effectively utilized to create new processes that maximize sustainability outcomes and minimize environmental impact. There is extensive evidence of technology enabling significant improvements in efficiency and effectiveness in sustainable agriculture. The technology is seamlessly embedded throughout the process, and its use is well-optimized. For example, by integrating cutting-edge technologies, smart farming systems can monitor and manage crops, soil conditions, water usage, and environmental factors autonomously and in real time. In this case, technology redefines processes and creates new possibilities.

2.2.2. Significance of the Model

The TAISA model is valuable for evaluating the integration level of technology in sustainable agriculture for different reasons. First, this model can be implemented to identify the extent to which technology is being applied and whether it is merely replacing existing methods or truly transforming the cultivation practices. This knowledge helps us understand the true impact of technology on farming processes; thus, if technology is only replacing existing methods without providing significant improvements, it might not be worth the investment. Second, the model helps stakeholders (e.g., researchers, growers, and engineers) understand whether they are fully leveraging the capabilities of technology or if there are untapped opportunities for enhancement. This analysis can lead to innovative ideas and advancements in the field. Third, the model encourages practitioners to move beyond basic technology uses and consider how it can fundamentally transform the cultivation process. This mindset can lead to developing groundbreaking techniques and approaches in sustainable agriculture that were not previously feasible. Fourth, technology integration in sustainable agriculture can contribute to improved efficiency and productivity in crop production. Using the TAISA model, practitioners can evaluate how technology is utilized to streamline processes, automate tasks, monitor and control environmental factors, and optimize resource utilization. This assessment helps identify areas where technology can further enhance efficiency and productivity in sustainable agriculture systems. Fifth, the TAISA model fosters a culture of innovation and collaboration within the sustainable agricultural community. By evaluating technology integration and striving for higher levels of transformation, stakeholders are encouraged to explore new ideas, share best practices, and collaborate on research and development initiatives. This can lead to technological advancements, cultivation techniques, and knowledge sharing within sustainable agriculture communities.

3. Methods

This systematic review was conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) guidelines [36] and follows recommendations outlined by Kitchenham and Charters [37]. This procedure requires that systematic reviews go through three stages, namely planning, conducting, and reporting the review.

3.1. Planning the Review

This stage entails the strategy to identify the empirical studies to answer the research questions. Journal articles and conference articles were searched in the following bibliometric databases and publishers: IEEE, MDPI, Scopus, and Web of Science (WoS). We used the following search terms: “aeroponics AND technology”, “precision aeroponics”, “smart aeroponics”, “sustainable agriculture AND aeroponics”, “smart farming AND aeroponics”, and “smart agriculture AND aeroponics”. The final search was performed on 30 June 2023, and allowed us to find 615 studies. After identifying and removing duplicate studies (212), a total of 403 studies were set to be further examined. Unpublished studies were not included because their quality assessment cannot be guaranteed in the absence of a peer review process. Two of the researchers examined each paper to determine its suitability for the study. Articles that did not meet the eligibility criteria were discarded.

Eligibility Criteria

Studies were first selected based on their title and keywords. The title and keywords of all articles were scanned to remove irrelevant studies. Fifty-eight studies were deemed irrelevant and removed; hence, this process yielded 345 studies. The abstract of each study was then read. This allowed us to remove 243 studies either because they were review articles, reports, dissertations, work-in-progress articles, or did not address the aim of our study. Thus, this process resulted in 102 articles. Next, we selected the studies that met the following conditions: (a) empirical studies, (b) studies that specify the technology used in the production process, and (c) studies that specify the cultivated product. These criteria led to a selection of 47 academic articles to be further examined and included in the analysis. The reference list of each paper was then scanned, but no additional study was found. The PRISMA flowchart of the study selection process is shown in Figure 2.

3.2. Conducting the Review

We designed a data extraction form to collect the information to address the research questions. The data form included the following information: title, year, type of technology used, cultivated product, country of the study, publisher, reported advantages, reported disadvantages, and main findings. Two of the researchers read each paper individually and extracted the information using the content analysis method to extract the data [38]. These researchers have degrees related to electronic engineering and a combined experience of more than ten years in aeroponic systems. Intercoder reliability was measured using Cohen’s Kappa statistic. This value was 0.92, which corresponds to an almost perfect agreement [39]. Disagreements were discussed and resolved through consensus among the researchers.

3.3. Reporting the Review

This stage refers to the process of documenting and presenting the findings of the review in a clear and transparent manner. This stage is crucial for ensuring the reproducibility and reliability of the review, as it allows readers to assess the rigor and credibility of the review findings. The results of this stage are presented in Section 4.

4. Results and Discussion

This section presents and discusses the systematic review results to answer the research questions. These results are based on the analysis of 47 empirical studies that focused on the uses of technology in aeroponic systems. Table 1 summarizes the information about the studies included in the review. A file with all the information about the studies can be solicited from the corresponding author of this study.

4.1. Trends in the Use of Technology in Aeroponic Systems

This section presents and discusses the results regarding the trends in technology-assisted aeroponics. To identify the trends, we evaluated (a) the technology type, (b) the cultivated product, (c) the country of the research, (d) the publisher of the study, and (e) the publication date. The results indicate that the most common technology in aeroponics is sensing technology and Industry 4.0. The most common cultivated product is vegetables. As for the country of the research, most studies were conducted in Indonesia. Similarly, IEEE published the largest number of studies. Finally, the publication date indicates a steady increase in the number of published studies from 2015 onwards.

4.1.1. Technology Type

We coded each study according to the criteria in Table 2. We selected this group of technologies because they have been identified as the most prominent technologies in sustainable agriculture, specifically in aeroponics [5,11,13]. It is important to mention that a single study can report the use of multiple technologies. In such cases, all technologies were assigned to the study. The last column of Table 2 shows the number of studies that implemented each specific technology.
As observed in the last column of Table 2, 68% of the studies implemented technologies related to industry 4.0 (N = 32) or sensing technologies (N = 32). Industry 4.0-related technologies bring precision, efficiency, and sustainability to plant cultivation. These technologies empower growers with data-driven insights, enable remote management, and enhance resource efficiency, ultimately leading to higher yields, better quality crops, and a more environmentally conscious approach to agriculture. Similarly, sensing technologies play a crucial role in optimizing aeroponic systems. These technologies provide real-time data that enables precise control, early issue detection, resource efficiency, and informed decision making, ultimately leading to improved crop yields, reduced resource consumption, and more sustainable agricultural practices.
On the other hand, dispenser-related technologies were implemented in 57% of the studies (N = 27). Integrating dispenser technologies into aeroponic systems enhances nutrient delivery precision, reduces resource wastage, minimizes human errors, and facilitates remote management. These technologies contribute to improved plant growth, higher yields, and more efficient use of resources in controlled environment agriculture.
Finally, 11% (N = 5) of the studies implemented renewable energy-related technologies. Incorporating renewable energy-related technologies into aeroponics aligns with sustainability goals, reduces energy costs, and minimizes environmental impact. These technologies offer financial benefits, energy security, and a strong market position for growers committed to responsible and forward-looking agricultural practices.

4.1.2. Cultivated Products

The variety of products that can be cultivated in aeroponics is extensive; therefore, we grouped the products according to their nature: vegetables, fruits, tubers, flowers, and aromatic plants (See Table 3). We selected these categories because they involve the products most commonly cultivated in aeroponics [8,23]. Some aeroponic systems cultivated more than one product. In such cases, all the products were assigned to the corresponding category. Aeroponics can be implemented to grow various vegetables, fruits, tubers, flowers, and aromatic plants. However, space and nutrient requirements make some products more challenging to grow. The last column of Table 3 shows the number of studies related to the cultivation of each type of product.
The results of our study indicate that the most common cultivated product was vegetables (68%, N = 32). Specifically, in the vegetable category, lettuce was the number one cultivated product (29 studies). Other cultivated products were spinach, arugula, and garlic. Tubers (17%, N = 8) and fruits (15%, N = 7) were the second and third most cultivated products. All tuber-related studies referred to the cultivation of potatoes. On the other hand, the most popular fruit was tomato (4 studies), but there were also studies related to the cultivation of mulberries, strawberries, and chili peppers. Finally, flowers and aromatic plants were grown in four percent of the studies, which represents two studies in each category. Regarding flowers, the studies were related to lilies and sunflowers, while aromatic plants were related to coriander and artemisia.
The results show that various types of plants can be grown using aeroponics. However, this technique is particularly well-suited for crops requiring specific oxygen, moisture, and nutrients at the root level. It is worth noting that, while aeroponics are more commonly associated with plants that have shallow root systems, there is an increasing interest in growing certain root vegetables such as potatoes. These efforts aim to optimize the conditions to encourage healthy root growth and tuber formation.
While aeroponics offer numerous advantages for growing various types of plants, certain crops may not be well-suited for this cultivation method due to their growth habits, root structures, or other specific requirements. Hence, large root crops, woody plants and trees, vining plants, plants with high water needs, and plants with fragile stems are not traditionally suited for aeroponics. This is reflected in the lack of evidence found in our study and has been stated in previous studies [23,28].

4.1.3. Country of the Research

This variable corresponds to the country where the aeroponic system was implemented. In cases where the study did not report this information, we coded the country of the first author of the paper as the country of the research. This analysis is essential because it shows the leading countries in aeroponics. Thus, stakeholders can find institutions and authors to work with and countries that might offer support for their research. Figure 3 shows the distribution map of the studies. Grouping by regions, we can notice that 32 studies were implemented in Asia (68%), 10 in the Americas (21%), 4 in Europe (8%), 1 in Africa (2%), and none in Oceania.
Results in Figure 3 show Indonesia (N = 9) as the country where most studies were carried out, followed by China (N = 7) and Philippines (N = 7) in second place, and Colombia (N = 3) and Mexico (N = 3) in third place. It is also important to note that the studies were carried out in 20 different countries worldwide, reflecting the extended interest in aeroponics.
The practice of aeroponics aligns with the growing interest in sustainable and high-tech agriculture, as it addresses challenges related to limited arable land, water scarcity, and changing climatic conditions. Its global adoption reveals its potential to revolutionize modern agriculture and contribute to meeting the zero-hunger goal of the sustainable development goals (SDG2), especially in urban areas where traditional farming might be challenging. In this sense, it is important to note that the present study does not refer to the countries where aeroponics was implemented but to countries where aeroponic systems were enhanced by technology. This is why, while some studies place Africa as an important region for developing aeroponics [8,79], only one of the reviewed studies in this systematic review was implemented in that continent.
This study has two remarkable findings regarding the country of the study. First, the significant number of studies conducted in Asia (68% of the studies) and second, the low number of studies conducted in Europe (8% of the studies). As for Asia, it is noteworthy how this region has opted to invest and develop technological solutions for enhancing aeroponics, especially in the western and southern-east regions of the continent. Stakeholders in these regions have interpreted integrating technology into aeroponics as a strategic approach to modernizing agriculture, increasing food production, and addressing various challenges that communities face in today’s world. Conversely, although Europe is a leading continent in various technological-related aspects, there seems to be a lack of interest in developing technologies to be integrated into aeroponics. Given the continuous interest in the planet’s sustainability, healthy food, and economic facilities, this region has the potential to lead the field. Therefore, the results of this study can serve as a call to European researchers and practitioners to analyze the multiple benefits of integrating technology into aeroponics and thus promote such practices.

4.1.4. Publisher of the Study

This variable corresponds to the publisher of the journal in which the study was published (see Figure 4). We coded the publisher rather than the journal because most studies were published in different journals (or conference proceedings). Each journal or proceeding published at most three studies; therefore, coding the journals would produce a very long list. Information about the publisher is important because it informs stakeholders regarding the leading publishers in the field, allowing them to know where they can find relevant literature or plan to publish their research.
Results in Figure 4 show that IEEE published the largest number of studies in the present systematic review (40% of the studies) followed by MDPI (15% of the studies). On the other hand, the number of studies published by Elsevier and Springer (two studies each) is strikingly low, as they are considered two of the most important academic publishing companies. Twelve studies were published by journals that do not belong to a specific publisher but are instead associated with universities or academic institutions. Additionally, it is important to mention that 24 studies (51%), were presented at scientific conferences and published as conference proceedings.
Identifying reputable publishers that cover studies integrating technology into aeroponics allows researchers, students, and professionals to access a wealth of information on the topic. Scientific articles provide insights, data, methodologies, and advancements in the field, helping individuals stay informed about the latest developments. Furthermore, being aware of publishers in the aeroponics domain can also help researchers connect with other professionals in the field. They can attend conferences, workshops, and seminars hosted by these publishers to network and collaborate with fellow researchers. Finally, the findings published in scientific articles about aeroponics can be applied in real-world applications, such as urban agriculture, vertical farming, and controlled environment agriculture. This information can be crucial for individuals and organizations looking to implement or improve aeroponic systems. Therefore, knowing which publishers publish scientific articles about aeroponics facilitates access to reliable, up-to-date, and credible information. This information is vital for advancing research, education, innovation, and practical applications in the field of aeroponics.

4.1.5. Publication Date

We classified the studies by year of publication to identify the evolution over time concerning the integration of technology into aeroponic systems. This analysis is essential as it shows the tendency in the interest of the research community in the field. Figure 5 shows the distribution of the reviewed studies.
Figure 5 indicates a steady increase from 2015 onwards. The results shown in Figure 5 do not include the number of studies published in 2023, as the search for studies was conducted in the middle of the year. However, it is foreseeable that the number of published manuscripts tends to keep increasing, at least in the near future.
Monitoring the number of published studies per year helps gauge the growth of research interest in technology-driven aeroponics. A steady increase in the number of studies, as indicated in Figure 5, indicates a growing focus on the subject, reflecting its relevance and potential. This information is also important to public and private funding organizations, as they often rely on research trends to allocate resources. Knowledge of the number of studies can facilitate funding decisions related to technology development and research initiatives in aeroponics.

4.2. Advantages of the Use of Technology in Aeroponic Systems

This section presents and discusses the results regarding the main advantages reported in technology-assisted aeroponics. We searched for the reported advantages in each study’s abstract, results, discussion, and conclusion sections. As expected, the integration of technology in aeroponics provides multiple advantages. All of the studies reported at least one advantage, and most reported two or more. Hence, we organized the advantages into eight categories to produce a shorter list. In this sense, the most reported advantage is sustainability, which corroborates the idea of aeroponics as a sustainable agriculture technique. Table 4 presents the description of the eight categories of advantages and the number of studies in each category.
Results in Table 4 show sustainability as the most reported advantage of using technology in aeroponics (53% of the studies). This is an encouraging result, as sustainability is one of the incentives for implementing this agricultural technique. A study by Sadek et al. [75] presented the design and implementation of a smart greenhouse using Industry 4.0-related technologies, such as IoT, AI, and machine learning. The authors claimed that by using these technologies, the aeroponic system maximized the use of water, energy, and agricultural fertilizers to achieve the highest productivity while supporting sustainable food production. The authors concluded that such a sustainability level was only possible using the implemented technologies.
Time efficiency was the second most reported advantage (45% of the studies). Technologies such as sensors and microcontrollers allow for precise control over environmental factors, helping reduce crop cycles and thus increasing efficiency. Using IoT, sensors, and microcontrollers, Dhanasekar et al. [74] implemented an efficient smart agriculture system. The authors concluded that the precision provided by using these technologies allows the creation of suitable environments for the plants, thus ensuring maximum crop efficiency.
Technology has also been described to increase production in aeroponics (32% of the studies). For example, AI algorithms can optimize nutrient profiles and growing conditions for maximum production. Such is the case reported in the study by Riswandi et al. [65], who concluded that with technology controlling environmental factors such as temperature, humidity, and light, plants can experience accelerated growth rates, thus increasing overall productivity.
Thirty percent of the studies reported cleaner production as an advantage of using technology in aeroponics. Using specific technologies, such as automated monitoring and sterilization systems, ensures cleaner and healthier production through controlled environments that limit exposure to pests and diseases. For example, Guo et al. [78] implemented a back propagation neural network algorithm to identify mildew on the roots of mulberry branches in rapid propagation. The authors reported that the system accurately identified mulberry cuttings affected by mildew disease with an accuracy rate of 80%, which is described as excellent performance in ensuring clean and healthy production.
Cost-effectiveness is a contrasting finding in this study. While previous studies have identified high costs as one of the main challenges of integrating technology in aeroponics [13,80], 23% of the reviewed studies reported that using technology helps reduce costs associated with production. However, it is important to note that this benefit is not achieved in the short term. The study by Calzita et al. [76] highlighted the benefits of automation for cost savings. The authors reported a reduction in labor costs, use of resources such as nutrients, water, and pesticides, as well as increased productivity and decreased production cycles, which resulted in better profitability of the automated crop.
Space efficiency was reported as an advantage in 19% of the studies. For example, technology helps design and implement efficient vertical systems, making the most of the available space. Such is the case reported in the study by Belista et al. [47], who used IoT, sensors, and different elements of dispenser technology to create a smart aeroponic vertical system. The authors highlighted that technology allowed them to maximize production while reducing crop space. Therefore, they propose this type of cultivation as essential to promote urban farming, where space is usually limited.
Product size was reported as an advantage in 17% of the studies. By controlling nutrient misting, humidity levels, and lighting through automation, plants receive optimal conditions for growth. This results in improved nutrient absorption, root development, and photosynthesis efficiency, all of which contribute to larger products. Yang et al. [9] implemented an ultrasonic aeroponic system to improve lettuce size. Using a smart dispenser system, the researchers managed to control the wind speed, the ambient temperature, and the atomization time, three determining factors for the product size. The authors claimed that the precise control of these variables, achieved thanks to technological tools, was key to obtaining better product size, thus improving crop profitability.
Finally, 13% of the studies reported continuous production as an advantage of using technology in aeroponics. That is, controlled environments powered by technology enable year-round cultivation regardless of external weather conditions. This can lead to consistent crop production and a more predictable supply chain. By controlling root lighting of the roots of the artemisia plant, the study by Paponov et al. [77] achieved year-round production in an aeroponic system located in Norway. Additionally, the authors controlled the temperature and humidity of the roots, which translated into the precise control of the conditions for production. The authors highlighted the benefits of technology to ensure food production in places with highly changeable climates, such as the northernmost countries.

4.3. Disadvantages of the Use of Technology in Aeroponics

This section presents and discusses the results regarding the main disadvantages reported in technology-assisted aeroponics. We searched for the reported disadvantages in each study’s abstract, results, discussion, and conclusion sections. While technology integration brings multiple benefits, some challenges remain to be addressed to obtain the best of this emerging production technique. Eight studies (17%) reported at least one challenge or disadvantage in technology-assisted aeroponics. We organized the disadvantages into five categories to produce a shorter list. In this sense, the most reported disadvantage is technical complexity, which poses a challenge for the dissemination of this agriculture technique. Table 5 presents the description of the five categories of disadvantages and classifies the studies per reported disadvantages.
Technical Complexity was the most reported challenge of using technology in aeroponics (13% of the studies). That is, the more technological elements a system has, the more complex the system will be [81]. This challenge was pointed out by Setiowati et al. [73], who reported that aeroponic systems with advanced technology can become complex, with multiple components working together. The authors concluded that ensuring compatibility and reliability among various components, such as pumps, misting systems, nutrient delivery mechanisms, and sensors, can be the main challenges to succeed in modern aeroponics.
Power dependency was reported as a challenge in 6% of the studies. Integrating technology often increases energy consumption, especially if advanced lighting and environmental control systems are used. More importantly, power failures can translate into crop loss. In their study, Sani et al. [12] claimed that balancing the benefits of technology with energy efficiency is crucial for sustainable operations. In this sense, the authors highlighted the importance of using renewable energy sources to mitigate the negative effects of power consumption in aeroponics.
Finally, setup cost, maintenance and monitoring, and learning curve were associated as an advantage of integrating technology into aeroponics in the study by Sadek et al. [75]. While it is well known that aeroponics technology is a long-term inversion, it is also true that initial costs are only affordable by some stakeholders. Similarly, integrating technology into aeroponics implies maintaining and monitoring those technologies. Therefore, downtime for maintenance and repairs could interrupt production schedules and lead to decreased yields. Finally, technology integration involves adequate technical expertise to ensure the system’s proper functioning. Therefore, this situation may require additional training or hiring specialized personnel.

4.4. Level of Technology Integration in Aeroponics

This section presents and discusses the results regarding the level of technology integration in technology-supported aeroponics. We evaluated this level based on the TAISA model (see Figure 1). This analysis aims to identify the purpose of technology integration in each specific aeroponic system. Accordingly, we assigned each case a level of “limited”, “basic”, “moderate”, or “advanced”. This evaluation was performed by two researchers with degrees in electronics who are experts in aeroponic systems. The results indicate that the most common level is “advanced”, which indicates that technology has primarily been employed in creating new processes that are not possible to implement without the help of technology. Figure 6 depicts the number of studies in each category.
As indicated in Figure 6, 2% of the studies presented a limited level of integration (N = 1), indicating that the purpose was not to improve the system functions but to replace some traditional tools. Nine percent of the studies presented a basic level of integration (N = 4), which indicates that producers partially implemented technologically based solutions with some improvements in the process. Similarly, 34% of the studies used technology at a moderate level (N = 16), indicating that some processes were intervened with technology, and the production was notoriously improved. Finally, 57% of the studies presented an advanced level of technology (N = 27), indicating that all the processes were intervened with technology, and technology was implemented to create new processes. Next, we describe some studies, with the motivation behind them being coded in the assigned category.

4.4.1. Limited Integration of Technology in an Aeroponic System

As indicated in Figure 1, a study was coded as “Limited” when technology was used to substitute specific activities or tools without functional changes or improvements. In the present review, only the study by Dannehl et al. [45] was assigned to this category. The study proposed a hybrid aeroponic/nutrient film technique system for the cultivation of greenhouse tomatoes. The system was installed using conventional materials and equipment available on the market. Despite using multiple elements related to dispenser technology, their study did not report functional changes in the process. That is, the implemented technology did not enhance the process; it only replaced manual irrigation.

4.4.2. Basic Integration of Technology in an Aeroponic System

A study was coded as “Basic” when a few fundamental technological components were incorporated to improve functionality and efficiency. For example, the study by Mazhar et al. [63] developed an automated atomization and spraying system to grow lettuce in an aeroponic system. Specifically, the system aimed to impact the chemical properties of the nutrient solution, biomass yield, root-to-shoot ratio, and nutrients uptake. The system allowed a high dosage accuracy of plant root coverage, thus saving energy, resources, and contributing to sustainability. In this case, the implemented technology improved the process but did not fundamentally change it.

4.4.3. Moderate Integration of Technology in an Aeroponic System

A study was coded as “Moderate” when technology was consistently integrated into an aeroponic system to significantly improve product quality and sustainability efforts. For example, the study by Mehmood et al. [71] designed a prototype aeroponic system for indoor vegetable plant growth using the AutoCAD design software. The system included a timer to control the irrigation interval, a submergible pump, a plastic pipe for water flow, and LED lights to control the sunlight requirement. The authors claimed to have reduced the number of hours dedicated by the growers and the number of resources utilized throughout the process, thus contributing to efficiency and sustainability. In this case, the implemented technology modified the process and enhanced efficiency and sustainability.

4.4.4. Advanced Integration of Technology in an Aeroponic System

A study was coded as “Advanced” when technology was fully integrated into the system to create new processes, which is not otherwise possible without the use of technology. The fertigation control system presented by Setiowati et al. [73] is a clear example of an advanced technology integration. The system managed to control the temperature of the roots at an ideal temperature for growing lettuce. This precise control would not be possible without using technology; therefore, technology redefined the process. The system used multiple technologies, such as IoT, sensors, and microprocessors, which altogether enhanced the system’s efficiency, rentability, and sustainability.

4.5. Limitations of the Study and Future Research

The results of this study are promising and show how integrating technology into aeroponics can provide multiple benefits for growers, consumers, and nature alike. However, some limitations must be considered when interpreting our results. First, we included journal and conference articles published in four bibliometric databases. Therefore, considering other types of studies, such as dissertations, books, and unpublished studies, could have enriched the scope of our results. Additionally, including different databases and conference proceedings could enhance the sample, providing a more accurate panorama.
On the other hand, this study uses the TAISA model to identify the technology integration level in aeroponics and how this integration benefits the production process. Therefore, we encourage stakeholders to embrace similar research projects to identify how technology can be integrated into similar sustainable agricultural techniques, such as hydroponics and aquaponics.

5. Conclusions

This systematic review identified the status and tendencies in the usage of technology in aeroponics as well as the main opportunities and challenges. Furthermore, the study introduced a TAISA model to identify the level of technology integration in sustainable agriculture. To the best of our knowledge, this is the first study of its type. Therefore, the results of this review can serve as a reference for policymakers, researchers, and producers.
As for the trends regarding the use of technology in aeroponics, the results indicate that most implemented technologies are related to Industry 4.0 and sensors. Furthermore, the most cultivated products are vegetables, particularly lettuce. Indonesia is the country where most studies were developed, and Asia is the leading continent regarding the publication of studies related to technology integration into aeroponics. IEEE published the largest number of studies, and finally, the classification by year of publication indicates an increasing number of studies from 2015.
As for the advantages of integrating technology into aeroponics, sustainability was the most reported advantage. This result is positive, as sustainability is a key incentive for implementing aeroponics. On the other hand, technical complexity was described as the main challenge of integrating technology into aeroponics. Integrating advanced technology requires technical and expert knowledge, increasing the system’s complexity.
Finally, the results indicate that the most common level of technology integration is “Advanced”, which supposes that technology has been implemented with the purpose of redefining and creating new processes. It is important to note that the level of technology integration depends on factors such as budget, system scale, and the goals of the aquaponics project. In summary, integrating technology into aeroponics can reshape modern agriculture by fostering sustainable practices, increasing yields, mitigating resource constraints, and assisting in achieving the zero-hunger sustainable goal. As technological advancements evolve, careful consideration of both the benefits and limitations will pave the way for a more efficient, productive, and resilient aeroponic cultivation system.

Author Contributions

Conceptualization, J.G. (Juan Garzón), L.M. and J.G. (Jorge Garzón); methodology, J.G. (Juan Garzón), L.M. and J.G. (Jorge Garzón); software, J.G. (Juan Garzón); validation, J.G. (Juan Garzón) and L.M.; formal analysis, J.G. (Juan Garzón) and L.M.; investigation, J.G. (Juan Garzón) and L.M.; resources, J.G. (Juan Garzón) and L.M.; data curation, J.G. (Juan Garzón) and L.M.; writing—original draft preparation, J.G. (Juan Garzón) and G.L.; writing—review and editing, J.G. (Juan Garzón) and G.L.; project administration, J.G. (Jorge Garzón); funding acquisition, J.G. (Jorge Garzón). All authors have read and agreed to the published version of the manuscript.

Funding

This is a product of the Research Program: “Technologies in Urban Farming”, called Minciencias 852, 2019 (Grant Number: 127-2021). It is funded with resources from the “Patrimonio Autónomo Fondo Nacional de Financiamiento para la Ciencia, la Tecnología y la Innovación Francisco José de Caldas” (Francisco José de Caldas National Fund for Science, Technology and Innovation), Ministerio de Ciencia, Tecnología e Innovación (Minciencias), Colombia.

Data Availability Statement

All data related to this research study can be requested from the corresponding author.

Acknowledgments

The authors thank the Universidad Católica de Oriente for allowing us to participate in this research project. In addition, we thank Minciencias for financing the project.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

References

  1. Wimmerova, L.; Keken, Z.; Solcova, O.; Bartos, L.; Spacilova, M. A Comparative LCA of Aeroponic, Hydroponic, and Soil Cultivations of Bioactive Substance Producing Plants. Sustainability 2022, 14, 2421. [Google Scholar] [CrossRef]
  2. FAO. The Future of Food and Agriculture—Trends and Challenges; FAO: Rome, Italy, 2017. [Google Scholar]
  3. Kumar, P.; Sampath, B.; Kumar, S.; Babu, B.; Ahalya, N. Hydroponics, Aeroponics, and Aquaponics Technologies in Modern Agricultural Cultivation. In Trends, Paradigms, and Advances in Mechatronics Engineering; IGI Global: Hershey, PA, USA, 2023; pp. 223–241. [Google Scholar]
  4. Balasundram, S.K.; Shamshiri, R.R.; Sridhara, S.; Rizan, N. The Role of Digital Agriculture in Mitigating Climate Change and Ensuring Food Security: An Overview. Sustainability 2023, 15, 5325. [Google Scholar] [CrossRef]
  5. Bhakta, I.; Phadikar, S.; Majumder, K. State-of-the-Art Technologies in Precision Agriculture: A Systematic Review. J. Sci. Food Agric. 2019, 99, 4878–4888. [Google Scholar] [CrossRef] [PubMed]
  6. Gurley, T.W. Aeroponics, 1st ed.; CRC Press: Boca Raton, FL, USA, 2020; ISBN 9780367810078. [Google Scholar]
  7. Chaudhry, A.R.; Mishra, V.P. A Comparative Analysis of Vertical Agriculture Systems in Residential Apartments. In Proceedings of the 2019 Advances in Science and Engineering Technology International Conferences (ASET), Dubai, United Arab Emirates, 26 March–10 April 2019. [Google Scholar] [CrossRef]
  8. Lakhiar, I.A.; Gao, J.; Syed, T.N.; Chandio, F.A.; Buttar, N.A. Modern Plant Cultivation Technologies in Agriculture under Controlled Environment: A Review on Aeroponics. J. Plant Interact. 2018, 13, 338–352. [Google Scholar] [CrossRef]
  9. Yang, X.; Luo, Y.; Jiang, P. Sustainable Soilless Cultivation Mode: Cultivation Study on Droplet Settlement of Plant Roots under Ultrasonic Aeroponic Cultivation. Sustainability 2022, 14, 13705. [Google Scholar] [CrossRef]
  10. Niu, G.; Masabni, J. Hydroponics. In Plant Factory Basics, Applications and Advances; Elsevier: Amsterdam, The Netherlands, 2022; pp. 153–166. [Google Scholar]
  11. Abbasi, R.; Martinez, P.; Ahmad, R. The Digitization of Agricultural Industry—A Systematic Literature Review on Agriculture 4.0. Smart Agric. Technol. 2022, 2, 100042. [Google Scholar] [CrossRef]
  12. Sani, M.; Siregar, S.; Kumiawan, A.; Jauhari, R.; Mandalahi, C. Web-Based Monitoring and Control System for Aeroponics Growing Chamber. In Proceedings of the 2016 International Conference on Control, Electronics, Renewable Energy and Communications (ICCEREC), Bandung, Indonesia, 13–15 September 2016; pp. 162–168. [Google Scholar]
  13. Khan, M.; Akram, M.; Janke, R.; Khan, R.; Al-Sadi, A.; Farooque, A. Urban Horticulture for Food Secure Cities through and beyond COVID-19. Sustainability 2020, 12, 9592. [Google Scholar] [CrossRef]
  14. Lakhiar, I.A.; Gao, J.; Syed, T.N.; Ali Chandio, F.; Tunio, M.H.; Ahmad, F.; Ali Solangi, K. Overview of the Aeroponic Agriculture—An Emerging Technology for Global Food Security. Int. J. Agric. Biol. Eng. 2020, 13, 1–10. [Google Scholar] [CrossRef]
  15. Lakhiar, I.A.; Jianmin, G.; Syed, T.N.; Chandio, F.A.; Buttar, N.A.; Qureshi, W.A. Monitoring and Control Systems in Agriculture Using Intelligent Sensor Techniques: A Review of the Aeroponic System. J. Sens. 2018, 2018, 8672769. [Google Scholar] [CrossRef]
  16. Rahmad, I.; Tanti, L.; Puspasari, R.; Ekadiansyah, E.; Agung Fragastia, V. Automatic Monitoring and Control System in Aeroponic Plant Agriculture. In Proceedings of the 2020 8th International Conference on Cyber and IT Service Management (CITSM), Pangkal, Indonesia, 23–24 October 2020; pp. 1–5. [Google Scholar] [CrossRef]
  17. Fasciolo, B.; Awouda, A.; Bruno, G.; Lombardi, F. A Smart Aeroponic System for Sustainable Indoor Farming. Procedia CIRP 2023, 116, 636–641. [Google Scholar] [CrossRef]
  18. Lasi, H.; Fettke, P.; Kemper, H.-G.; Feld, T.; Hoffmann, M. Industry 4.0. Bus. Inf. Syst. Eng. 2014, 6, 239–242. [Google Scholar] [CrossRef]
  19. Roffi, T.M.; Jamhari, C.A. Internet of Things Based Automated Monitoring for Indoor Aeroponic System. Int. J. Electr. Comput. Eng. 2023, 13, 270. [Google Scholar] [CrossRef]
  20. Torres-Tello, J.; Ko, S.-B. Interpretability of Artificial Intelligence Models That Use Data Fusion to Predict Yield in Aeroponics. J. Ambient Intell. Humaniz. Comput. 2023, 14, 3331–3342. [Google Scholar] [CrossRef]
  21. Ragaveena, S.; Shirly Edward, A.; Surendran, U. Smart Controlled Environment Agriculture Methods: A Holistic Review. Rev. Environ. Sci. Bio/Technol. 2021, 20, 887–913. [Google Scholar] [CrossRef]
  22. Morgunov, A.P.; Kirgizova, I.V. Control Unit for the Dosed Feeding of the Nutrient Solution into the Industrial Aeroponic Installation System. J. Phys. Conf. Ser. 2019, 1210, 012099. [Google Scholar] [CrossRef]
  23. Eldridge, B.M.; Manzoni, L.R.; Graham, C.A.; Rodgers, B.; Farmer, J.R.; Dodd, A.N. Getting to the Roots of Aeroponic Indoor Farming. New Phytol. 2020, 228, 1183–1192. [Google Scholar] [CrossRef]
  24. Sumarni, E.; Hardanto, A.; Arsil, P. Effect of Root Zone Cooling and Evaporative Cooling in Greenhouse on the Growth and Yield of Potato Seed by Aeroponics in Tropical Lowlands. Agric. Eng. Int. CIGR J. 2021, 23, 28–35. [Google Scholar]
  25. Devederkin, I.V.; Antonov, S.N.; Permyakov, A.V. Aerosol Management of Nutrients in Aeroponic Potato Mini-Tubers Cultivation Technology. IOP Conf. Ser. Earth Environ. Sci. 2021, 852, 012021. [Google Scholar] [CrossRef]
  26. Ramalingannanavar, N.; Nemichandrappa, M.; Srinivasa Reddy, G.V.; Dandekar, A.T.; Kamble, J.B.; Dhanoji, M.M. Design, Development and Evaluation of Solar Powered Aeroponic System—A Case Study. Int. J. Curr. Microbiol. Appl. Sci. 2020, 9, 3102–3112. [Google Scholar] [CrossRef]
  27. Klarin, B.; Garafulić, E.; Vučetić, N.; Jakšić, T. New and Smart Approach to Aeroponic and Seafood Production. J. Clean. Prod. 2019, 239, 117665. [Google Scholar] [CrossRef]
  28. Fussy, A.; Papenbrock, J. An Overview of Soil and Soilless Cultivation Techniques—Chances, Challenges and the Neglected Question of Sustainability. Plants 2022, 11, 1153. [Google Scholar] [CrossRef] [PubMed]
  29. Basso, B.; Antle, J. Digital Agriculture to Design Sustainable Agricultural Systems. Nat. Sustain. 2020, 3, 254–256. [Google Scholar] [CrossRef]
  30. Ríos, J.; Candelo, J.; Hoyos, F. Growing Arugula Plants Using Aeroponic Culture with an Automated Irrigation System. Int. J. Agric. Biol. Eng. 2020, 13, 52–56. [Google Scholar] [CrossRef]
  31. Lucero, L.; Lucero, D.; Ormeno-Mejia, E.; Collaguazo, G. Automated Aeroponics Vegetable Growing System. Case Study Lettuce. In Proceedings of the 2020 IEEE ANDESCON, Quito, Ecuador, 13–16 October 2020. [Google Scholar] [CrossRef]
  32. Tunio, M.H.; Gao, J.; Shaikh, S.A.; Lakhiar, I.A.; Qureshi, W.A.; Solangi, K.A.; Chandio, F.A. Potato Production in Aeroponics: An Emerging Food Growing System in Sustainable Agriculture for Food Security. Chil. J. Agric. Res. 2020, 80, 118–132. [Google Scholar] [CrossRef]
  33. Jamshidi, A.; Moghaddam, A.; Ommani, A. Effect of Ultrasonic Atomizer on the Yield and Yield Components of Tomato Grown in a Vertical Aeroponic Planting System. Int. J. Hortic. Sci. Technol. 2019, 6, 237–246. [Google Scholar] [CrossRef]
  34. Puentedura, R. Transformation, Technology, and Education. Available online: http://www.hippasus.com/rrpweblog/archives/2013/05/29/SAMREnhancementToTransformation.pdf (accessed on 22 September 2023).
  35. Hamilton, E.R.; Rosenberg, J.M.; Akcaoglu, M. The Substitution Augmentation Modification Redefinition (SAMR) Model: A Critical Review and Suggestions for Its Use. TechTrends 2016, 60, 433–441. [Google Scholar] [CrossRef]
  36. Page, M.J.; McKenzie, J.E.; Bossuyt, P.M.; Boutron, I.; Hoffmann, T.C.; Mulrow, C.D.; Shamseer, L.; Tetzlaff, J.M.; Akl, E.A.; Brennan, S.E.; et al. The PRISMA 2020 Statement: An Updated Guideline for Reporting Systematic Reviews. Syst. Rev. 2021, 10, 105906. [Google Scholar] [CrossRef]
  37. Kitchenham, B.; Charters, S. Guidelines for Performing Systematic Literature Reviews in Software Engineering Version 2.3; Keele University: Keele, UK; Durham University: Durham, UK, 2007. [Google Scholar]
  38. Krippendorff, K. Content Analysis: An Introduction to Its Methodology; Sage Publications: Thousand Oaks, CA, USA, 2018. [Google Scholar]
  39. Cohen, J. Weighted Kappa: Nominal Scale Agreement Provision for Scaled Disagreement or Partial Credit. Psychol. Bull. 1968, 70, 213. [Google Scholar] [CrossRef]
  40. Idris, I.; Sani, M.I. Monitoring and Control of Aeroponic Growing System for Potato Production. In Proceedings of the 2012 IEEE Conference on Control, Systems & Industrial Informatics, Bandung, Indonesia, 23–26 September 2012; pp. 120–125. [Google Scholar] [CrossRef]
  41. Reyes, J.L.; Montoya, R.; Ledesma, C.; Ramírez, R. Development of an Aeroponic System for Vegetable Production. Acta Hortic. 2012, 947, 153–156. [Google Scholar] [CrossRef]
  42. Pathania, N.; Trevorrow, P.; Hughes, M.; Marton, T.; Justo, V.; Salvani, J. Preliminary Research to Develop a Low_technology Aeroponic System for Producing Clean Seed Potato in the Philippines. In Proceedings of the ACIAR–PCAARRD Southern Philippines Fruits and Vegetables Program Meeting, Cebu, Philippines, 3 July 2012; pp. 138–147. [Google Scholar]
  43. Pathania, N.; Trevorrow, P.; Hughes, M.; Jovicich, E. Optimization of Aeroponic Technology for Future Integration in Quality Potato Seed Production Systems in Tropical Environments. Acta Hortic. 2016, 1118, 31–38. [Google Scholar] [CrossRef]
  44. He, J. Integrated Vertical Aeroponic Farming Systems for Vegetable Production in Space Limited Environments. Acta Hortic. 2017, 1176, 25–36. [Google Scholar] [CrossRef]
  45. Dannehl, D.; Taylor, Z.; Suhl, J.; Miranda, L.; Ulrichs, C.; Salazar, C.; Fitz-Rodriguez, E.; Lopez-Cruz, I.; Rojano-Aguliar, A.; Navas-Gomez, G.; et al. Sustainable Cities: Viability of a Hybrid Aeroponic/Nutrient Film Technique System for Cultivation of Tomatoes. Int. J. Agric. Biosyst. Eng. 2017, 11, 470–477. [Google Scholar]
  46. Montoya, A.P.; Obando, F.A.; Morales, J.G.; Vargas, G. Automatic Aeroponic Irrigation System Based on Arduino’s Platform. J. Phys. Conf. Ser. 2017, 850, 012003. [Google Scholar] [CrossRef]
  47. Belista, F.C.L.; Go, M.P.C.; Lucenara, L.L.; Policarpio, C.J.G.; Tan, X.J.M.; Baldovino, R.G. A Smart Aeroponic Tailored for IoT Vertical Agriculture Using Network Connected Modular Environmental Chambers. In Proceedings of the 2018 IEEE 10th International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment and Management (HNICEM), Baguio City, Philippines, 29 November–2 December 2018; pp. 1–4. [Google Scholar]
  48. Rahman, F.; Ritun, I.J.; Ahmed Biplob, M.R.; Farhin, N.; Uddin, J. Automated Aeroponics System for Indoor Farming Using Arduino. In Proceedings of the 2018 Joint 7th International Conference on Informatics, Electronics & Vision (ICIEV) and 2018 2nd International Conference on Imaging, Vision & Pattern Recognition (icIVPR), Kitakyushu, Japan, 25–29 June 2018; pp. 137–141. [Google Scholar]
  49. Chang, H.-Y.; Wang, J.-J.; Lin, C.-Y.; Chen, C.-H. An Agricultural Data Gathering Platform Based on Internet of Things and Big Data. In Proceedings of the 2018 International Symposium on Computer, Consumer and Control (IS3C), Taichung, Taiwan, 6–8 December 2018; pp. 302–305. [Google Scholar]
  50. Hoyos, F.; Candelo, J.; Chavarria, H. Automation of Pesticide-Free Cilantro Aeroponic Crops. INGE CUC 2019, 15, 123–132. [Google Scholar] [CrossRef]
  51. Vera-Puerto, I.; Olave, J.; Tapia, S.; Chávez, W. Atacama Desert: Water Resources and Reuse of Municipal Wastewater in Irrigation of Cut Flower Aeroponic Cultivation System (First Laboratory Experiments). Desalination Water Treat. 2019, 150, 73–83. [Google Scholar] [CrossRef]
  52. Lakhiar, I.A.; Gao, J.; Xu, X.; Syed, T.N.; Chandio, F.A.; Jing, Z.; Buttar, N.A. Effects of Various Aeroponic Atomizers (Droplet Sizes) on Growth, Polyphenol Content, and Antioxidant Activity of Leaf Lettuce (Lactuca sativa L.). Trans. ASABE 2019, 62, 1475–1487. [Google Scholar] [CrossRef]
  53. Argo, B.D.; Hendrawan, Y.; Ubaidillah, U. A Fuzzy Micro-Climate Controller for Small Indoor Aeroponics Systems. Telkomnika Telecommun. Comput. Electron. Control 2019, 17, 3019–3026. [Google Scholar] [CrossRef]
  54. Jamhari, C.A.; Wibowo, W.K.; Annisa, A.R.; Roffi, T.M. Design and Implementation of IoT System for Aeroponic Chamber Temperature Monitoring. In Proceedings of the 2020 Third International Conference on Vocational Education and Electrical Engineering (ICVEE), Surabaya, Indonesia, 3–4 October 2020; pp. 1–4. [Google Scholar] [CrossRef]
  55. Torres-Tello, J.; Venkatachalam, S.; Moreno, L.; Ko, S.B. Ensemble Learning for Improving Generalization in Aeroponics Yield Prediction. In Proceedings of the 2020 IEEE International Symposium on Circuits and Systems (ISCAS), Seville, Spain, 12–14 October 2020; pp. 1–5. [Google Scholar] [CrossRef]
  56. Cabascango, M.; Mejia-Echeverria, C.; Morales, D.O.; Ojeda Pena, D. Modeling of Forced Airflow in a Greenhouse. In Proceedings of the 2020 IEEE ANDESCON, Quito, Ecuador, 13–16 October 2020; pp. 1–5. [Google Scholar] [CrossRef]
  57. Caya, M.V.C.; Dela Cruz, J.C.; Estrella, A.M.C.; Mendoza, J.C.A. Fuzzy Controlled LED Lighting Compensation for Aeroponics System. In Proceedings of the 2021 IEEE 13th International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment, and Management (HNICEM), Manila, Philippines, 28–30 November 2021; pp. 1–6. [Google Scholar]
  58. Karuniawati, S.; Gautama Putrada, A.; Rakhmatsyah, A. Optimization of Grow Lights Control in IoT-Based Aeroponic Systems with Sensor Fusion and Random Forest Classification. In Proceedings of the 2021 International Symposium on Electronics and Smart Devices (ISESD), Bandung, Indonesia, 29–30 June 2021; pp. 1–6. [Google Scholar]
  59. Kuncoro, B.; Sutandi, T.; Adristi, C.; Kuan, Y. Aeroponics Root Chamber Temperature Conditioning Design for Smart Mini-Tuber Potato Seed Cultivation. Sustainability 2021, 13, 5140. [Google Scholar] [CrossRef]
  60. Chowdhury, M.; Islam, M.N.; Reza, M.N.; Ali, M.; Rasool, K.; Kiraga, S.; Lee, D.H.; Chung, S.O. Sensor-Based Nutrient Recirculation for Aeroponic Lettuce Cultivation. J. Biosyst. Eng. 2021, 46, 81–92. [Google Scholar] [CrossRef]
  61. Narimani, M.; Hajiahmad, A.; Moghimi, A.; Alimardani, R.; Rafiee, S.; Mirzabe, A.H. Developing an Aeroponic Smart Experimental Greenhouse for Controlling Irrigation and Plant Disease Detection Using Deep Learning and IoT. In Proceedings of the 2021 ASABE Annual International Virtual Meeting, Online, 12–16 July 2021; American Society of Agricultural and Biological Engineers: St. Joseph, MI, USA, 2021. [Google Scholar]
  62. Tang, H.C.K.; Cheng, T.Y.S.; Wong, J.C.Y.; Cheung, R.C.C.; Lam, A.H.F. Aero-Hydroponic Agriculture IoT System. In Proceedings of the 2021 IEEE 7th World Forum on Internet of Things (WF-IoT), New Orleans, LA, USA, 14 June–31 July 2021; pp. 741–746. [Google Scholar]
  63. Tunio, M.H.; Gao, J.; Lakhiar, I.A.; Solangi, K.A.; Qureshi, W.A.; Shaikh, S.A.; Chen, J. Influence of Atomization Nozzles and Spraying Intervals on Growth, Biomass Yield, and Nutrient Uptake of Butter-Head Lettuce under Aeroponics System. Agronomy 2021, 11, 97. [Google Scholar] [CrossRef]
  64. Rahman, M.H.; Islam, M.J.; Azad, M.O.K.; Rana, M.S.; Ryu, B.R.; Lim, Y.S. Led Light Pre-Treatment Improves Pre-Basic Seed Potato (Solanum Tuberosum l. Cv. Golden King) Production in the Aeroponic System. Agronomy 2021, 11, 1627. [Google Scholar] [CrossRef]
  65. Riswandi; Niswar, M.; Tahir, Z.; Zainal; Wey, C.Y. Design and Implementation of IoT-Based Aeroponic Farming System. In Proceedings of the 2022 IEEE International Conference on Cybernetics and Computational Intelligence (CyberneticsCom), Malang, Indonesia, 16–18 June 2022; pp. 308–311. [Google Scholar]
  66. Martinez-Nolasco, C.; Padilla-Medina, J.A.; Nolasco, J.J.M.; Guevara-Gonzalez, R.G.; Barranco-Gutiérrez, A.I.; Diaz-Carmona, J.J. Non-Invasive Monitoring of the Thermal and Morphometric Characteristics of Lettuce Grown in an Aeroponic System through Multispectral Image System. Appl. Sci. 2022, 12, 6540. [Google Scholar] [CrossRef]
  67. Bolivar, P.B.N.; Clar, J.L.G.; Constantino, M.J.L.; Roguin, E.A.; Beano, M.G.P.; Capuno, M.E.A.D.; Agustin, E.V.; Soriano, A.J.; Sigue, A.F. IoT-Based Aeroponic System for Seasonal Plants Using Fuzzy Logic. In Proceedings of the TENCON 2022–2022 IEEE Region 10 Conference (TENCON), Hong Kong, China, 1–4 November 2022; pp. 1–6. [Google Scholar]
  68. Estuita, J.A.; Arthur Monillas, J.; Ramos, J.; Reas, R.; Bandala, A.; Concepcion, R.; Francisco, K.; Vicerra, R.R.; Dadios, E.P. Structure and Misting Subsystem Design of Automated Aeroponic System for Lactuca Sativa Production. In Proceedings of the 2022 IEEE 14th International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment, and Management (HNICEM), Boracay Island, Philippines, 1–4 December 2022; pp. 1–7. [Google Scholar]
  69. Qi, S.; Ma, Y.; Zhang, M.; Yin, B.; Xu, Z.; Liu, S. Design and Experiment of a Barrel-Shaped Aeroponic Cultivation System. Int. J. Agric. Biol. Eng. 2022, 15, 90–94. [Google Scholar] [CrossRef]
  70. Méndez-Guzmán, H.A.; Padilla-Medina, J.A.; Martínez-Nolasco, C.; Martinez-Nolasco, J.J.; Barranco-Gutiérrez, A.I.; Contreras-Medina, L.M.; Leon-Rodriguez, M. IoT-Based Monitoring System Applied to Aeroponics Greenhouse. Sensors 2022, 22, 5646. [Google Scholar] [CrossRef] [PubMed]
  71. Mehmood, U.; Khaliq, A.; Ahmad, F.; Awais, M. Test and Evaluation of Prototype Aeroponic System for Indoor Vegetable Plant Growth. In Proceedings of the 1st International Conference on Innovative Academic Studies, Konya, Turkey, 10–13 September 2022; pp. 1–6. [Google Scholar]
  72. Mohamed, T.; Gao, J.; Tunio, M. Development and Experiment of the Intelligent Control System for Rhizosphere Temperature of Aeroponic Lettuce via the Internet of Things. Int. J. Agric. Biol. Eng. 2022, 15, 225–233. [Google Scholar] [CrossRef]
  73. Setiowati, S.; Wardhani, R.N.; Riandini; Agustina Siregar, E.B.; Saputra, R.; Sabrina, R.A. Fertigation Control System on Smart Aeroponics Using Sugeno’s Fuzzy Logic Method. In Proceedings of the 2022 8th International Conference on Science and Technology (ICST), Yogyakarta, Indonesia, 7–8 September 2022; pp. 1–6. [Google Scholar]
  74. Dhanasekar, S.; Abarna, V.K.; Gayathri, V.; Valarmathi, G.; Madhumita, D.; Jeevitha, R. An Efficient Smart Agriculture System Based on The Internet of Things Using Aeroponics Method. In Proceedings of the 2023 9th International Conference on Advanced Computing and Communication Systems (ICACCS), Coimbatore, India, 17–18 March 2023; pp. 1386–1391. [Google Scholar]
  75. Sadek, N.; Kamal, N.; Shehata, D. Internet of Things Based Smart Automated Indoor Hydroponics and Aeroponics Greenhouse in Egypt. Ain Shams Eng. J. 2023, in press. [CrossRef]
  76. Calzita, C.R.; Jubilo, K.A.; Permejo, G.; Reas, R.; Baun, J.J.; Concepcion, R.; De Leon, J.A.; Bandala, A.; Mayol, A.P.; Vicerra, R.R.; et al. Intelligent Aeroponic System for Real-Time Control and Monitoring of Lactuca Sativa Production. In Proceedings of the 2023 17th International Conference on Ubiquitous Information Management and Communication (IMCOM), Seoul, Republic of Korea, 3–5 January 2023; pp. 1–7. [Google Scholar]
  77. Paponov, M.; Ziegler, J.; Paponov, I.A. Light Exposure of Roots in Aeroponics Enhances the Accumulation of Phytochemicals in Aboveground Parts of the Medicinal Plants Artemisia Annua and Hypericum Perforatum. Front. Plant Sci. 2023, 14, 1079656. [Google Scholar] [CrossRef]
  78. Guo, Y.; Gao, J.; Tunio, M.H.; Wang, L. Study on the Identification of Mildew Disease of Cuttings at the Base of Mulberry Cuttings by Aeroponics Rapid Propagation Based on a BP Neural Network. Agronomy 2022, 13, 106. [Google Scholar] [CrossRef]
  79. Totin, E.; Segnon, A.C.; Schut, M.; Affognon, H.; Zougmoré, R.B.; Rosenstock, T.; Thornton, P.K. Institutional Perspectives of Climate-Smart Agriculture: A Systematic Literature Review. Sustainability 2018, 10, 1990. [Google Scholar] [CrossRef]
  80. Mateus-Rodriguez, J.R.; de Haan, S.; Andrade-Piedra, J.L.; Maldonado, L.; Hareau, G.; Barker, I.; Chuquillanqui, C.; Otazú, V.; Frisancho, R.; Bastos, C.; et al. Technical and Economic Analysis of Aeroponics and Other Systems for Potato Mini-Tuber Production in Latin America. Am. J. Potato Res. 2013, 90, 357–368. [Google Scholar] [CrossRef]
  81. Fleming, L.; Sorenson, O. Technology as a Complex Adaptive System: Evidence from Patent Data. Res. Policy 2001, 30, 1019–1039. [Google Scholar] [CrossRef]
Agronomy 13 02517 g001
Figure 1. TAISA model.
Figure 1. TAISA model.
Agronomy 13 02517 g001
Agronomy 13 02517 g002
Figure 2. PRISMA flowchart of the study selection process.
Figure 2. PRISMA flowchart of the study selection process.
Agronomy 13 02517 g002
Agronomy 13 02517 g003
Figure 3. Distribution of the studies by country of the research.
Figure 3. Distribution of the studies by country of the research.
Agronomy 13 02517 g003
Agronomy 13 02517 g004
Figure 4. Distribution of the studies by publisher of the journal of publication.
Figure 4. Distribution of the studies by publisher of the journal of publication.
Agronomy 13 02517 g004
Agronomy 13 02517 g005
Figure 5. Distribution of the studies by year of publication.
Figure 5. Distribution of the studies by year of publication.
Agronomy 13 02517 g005
Agronomy 13 02517 g006
Figure 6. Level of technology integration in aeroponics.
Figure 6. Level of technology integration in aeroponics.
Agronomy 13 02517 g006
Table 1. Summary of the studies included in the review.
Table 1. Summary of the studies included in the review.
Study Authors (Year) [Cite]Cultivated ProductTechnology Level
1Idris and Sani (2012) [40]TuberAdvanced
2Reyes et al. (2012) [41]VegetableModerate
3Pathania et al. (2012) [42]TuberModerate
4Sani et al. (2016) [12]FruitAdvanced
5Pathania et al. (2016) [43]TuberAdvanced
6He (2017) [44]VegetableAdvanced
7Dannehl et al. (2017) [45]FruitLimited
8Montoya et al. (2017) [46]VegetableModerate
9Belista et al. (2018) [47]VegetableAdvanced
10Rahman et al. (2018) [48]VegetableModerate
11Chang et al. (2018) [49]VegetableModerate
12Jamshidi et al. (2019) [33]FruitBasic
13Klarin et al. (2019) [27]Fruit; vegetableAdvanced
14Hoyos et al. (2019) [50]Aromatic plantAdvanced
15Vera et al. (2019) [51]FlowerAdvanced
16Lakhiar et al. (2019) [52]VegetableBasic
17Argo et al. (2019) [53]VegetableAdvanced
18Lucero et al. (2020) [31]VegetableAdvanced
19Rahmad et al. (2020) [16]VegetableAdvanced
20Jamhari et al. (2020) [54]VegetableAdvanced
21Torres et al. (2020) [55]VegetableAdvanced
22Ríos et al. (2020) [30]VegetableAdvanced
23Cabascango et al. (2020) [56]TuberBasic
24Caya et al. (2021) [57]VegetableAdvanced
25Karuniawati et al. (2021) [58]VegetableModerate
26Kuncoro et al. (2021) [59]TuberModerate
27Devederkin et al. (2021) [25]TuberBasic
28Chowdhury et al. (2021) [60]VegetableModerate
29Narimani et al. (2021) [61]FlowerAdvanced
30Tang et al. (2021) [62]VegetableAdvanced
31Tunio et al. (2021) [63]VegetableBasic
32Rahman et al. (2021) [64]TuberAdvanced
33Riswandi et al. (2022) [65]VegetableAdvanced
34Martinea et al. (2022) [66]VegetableModerate
35Bolivar et al. (2022) [67]Fruit; vegetableModerate
36Estuita et al. (2022) [68]VegetableAdvanced
37Qi et al. (2022) [69]VegetableModerate
38Méndez et al. (2022) [70]VegetableAdvanced
39Yang et al. (2022) [9]VegetableModerate
40Mehmood et al. (2022) [71]FruitModerate
41Mohamed et al. (2022) [72]VegetableAdvanced
42Setiowati et al. (2022) [73]VegetableAdvanced
43Dhanasekar et al. (2023) [74]Vegetable; tuber; fruitAdvanced
44Sadek et al. (2023) [75]VegetableAdvanced
45Calzita et al. (2023) [76]VegetableAdvanced
46Paponov et al. (2023) [77]Aromatic plantModerate
47Guo et al. (2023) [78]FruitModerate
Table 2. Description of the categories of implemented technology.
Table 2. Description of the categories of implemented technology.
CategoryDescriptionExamplesNumber of Studies
Sensing
technology		Devices that detect and measure physical or environmental conditions, converting them into electrical signals for analysis.Temperature sensors, flow sensors, cameras, and microphones32
Industry 4.0Digital transformation of processes through advanced technologies based on smart automation.AI, IoT, machine learning, microcontrollers, robotics, artificial lighting.32
Dispenser technologySystems that automatically dispense liquids, solids, or gases in controlled quantities and precise locations.Sprayers, nebulizers, ultrasonic dispersion, and pumps.27
Renewable energyEnergy derived from naturally replenishing sources such as sunlight, wind, water, and geothermal heat, with minimal ecological impact.Biomass, fuel cells, solar panel, wind turbines, and hydropower.5
Table 3. Categories of the cultivated products.
Table 3. Categories of the cultivated products.
CategoryProduct ExamplesNumber of Studies
Vegetable
Tuber
Fruit
Flowers		Lettuce, spinach, and arugula
Potato, yucca, and yam
Tomato, mulberry, and strawberry Lily, sunflower, and anthurium		32
8
7
2
Aromatic plantCoriander, artemisia, and mint2
Table 4. Advantages of technology integration into aeroponics.
Table 4. Advantages of technology integration into aeroponics.
AdvantageDescriptionNumber of Studies
SustainabilityAeroponics is considered a sustainable farming method due to its efficient use of resources. Technology can further enhance sustainability by optimizing resource consumption, such as water and nutrients. Advanced monitoring systems can detect and address any inefficiencies, minimizing waste and maximizing resource utilization.25
Time
efficiency		Technology in aeroponics allows for precise control over various environmental factors, which helps plants grow faster, leading to shorter crop cycles and increased productivity compared to traditional farming methods.21
Increased
Production		Technology has a substantial impact on increasing production in aeroponics by optimizing various aspects of plant growth and resource management. For example, collecting and analyzing data on plant growth, nutrient levels, and environmental conditions can yield insights that facilitate the development of effective and sustainable growth strategies.15
Clean
production		The controlled environment of aeroponic systems can lead to fewer pest and disease problems. This can reduce the need for chemical pesticides and herbicides, leading to cleaner and healthier products.14
Cost-effectiveInvestment in technology for aeroponics results in long-term cost savings. By eliminating the need for soil and reducing water usage, aeroponics lower production costs over time. Additionally, the high yield potential and faster crop cycles lead to increased profitability.11
Space
Efficiency		Technology allows for the designing and constructing of modular growing structures tailored to the available space. These structures can be optimized for efficient space utilization while accommodating the specific needs of plants.9
Product sizeTechnology allows real-time monitoring of environmental factors such as temperature, humidity, CO2 levels, and light intensity. Automated control systems can adjust these parameters to create the ideal growing conditions, maximizing plant growth and yield.8
Continuous productionTechnology helps aeroponic systems operate continuously, allowing for year-round production. By providing a controlled environment, plants can be grown regardless of external seasonal variations, ensuring a steady and reliable supply of produce.6
Table 5. Disadvantages of technology integration into aeroponics.
Table 5. Disadvantages of technology integration into aeroponics.
DisadvantageDescriptionNumber of Studies
Technical
Complexity		High-tech systems require a certain level of technical expertise to set up, operate, and troubleshoot. Growers must understand the technology involved to ensure proper functioning and prevent potential issues.6
Power
Dependency		Advanced technology relies heavily on a stable and reliable power supply. If there are power outages or disruptions, it could impact the functioning of automated systems and disrupt plant growth.3
Setup CostImplementing and maintaining advanced technology in aeroponic systems can be expensive. The initial investment for high-tech equipment, sensors, automation systems, and energy sources can be a significant barrier, especially for small-scale growers. 1
Maintenance and
Monitoring		High-tech systems require regular maintenance to ensure they function optimally. Downtime for maintenance and repairs could interrupt production schedules and lead to decreased yields.1
Learning CurveIntroducing technology into an aeroponic setup requires a learning curve. Transitioning to technology-driven systems involves a learning curve for growers. Adapting to new methods, understanding software interfaces, and troubleshooting technical issues can take time and effort.1
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Garzón, J.; Montes, L.; Garzón, J.; Lampropoulos, G. Systematic Review of Technology in Aeroponics: Introducing the Technology Adoption and Integration in Sustainable Agriculture Model. Agronomy 2023, 13, 2517. https://doi.org/10.3390/agronomy13102517

AMA Style

Garzón J, Montes L, Garzón J, Lampropoulos G. Systematic Review of Technology in Aeroponics: Introducing the Technology Adoption and Integration in Sustainable Agriculture Model. Agronomy. 2023; 13(10):2517. https://doi.org/10.3390/agronomy13102517

Chicago/Turabian Style

Garzón, Juan, Luis Montes, Jorge Garzón, and Georgios Lampropoulos. 2023. "Systematic Review of Technology in Aeroponics: Introducing the Technology Adoption and Integration in Sustainable Agriculture Model" Agronomy 13, no. 10: 2517. https://doi.org/10.3390/agronomy13102517

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop