Abstract
The increase in global population, expected daunting energy demands, and scarcity of resources has driven the search for new sustainable sources of materials, energy, and chemicals. In this context, biomass valorization has emerged as a promising technology to obtain high-value products in recent years. This research focuses on the valorization of rice production waste including straw, husk, and bran, due to their abundance, underutilization, and potential in generating a wide range of valuable products such as biofuels and materials. A systematic review was conducted regarding the valorization of rice production waste. The characteristics of biomass obtained from post-harvest rice production were explored, as well as the primary products derived from each of the discussed biomass feedstocks. Furthermore, the economic viability of the obtained products in their respective fields of application was evaluated, providing a solid foundation for future research and industrial applications. Different rice waste materials studied hold significant potential to obtain high‑value products including silica, adsorbent materials, biofuels, and various bioactive compounds.
Download PDF
Full Article
Rice Waste Feedstocks: A Review of Alternatives for their Conversion into High-Value Added Products
Kelvin A. Sanoja-López, Nikolt S. Loor-Molina, and Rafael Luque *
The increase in global population, expected daunting energy demands, and scarcity of resources has driven the search for new sustainable sources of materials, energy, and chemicals. In this context, biomass valorization has emerged as a promising technology to obtain high-value products in recent years. This research focuses on the valorization of rice production waste including straw, husk, and bran, due to their abundance, underutilization, and potential in generating a wide range of valuable products such as biofuels and materials. A systematic review was conducted regarding the valorization of rice production waste. The characteristics of biomass obtained from post-harvest rice production were explored, as well as the primary products derived from each of the discussed biomass feedstocks. Furthermore, the economic viability of the obtained products in their respective fields of application was evaluated, providing a solid foundation for future research and industrial applications. Different rice waste materials studied hold significant potential to obtain high‑value products including silica, adsorbent materials, biofuels, and various bioactive compounds.
DOI: 10.15376/biores.19.1.Sanoja-Lopez
Keywords: Biomass; Rice husk; Rice bran; Rice straw; Agricultural residues; Revalorization; Economic analysis
Contact information: Universidad ECOTEC, Km. 13.5 Samborondón, Samborondón, EC092302, Ecuador; *Corresponding authors: ksanoja@ecotec.edu.ec; nikoltloor@gmail.com; rluque@ecotec.edu.ec
INTRODUCTION
The increase in global population has raised significant concerns about the availability of various products used by our society (Su and Xu 2022). Consequently, the scientific community is continuously exploring alternatives to replace currently utilized natural resources. Among these research efforts, biomass valorization to obtain high-value products stands out as one of the most promising approaches with potential to replace certain current end products. Biomass is defined as any organic material of plant or animal origin that can be used as an energy source or converted into useful chemicals or materials. Its key features include the ability to store solar energy through photosynthesis, its availability in various forms, and its potential to reduce greenhouse gas emissions as compared to fossil fuels (Núñez-Delgado et al. 2022; Stančin et al. 2023).
Numerous biomass feedstocks with interesting characteristics have been studied over the decades, demonstrating the potential to be converted into valuable products such as biofuels, biogas, high-purity chemicals, cosmetics, among others (Dessie et al. 2023; Drobniak et al. 2023). However, one biomass that has garnered significant attention within the scientific community is derived from waste products in rice production (Fig. 1). Due to its abundance and availability in many regions worldwide (economically and environmentally attractive option), rice waste has emerged as a promising alternative for the production of value-added products. It is estimated that approximately 1.2 billion tons of rice residues are generated annually worldwide post-harvest (Santana Costa and Paranhos 2018; Medina Litardo et al. 2022). The residues generated during rice production can be classified into three main types: straw, husk, and bran, each with distinct characteristics and potential for the production of different materials of interest. In general, they can serve as a source of bioenergy, raw materials for bioplastics production, construction materials, organic fertilizers, and high-value compounds, such as silica (Overturf et al. 2020).
Fig. 1. Rice production waste generated during the process
Recent publications including those by Gupte et al. (2022) and Illankoon et al. (2023), have demonstrated the feasibility of using these types of residues to obtain high-value products. These studies covered various approaches found in literature, highlighting the potential of these biomass feedstocks. Therefore, the aim of this present research is to compile and analyze relevant information on the utilization of rice production residues. To achieve this objective, the main products derived from the three primary biomass sources mentioned will be described. The feasibility of these products will be analyzed based on the relationship between the obtained product and its market price, aiming to discuss which of these products holds prospects for higher profitability. This analysis will pave the way for future research to enhance our understanding of the products derived from rice production waste and their potential industrial applications, avoiding potential gaps in knowledge.
Rice Straw (RS)
Rice straw (RS) possesses interesting characteristics that allow it to be utilized in various technologies, such as raw material for composting, paper production, energy generation, mushroom cultivation, gasification, pyrolysis, construction material, pellet production, silica extraction, feed for ruminants, biofuel production, adsorbent, and biochar production (Zheng et al. 2023). Its chemical composition typically consists of approximately 35% to 45% cellulose, 25% to 35% hemicellulose, 15% to 25% lignin, 5% to 20% silica, 15% to 20% ash, and 3% to 8% proteins and fats (Tian et al. 2020). As a result, numerous studies have been conducted on these biomasses to enhance their profitability and expand their field of utility for waste products. In Fig. 2, the general production of two high-value products from rice straw can be observed.
Biofuels
Numerous research efforts have been directed towards RS for biocompound production, aiming to find cost-effective alternatives to traditional fuels and to utilize this biomass that is often burned (Michailos and Webb 2020). However, such endeavors can yield limited returns based on process profitability. An alternative approach to address these challenges involves biomass modification for biocompound production. In this regard, Saini et al. (2023) proposed modifications to RS biomass to produce bioethanol. They achieved an impressive increase in yield (>70%), reaching up to 7.28 g*L-1 of bioethanol. Their method involved reducing lignin content and enhancing available carbohydrates, followed by subjecting the biomass to a cellulase cocktail to facilitate bioethanol production. Another avenue for biocompound production from RS biomass involves rice modification. Hu et al. (2023) focused on a mutant rice variety (cesa7), conducting a recalcitrance study of lignocellulose to enhance accessibility and biomass porosity. Consequently, they observed heightened bioethanol production compared to a wild-type variant subjected to the same process. The most intriguing finding, however, emerged during biomass saccharification, achieving hexose contents exceeding 96%. This allowed for application in the production of highly porous aerogels with a significant surface area, rendering the process not only economically viable but also enabling the utilization of these biomasses in various combined processes.
Similarly, RS has been involved in biodiesel production processes. This involves its modification with other materials such as graphene oxide as catalysts using a liquefaction process with supercritical ethanol for the conversion of oils into bioethanol. The results demonstrated the efficacy of such modified biomass for biofuel production. The optimal parameters used during the process led to a 33.4% conversion of the raw material into biofuel, all at a temperature of 320 °C and a catalyst weight percentage of 5% (Echaroj et al. 2021). Similar research focusing on biodiesel production was conducted by Saetiao et al. (2023). In this study, the authors converted palm oil using an RS ash support with varying amounts of calcium oxide (25 to 35% by weight) and calcination temperatures (600 to 800 °C) to produce biodiesel. The results of this study achieved a yield of 96.5% conversion to biofuel under optimal working conditions of 4.87% by weight of catalyst (35% by weight of calcium oxide treated at 600 °C), 175 minutes of reaction time, 65°C reaction temperature, and a methanol:oil ratio of 9.34:1. These findings demonstrate that different approaches to biomass can contribute to the production of biofuels using various raw materials. Despite the continuous evolution of RS conversion into biofuels, its high oxygen content limits its commercial application. However, proper pretreatment can help address current issues such as the treatment of waste oils from petroleum industries. Xu et al. (2022) proposed an innovative solution for treating petroleum sludge (OS) using RS to enhance the production of different hydrocarbons. In this process, RS underwent torrefaction and subsequent co-pyrolysis with OS. As a result, these processes synergistically improved gas production, significantly enhancing the formation of alkanes and olefins while reducing the generation of oxygenated compounds in the oil. This led to improved oil quality by increasing hydrocarbon concentration at the expense of oxygenated compounds.
Bio-Gas
Despite the significant advances achieved in biomass modification and pretreatment for its lignocellulosic content, these processes come with certain drawbacks that diminish process profitability. As a result, new research endeavors have emerged to address these issues. An example of this is the utilization of N2, CO2, and O2 nanobubbles, which were employed as soaking agents and catalysts to enhance anaerobic digestion performance. This led to a 21.4% increase in methane production compared to pristine RS, with a maximum production of 313.9 ml*g-1 VS (volatile solids). Nanobubbles demonstrated a promising alternative for two-step biogas production processes (Wang et al. 2023a). Similarly, other approaches for this biomass in biocompounds production have been proposed. The production of clean hydrogen was proposed by Pan et al. (2023). In this study, wood chips and RS were subjected to an innovative multi-generation energy system based on co-firing with an air electrolysis membrane exchange agent, a supercritical carbon dioxide Brayton cycle, and a humidification-dehumidification system. Results showed that hydrogen production from RS reached 1.96 kg*h-1 with a CO2 production rate of 10.41 g*kWh-1. The cited research validated the potential use of a system ensemble for energy production. The obtained results underscore the capacity of this biomass to contribute to future energy generation.
Combining different processes has demonstrated a significant improvement in the yield of various biofuels. Dong et al. (2023) proposed the feasibility of a study for the continuous production of a mixture of CH4 and H2 (denoted as biohythane) from RS using an anaerobic bioreactor integrated under thermophilic conditions. The results showed yields of up to 612.5 ml*g-1 VS with a composition of approximately 17% H2 and 83% CH4. The viability of this study is highlighted by biohythane production rates, as this process significantly increases the production of both gases by up to 13% more than if the production processes are carried out separately. Furthermore, the utilization of energy employed increases by up to 167% in terms of conversion of the target products, making the study an intriguing perspective for RS utilization.
Fig. 2. General scheme for obtaining biofuels and biogas from rice straw
Materials
The use of RS in reclaimed soils increases nutrient content and potential crop production. Although this technology has not yet been developed to provide clear operational concepts, several studies have demonstrated that incorporating these biomass feedstocks can degrade various contaminants present in the soil. Tian et al. (2023) conducted research to measure the emergence of antibiotic resistance in soils contaminated with norfloxacin, to which RS, biocarbon and ashes were added. The results of this study showed an increase in nutrient content in the soil upon the addition of RS as compared to the control soil, as well as a significant increase in the resistance attributed to straw and biocarbon. This soil modification allowed for the degradation of norfloxacin, while ash content inhibited drug degradation. However, the authors suggested optimizing the process to enhance biodegradation and more effectively inhibit antibiotic resistance in the soils. Narzary et al. (2023) pointed out that producing briquettes from rice straw can be a complex task due to the properties of this biomass despite the favourable calorific value. In this regard, they used binders with RS in a carbonization drum to alter the physical properties of this carbonized biomass. The results showed that density, tear resistance, and calorific value increased compared to biomass without binders, allowing for the formation of stable briquettes with improved characteristics. These briquettes, with respect to those made from paper, tars, or starch, require less energy for production, indicating a potential for burning this material and providing an alternative energy source. The proposed concept demonstrate that various carbonaceous materials can be obtained from RS depending on the methodology. This has also been evidenced in Wang et al. (2023), where modified biocarbon with Ca(OH)2 was synthesized and employed to remove methylene blue from contaminated water. The morphological characterization of the material and its physical characteristics (Fig. 3) demonstrated the presence of carbon and oxygen within the RS matrix, as well as the presence of functional groups OH, CO, Si-O that can be modified with other compounds, along with a porous structure that allows for effective material functionalization. All of this resulted in an adsorption capacity of 333.3 mg*g-1.
Fig. 3. Morphological and physical characterization of biochar (RB) from rice straw: a) FTIR, b) XRD, c) SEM. Reproduced by permission from Elsevier, Wang et al. 2023b.
Hydrogels were also synthesized from RS and subsequently applied to sandy and calcareous soils at a ratio of 0.2% by weight. The results showed that the application of these hydrogels to soils improves their hydrophysical, physicochemical, and biological properties, being an excellent addition during drought times, as it enables optimal conditions for crop growth with a reduced volume of irrigation (Solieman et al. 2023). Bangar et al. (2023) presents a different approach to the applications of RS, where their research focuses on developing biodegradable packaging materials from this biomass. This approach is promising, as it allows for the conversion of these waste materials into packaging materials, offering an alternative to traditional plastic waste and addressing the associated environmental issues. The researchers extracted cellulose using unconventional methods such as ultrasonication or microwave irradiation, and then modified the properties of this cellulose to form nanostructures, ultimately creating bioplastics. The results of this study indicated that the material’s properties make it suitable for various plastic-related applications such as food packaging, biodegradable containers, edible films/coatings, active packaging, and more. This innovative and sustainable approach provides a new solution to the plastic waste problem. Similarly, biomass modification has demonstrated increased yields and applicability in various fields. Saini et al. (2023) proposed modifications aimed at delignifying the biomass and increasing the percentage of available carbohydrates. This modified biomass was subsequently subjected to a cellulase cocktail for application in bioethanol production. Moreover, the lignin extracted from the pretreatment streams exhibited the ability to act as a biopesticide and biofertilizer. It showed promising results against H. armigera larvae, implying that the findings from this research offer a promising strategy for reutilizing pretreatment streams, making processes more cost-effective and expanding their application.
Rice Husk (RH)
Rice husk has been the subject of various uses and applications due to its properties. Among the rice production residues, it is the most studied, as studies have reported its use as a substrate for edible mushroom cultivation, livestock feed, manufacturing of ceramic and refractory materials, as well as production of active silica, among other value-added compounds (Yaghoubi et al. 2019). Several studies reported various characterization experiments for rice husk, which have allowed researchers to identify its main components. Research results including those from Morales-Paredes et al. (2023) and Zambrano-Intriago et al. (2022) pointed to porous structures and irregular fragments with holes for rice husk as determined using SEM. EDX analyses also confirmed a high presence of silicon, carbon and oxygen. Furthermore, FTIR spectra revealed the presence of various functional groups such as OH, COOH, Si-OH, CHO, and C=O.
This makes rice husk applicable in various fields, with a strong emphasis on adsorbent materials. Although the chemical composition of rice husk may vary depending on the region where it is produced, in general, it consists of 25 to 35% cellulose, 18 to 21% hemicellulose, 26 to 31% lignin, and 15 to 25% silica (Rajamani et al. 2023). Despite the great potential for various applications of rice husk, determining the most economically profitable or beneficial uses is of significant importance.
Silica
Silica is a compound with numerous applications in the field of chemistry, owing to its versatility and unique physicochemical properties. However, it is not freely available in nature, and conventional processes for obtaining it are considered unsustainable due to the involved procedures (Villota-Enríquez and Rodríguez-Páez 2023). Hence, discovering new methods and sources that require fewer treatments for its extraction could be an intriguing proposition. In this context, research has been conducted to obtain silica from biomass derived from RH. Shrestha et al. (2023) synthesized biogenic silica nanoparticles from rice husk ash through a process involving leaching with hydrochloric acid, followed by pyrolysis at 600 °C, and a sol-gel method. The sol-gel method is widely employed to create inorganic materials and thin films. In this method, a solution with inorganic or metallic compounds is treated with a precursor solution to form a colloidal dispersion. These dispersions are then hydrolyzed and condensed with the metal precursors to form inorganic polymers, allowing for the synthesis of materials and thin films at lower temperatures as compared to solid-state methods (Innocenzi 2023). The results of this study demonstrated highly pure amorphous silica, containing approximately 86.5% of heterogeneous amorphous silica nanoparticles with particle sizes around 50 to 60 nm, mesopores ranging from 10 to 30 nm, and the presence of Si-OH polar bonds. This material was employed as a chromatography column filler for the separation of ortho and para-nitroanilines, as well as ortho and para-nitrophenols, effectively accomplishing the task with a mobile phase composition of 80% hexane and 20% ethyl acetate, as shown in Fig. 4.
Fig. 4. Silica-filled chromatographic column for ortho and para-nitrophenol separation
These findings illustrate that waste materials can be transformed into valuable products, such as a chromatography column stationary phase. A similar study was conducted to obtain silica from rice husk ash using various alkaline methods (KOH and NaOH) with sol-gel precipitation. The outcome yielded irregularly shaped amorphous silica particles with an average particle size ranging from 10 to 50 µm, depending on the type and concentration of alkali used. Given the substantial amount of ash resulting from combustion, this study enables the transformation of such waste into a highly value product (Aprilia et al. 2023).
Research such as that conducted by Haider et al. (2022) demonstrated the applicability of such materials. In that study, silica was derived from treating RH with sulfuric acid using various calcination and combustion processes. The resulting silica was then employed for the removal of dyes (methylene blue). The findings of this investigation revealed that the obtained silica was amorphous and mesoporous with purity exceeding 94%, and a yield conversion of over 72% without the need for additional calcination. These characteristics allowed for the adsorption of 107 mg of methylene blue per gram of silica in one hour of adsorption. This not only presents an environmentally friendly approach for the reuse of waste generated from rice husk but also offers a solution for treating dyes present in water. Due to the promising results yielded by the extraction of silica from RH, various approaches have been developed to obtain such silica. Franco et al. (2018) designed a method for obtaining high-purity silica (>95%) using a mechanochemical/microwave approach. They employed a ball mill in which RH was combined with an acidic solution, followed by microwave treatment to obtain silica. This approach not only facilitated the extraction of high-purity silica but also allowed for the mechanochemical incorporation of metals onto the silica surface to create nanocatalysts. These nanocatalysts exhibited excellent catalytic activities, enabling the selective quantification of monoalkylated products. Once again, this showcases the significant value of this biomass and its potential application as supports for nanocatalyst development.
Noori et al. (2023) coupled zirconia with the silica obtained from RH, which was used as a catalyst for carbon-carbon bond formation through the Heck reaction under solar irradiation. In this study, they first synthesized silica nanoparticles and then modified the surface through trimethoxysilane grafting. Thiol-ene free radicals were subsequently reacted with zirconia alkenes using azobisisobutyronitrile as an initiator. The catalytic capacity of the nanocomposite was tested in the arylization of olefins under concentrated solar irradiation and conventional thermal conditions. The results of this research demonstrated that utilizing solar irradiation for the arylization of olefins using modified silica as a catalyst offers a more efficient alternative route due to its high energy savings and achieved yield. Therefore, this investigation presented a viable strategy through the utilization of a renewable energy source as an irradiation method, a non-volatile solvent, a straightforward methodology, catalyst recovery, and good yields within short reaction times.
Composite/Adsorptive Materials
Due to the mentioned properties of RH, its use as a base for the development of adsorbents can result in new materials with unique and enhanced properties. Fernández-Andrade et al. (2023), through an in-situ growth process, designed a hybrid (MOF@Biomass) using rice husk and microwave-synthesized Mil-53(AL) particles. This process involved pre-treating the RH, adsorbing Al onto RH, and an in-situ growth reaction with the MOF. This led to a significant size increase up to 400 times compared to Mil-53(AL) crystals and utilization of the product in the removal of oxytetracycline at 139 mg*g-1, diclofenac at 93 mg*g-1, and glyphosate at 162 mg*g-1, achieving removal rates of 91%, 80%, and 97%, respectively. This demonstrated that MIL-53(AL) maintained its contaminant-degrading properties after hybridization compared to pristine MOF adsorption. Similarly, the development of Fe3O4 nanostructures using rice husk was achieved through a microwave-assisted combustion process. Analysis of the material revealed polycrystalline Fe3O4 structures with a size of 5 to 10 nm decorated with amorphous SiO2 nano-spheres with a size of 50 nm, resulting in the obtained material Fe3O4@SiO2. This transformed the non-magnetic material into a ferromagnetic state, which is not inherent to Fe3O4. The product had a saturation magnetization of 45 emu*g-1. Moreover, using 100 mg of this adsorbent for 20 minutes could remove over 90% of Hg2+ ions at a concentration of 100 mg*L-1. This demonstrates the potential of such RH-based materials for the removal of contaminants from water. However, the recovery of the adsorbent after treatment remains challenging, and different approaches may be needed. This material holds promise for cost-effective treatment of waters containing heavy metals. (Araichimani et al. 2022)
Various studies for the removal of emerging and hazardous contaminants using RH-modified adsorbents have been proposed, with highly promising results. Wang et al. (2022) developed a CO2 adsorbent by impregnating KOH onto rice husk-based activated carbon (DKOH-AC), showing improved physicochemical characteristics of the material. The adsorption process was shown to be controlled by intraparticle diffusion. Adsorption tests in a chamber demonstrated promising results for the rapid reduction of CO2 from 2000 ppm to less than 1000 ppm in approximately 100 minutes, with good regenerability and reusability. Similarly, Yang et al. (2022) developed an adsorbent (RHB-ZnO3) based on rice husk-derived biochar and ZnO nanoparticles for batch adsorption of Reactive Red 24 in an aqueous solution. The material’s surface area was 13.84 m2*g-1, with an adsorption capacity of 174 mg per gram of adsorbent in 60 minutes, which was 4 times higher than the results obtained with ZnO particles. In addition, the low ZnO requirement of 3% (w/w) demonstrated the feasibility of RHB-ZnO3 synthesis, considering the achieved yields during the research and reusability after multiple absorption-desorption cycles. A similar approach was used to develop multi-walled carbon nanotubes (MWCNTs) from rice husk and study their different functionalized forms with HNO3/H2SO4 (MWCNT), NaOCl (MWCNT), and H2O2 (MWCNT), which were subsequently employed in the adsorption of benzene and toluene. The results of this research demonstrated efficient integration of functional groups into carbon nanotubes, along with good adsorption capacities for the studied aromatic compounds. MWCNTs exhibited better adsorption capacity, while MWCNTs with functionalization by H2O2 represented the lowest capacity (Le et al. 2023). Therefore, it is evident that the use of this biomass in the production of different adsorptive materials presents a significant opportunity for the valorization of rice husk waste generated during rice production.
Rice Bran (RB)
Rice bran (RB) is the final product of the outer covering of rice after dehusking and milling, representing approximately 9% of the total weight during rice production. Despite this, due to its significant nutritional value, bioactive compounds, and substantial health benefits, its utilization can be profitable (Manzoor et al. 2023). In their research, Hong and Wang (2017) conducted a characterization of the morphological and physical properties of rice bran. This allowed them to demonstrate that this biomass has a cellular fiber structure with hexagonal or pentagonal shapes and lacks an appreciable porous structure. EDX analysis also showed the presence of magnetic particles, and functional groups NH and OH were observed through FTIR analysis. These results show that this type of biomass has favorable properties for various applications. Additionally, its chemical composition consists of 15% to 25% fats, 10% to 15% proteins, 10% to 20% dietary fiber, 45% to 60% carbohydrates, and 6% to 8% ash, in addition to vitamins and minerals. This has led to its use in various industries, including oil production, nutritional supplements, cosmetics, pharmaceuticals, fuels, among others. (Wancura et al. 2023)
Bioactives
Rice bran (RB) is highly nutritious and rich in bioactive compounds such as phenols with antioxidant activities. However, developing a cost-effective extraction method using solvents is crucial for its practical application. Bunmusik et al. (2023) optimized the ultrasound-assisted extraction process of bioactives from pigmented rice using solvents. The extraction parameters included temperatures of 20 to 60 °C, time intervals of 20 to 40 minutes, and a sample-solvent ratio of 1:10 to 1:30 mg*mL-1. The results demonstrated that extraction conditions significantly affected bioactive compounds, as evidenced by the total content of anthocyanins, phenols, flavonoids, and antioxidant activities measured by DPPH (1,1-diphenyl-2-picrylhydrazyl) radical scavenging capacity. Optimal extraction conditions were achieved using 60% (v/v) aqueous methanol with 0.1% citric acid as the solvent, applying ultrasound at 30 °C for 30 minutes with a 1:20 mg*mL-1 sample-solvent ratio. These parameters minimize the cost-effective extraction of phytochemical bioactives and their potential use in various applications. However, solvent recovery can pose challenges. To address this, Moirangthem et al. (2021) conducted a similar investigation for anthocyanin extraction from RB. In this case, supercritical water-assisted microwave extraction was employed at 90 °C for 5 minutes. The obtained results demonstrated an extraction efficiency of 85.8% for anthocyanins, surpassing yields achieved by traditional solvent-based methods for rice bran bioactive extraction. Moreover, the potential to inhibit colorectal cell formation and the lack of cytotoxicity in Jurkat cell lines make this approach applicable in the field of biomedicine.
The combination of rice bran (RB) with other materials has also been studied in the conversion of RB into value-added products. The development of a controlled release system for bioactive graphene oxide, tailored to the target environment, was investigated using simulated intestinal fluid (SIF) and a surfactant solution. The material was prepared using lipid nanoparticles, obtained from nanostructured lipids (NLC) encapsulating bioactive γ-oryzanol (GO) from RB oil. The fabrication involved a hot homogenization process using sunflower oil and stearic acid as the encapsulating lipid matrix, RB phospholipids, and polysorbate 80 (Tween 80) as a stabilizer. The fabricated GO-NLC demonstrated a high encapsulation efficiency of 95%, with spherical morphology and an average particle diameter of 143 nm. As a result, the material exhibited an 18-fold increase in free radical scavenging activity, a 200-fold increase in anti-inflammatory activity, and a twofold increase in hyaluronidase inhibition. Furthermore, this characteristic was preserved by over 90% after 60 days under light and ambient temperature conditions. The obtained results indicate that this material functions as a rapid-triggered release system, as well as a colloidal nanocarrier for prolonged GO release (Villar et al. 2022).
Another approach to utilizing this biomass was proposed by Sapna and Jayadeep (2022). They suggested the optimal combination of cellulolytic-xylanolytic enzymes (CXC) with RB to enhance the release of nutraceuticals and bioactivities. This was achieved by using enzyme ratios of 1.5:3 (CXC1), 3:2 (CXC2), and 4.5:1 (CXC3) per 2g of RB. This led to a significant increase in ferulic acid in soluble phenols by 253%, p-coumaric acid in combined phenols by 66%, and γ-oryzanol fractions ranging from 41% to 743% for the CXC2 assay. These material properties exhibited higher ferric reducing power and DPPH (2,2-diphenyl-1-picrylhydrazyl) radical scavenging activity, nitric oxide and superoxide anion elimination, inhibition of human LDL oxidation, and hydroxyl radical scavenging. As a result, this combination improved the nutraceutical profile and antioxidant potential of RB. This opens up possibilities for utilizing the characteristics present in rice bran within the fields of phytochemistry and biotechnology, with various perspectives and applications.
Li et al. (2023) developed an intelligent film for monitoring various parameters of interest in the food industry. They investigated the effect of incorporating barley prolamins (HBP) on the properties of barley β-glucan films (HBBG), aiming to enhance the anthocyanins of black rice bran (BRA). The addition of HBP reduced the water vapor and oxygen permeability of the HBBG film. It also improved mechanical, thermal, optical properties, and water contact angle. This allowed for rapid color changes in the films (HBBG/HBP/BRA) observed under different pH solutions and ammonia atmosphere due to the anthocyanins in BRA. Moreover, it enhanced the stability of anthocyanins through hydrogen bonds formed by the materials used. These results enabled the monitoring of pork freshness at 4 ◦C and demonstrated the potential of using these films in packaging materials to extend the shelf life of foods. Additionally, these films showed high sensitivity to ammonia and significant color changes in a pH range from 2 to 13, making them suitable for monitoring food freshness.
Bioplastics
The high content of starch and proteins present in rice bran allows its use as a macromolecule in bioplastic production. This abundant resource from the agri-food industry has garnered interest in bioplastic production due to its abundance and low cost. Bioplastics are made from biopolymers, which can be found in residues generated by agricultural industries because of their protein, lipid, and polysaccharide content. Among the various sources used for bioplastic production, rice bran has emerged as a great option for obtaining bioplastics.
In this context, Alonso-González et al. (2021) developed bioplastics from a homogeneous mixture of RB, glycerol, and water, which was subsequently processed through injection molding. During this research, different mixtures were evaluated, yielding varying rheological behaviors during and after drying. However, the ratio of 55% RB and 45% plasticizing mixture (33% glycerol and water) at 80 °C exhibited the best results during experimentation, as the other mixtures had to undergo a drying process before injection molding. Moreover, it was demonstrated that temperature is a highly significant factor as it aids in starch plasticization and thus affects its properties. Nevertheless, even though higher temperatures result in improved mechanical characteristics compared to lower temperatures, they present poor physical integrity during water immersion due to stable properties generated at high temperatures, which has been primarily attributed to the loss of soluble matter. For this reason, developing a technique that enables greater medium stability will be essential for producing bioplastics with improved characteristics.
In one study, glycerol was mixed with rice bran and used to analyze the effect of three different molding temperatures (100, 130, and 150 °C) on the mechanical properties, microstructure, and water adsorption capacity of the final matrices. The results indicate that the combination of RB with glycerol leads to the disruption of hydrogen bonds, resulting in increased processability and enabling thermomechanical methods to be used in the fabrication of desired bioplastics. Additionally, it was demonstrated that although the Young’s modulus increases proportionally with the rise in temperature during injection molding, leading to a more compact structure, the water adsorption capacity decreases (Alonso-Gonzalez et al. 2021)
Alonso-González et al. (2022), in a preliminary investigation, focused on bioplastic production from rice bran after treating the raw material with water and different proportions of glycerol and sorbitol. The researchers aimed to deeply incorporate plasticizers by subjecting starches to shear forces at high temperatures and excess water (gelatinization). During this research, results obtained using different plasticizers with water were compared. The outcomes showed that while water is necessary for producing stiffer specimens, an excess of water hinders the injection molding process, leading to brittle bioplastics. The 2:1 glycerol/water ratio was the highest that could be processed, while the sorbitol/water mixture could achieve higher proportions of up to 4:1, demonstrating sorbitol as a better plasticizer. This illustrates the correct selection of plasticizers and water, producing stiffer bioplastics with viscoelastic modulus, maximum stress, Young’s modulus, increased elasticity, and water absorption capacities. Additionally, the effectiveness of RB for bioplastic production is showcased. Despite the results obtained from these studies, the combination of various waste sources, such as rice bran as a biopolymeric material, and chitin found in shrimp shells, holds significant potential for the production of bioplastics. Chitin can be transformed into chitin nanowhiskers (CNW), which can reinforce the biopolymeric materials present in rice bran. Therefore, to enhance the starch properties, an investigation was conducted using CNW from shrimp shell waste along with the addition of glycerol as a plasticizer. Figure 5 shows a scheme of the combination of these wastes and their application in the production of bioplastics. The results of this study suggest that the combination of these two waste materials emerges as a promising alternative for bioplastics production. The bioplastics obtained during the research exhibited outstanding degradation properties in soil burial tests, with a degradation of 50.7% in sandy soil, 86.2% in humus, and 100% in compost over a period of 15 days. Despite this, mechanical properties such as tensile strength and water adsorption, while doubling compared to bioplastics produced solely from rice bran, still fell below standard parameters. This demonstrates that combining different waste materials can yield bioplastics with improved alternatives, and it is anticipated that future research will lead to process enhancements and better outcomes (Setiawan et al. 2022).
Fig. 5. Production of bioplastics from rice bran polymers and chitin nanowhiskers and their application fields
Another approach was proposed by Adnan et al. (2023), where they obtained polyhydroxybutyrate (PHB), a macromolecule produced by bacteria as part of their metabolism, using various agricultural residues as nutrient sources, including rice bran. In the study, ten bacterial strains were evaluated, and the B. flexus strain showed the highest PHB production after 48 hours of incubation using glucose as a carbon source and peptone as a nitrogen source. This was achieved through response surface methodology (RSM) using a Box-Behnken design (BBD). The results indicate that this methodology can be highly effective in optimizing PHB production yield, with optimal conditions leading to up to 1.3 times increased polymer production compared to non-optimized incubation methods, significantly reducing bacterial production costs. These macromolecules can be considered an alternative for bioplastics production due to their rapid degradation properties under natural environmental conditions. Moreover, the process is scalable for large-scale bioplastics production, with applications in various industrial sectors such as packaging, agriculture, and medicine. Therefore, improving process conditions and investigating PHB production in fermenters could be a promising alternative in the field of bioplastics, meeting the growing demand for environmentally-friendly plastics.
Economic Analysis of the Valorization of Rice Production Residues
Conducting a comprehensive economic analysis of rice waste for obtaining value-added products is a complex task given the properties and applications of each of the waste products generated during rice production. Additionally, the increasing research and existing methods for obtaining each product discussed in this work affect not only the economic performance of the different products but also their application in other industrial fields. Other waste from corn, sugarcane, or wood industry waste has also demonstrated significant potential in waste valorization. However, making a comparison with other waste can be a complex task. It is estimated that only 25% of all generated waste is recycled/valorized, while the rest is dumped in landfills or burned (Kee et al. 2022). Annually, 1102 million tons of corn crops (Aghaei et al. 2022), over 2000 million tons of sugarcane (Torres de Sande et al. 2021), and more than 1000 million tons of wood waste are generated (Xu et al. 2023).
Numerous research studies have shown the applicability of these biomass types for the production of (bio)materials, chemicals, and fuels. For example, Collard et al. (2022) obtained high-quality liquid fuel and gases from pine wood waste, while Xu et al. (2023) obtained modified bitumen with good mechanical properties and a porous structure through hydrothermal carbonization of wood. Zheng et al. (2022) generated high yields of H2 from various straws, and Vaštyl et al. (2022) obtained gases, biochar, and oil through fast pyrolysis of cocoa pod husks and used tires. Moreover, Sica et al. (2023) achieved high ethanol yields from sugarcane waste. Each of these approaches demonstrates that other biomass feedstocks can also lead to high-value-added products. However, despite the similarities in the amounts of waste produced between rice production and other biomass sources, the content and diversification of rice waste allow for a wider range of applications and products such as the extraction of silica or bran during processing (Alan and Köker 2023; Torres-Mayanga et al. 2019). Additionally, other unexplored approaches in this contribution such as the use of carbonaceous materials as supercapacitor electrode materials (Ray et al. 2023; Wang et al. 2023), anode materials for lithium-ion batteries (Wu et al. 2022; Kumchompoo et al. 2023), the synthesis of materials for adsorption of heavy metals (Liu et al. 2022; Xu et al. 2022) or organic dye (You et al. 2022; Hu et al. 2023) pointed to the utilization of rice waste being more economically feasible as compared to other potential biomass sources. This section aims to provide a general overview of the profitability of utilizing biomass generated during rice production and identify which of these options would be the best choice for large-scale applications. Table 1 presents a comprehensive analysis of market prices for each material obtained from various biomass sources, along with the fields in which they can be applied. This demonstrates the approaches and feasibility of producing each of these materials and which of the different biomass sources is economically viable due to the variety of products or benefits they offer.
The various discussed biomass feedstocks show significant economic viability for obtaining value-added products, as shown in Table 1. While RS enables the production of biofuels, biogases, and different materials, the profitability and scalability of biofuels stand out in the RS-derived product spectrum. This, combined with the growing demand for alternative fuel sources and their industrial applications, positions biofuels as the most promising option to explore and research among the developed technologies for utilizing rice straw generated during rice production. The projected market value is $154 billion by 2024. Another material of consideration from RS is carbon-based materials. Data obtained suggests that such materials currently generate around $22.9 billion annually. Additionally, more cost-effective methods for their production make the utilization of RS for carbon-based material production a significant opportunity.
Table 1. Cost Analysis and Applications of Biomasses from Rice Residues
Similarly, products derived from Rice Bran (RB) also possess substantial potential for application across various fields, and they are estimated to become a significant part of industries’ economies working with such compounds within a couple of years, as depicted in Table 1. Despite the projected $65.6 billion market value for bioactive by 2028 and $31.22 billion for bioplastics by 2027, the latter is particularly promising due to the growing demand for plastics and the environmental pollution they cause. Utilizing this biomass for bioplastics production or further advancing their technology may offer better profitability in the future, given the current issues associated with petroleum-derived plastics.
In summary, RH stands out as the most promising biomass to obtain high-value products as compared to other materials derived from the different biomass feedstocks showcased in this contribution. This is not only due to the extensive applicability of adsorbent and silica materials across numerous industrial sectors within our society but also the favorable pricing, the substantial quantities of reclaimable waste materials, and the developed technologies surrounding them, making these processes highly profitable and scalable. Coupled with material modification technologies that can be applied and the potential for combining them with other materials to enhance effectiveness, this makes it a compelling avenue. Therefore, labeling the different RH-based materials as superior to silica might not be the optimal choice. Hence, considering the general potential of this type of waste as a source for various adsorbent and synthesis materials provides a more accurate understanding of how this raw material could influence diverse environmental treatments, fields like medicine, filtration, cosmetics, food, and more. Nevertheless, each of the discussed biomasses presents significant potential in their application for producing value-added products. This not only enables the synthesis of diverse materials but also offers alternatives for managing the waste generated during rice production processes, thereby fostering a more circular economy and reducing environmental impact on our surroundings.
Future Perspectives and Conclusions
The utilization of residues generated in rice production and their conversion into high value-added products offer relevant potential for the valorization of such raw materials. The three primary biomass feedstocks derived from rice production (straw, husk, and bran) enabled the extraction of various products of great current interest. These products can find applications across a spectrum including (bio)fuels, the development of active compounds and plastics, as well as materials including silica or other adsorbents. These high value-added products can find applications in environmental remediation, biomedical applications, filtration, cosmetics, foodstuffs and various others. Furthermore, the combination of these materials with other technologies or substances not only broadens their field of application but also can potentially provide more economically feasible processes while enhancing the added value of such residues. Intriguing approaches including integrating MOFs with RH into nanohybrids, combining cellulose from RB with chitin for bioplastic production or merging modified RS with petroleum sludges for various hydrocarbon production, represent just a few of the remarkable possibilities offered by rice-derived waste fractions.
Each of the diverse approaches to obtain value-added products from selected fractions in this work exhibited potentially remarkable applicability within their respective fields of use, with potentially promising economic prospects. Based on these premises, researchers are prompted to continue studying and developing more cost-effective processes and novel products derived from various rice production residues as well as combining these fractions with others to expand their applications scope. This expansion is pivotal for a circular economy around these residues while respecting the environment.
We believe that this contribution can stimulate further studies focused on the development of new products as well as a future pilot-scale implementation of some of the aforementioned processes, which possess considerable potential but have not yet been studied for scaling up, e.g., bioactives or bioplastics production. The future utilization of new waste feedstocks has the potential to play a substantial role in the economy and products used by our society, thus making them an integral, sustainable component of energy and material solutions. This, in turn, can foster the design of greener and cleaner processes and technologies for a more sustainable future.
Rice waste can be consequently considered a compelling alternative in the quest for new resources, also having potentially relevant valorization strategies towards the production of a number of valuable end products.
REFERENCES CITED
Adnan, M., Siddiqui, A. J., Ashraf, S. A., Snoussi, M., Badraoui, R., Ibrahim, A. M. M., Alreshidi, M., Sachidanandan, M., and Patel, M. (2023). “Characterization and process optimization for enhanced production of polyhydroxybutyrate (PHB)-based biodegradable polymer from Bacillus flexus isolated from municipal solid waste landfill site,” Polymers 15(6), article 1407.
Aghaei, S., Karimi Alavijeh, M., Shafiei, M., and Karimi, K. (2022). “A comprehensive review on bioethanol production from corn stover: Worldwide potential, environmental importance, and perspectives,” Biomass and Bioenergy 161, article 106447. DOI: 10.1016/j.biombioe.2022.106447
Alan, H., and Köker, A. R. (2023). “Analyzing and mapping agricultural waste recycling research: An integrative review for conceptual framework and future directions,” Resources Policy 85, article 103987. DOI: 10.1016/j.resourpol.2023.103987
Alonso-Gonzalez, M., Felix, M., Guerrero, A., and Romero, A. (2021). “Effects of mould temperature on rice bran-based bioplastics obtained by injection moulding,” Polymers 13(3), article 398. DOI: 10.3390/polym13030398
Alonso-González, M., Felix, M., Guerrero, A., and Romero, A. (2021). “Rice bran-based bioplastics: Effects of the mixing temperature on starch plastification and final properties,” International Journal of Biological Macromolecules 188, 932-940. DOI: 10.1016/j.ijbiomac.2021.08.043
Alonso-González, M., Felix, M., and Romero, A. (2022). “Influence of the plasticizer on rice bran-based eco-friendly bioplastics obtained by injection moulding,” Industrial Crops and Products 180, article 114767. DOI: 10.1016/j.indcrop.2022.114767
Aprilia, S., Rosnelly, C. M., Zuhra, Fitriani, F., Haffiz Akbar, E., Raqib, M., Rahmah, K., Amin, A., and Baity, R. A. (2023). “Synthesis of amorphous silica from rice husk ash using the sol–gel method: Effect of alkaline and alkaline concentration,” Materials Today: Proceedings 87, 225-229. DOI: 10.1016/j.matpr.2023.02.403
Araichimani, P., Prabu, K. M., Suresh Kumar, G., Karunakaran, G., Surendhiran, S., Shkir, M., and Ali, H. E. (2022). “Synthesis of Fe3O4-decorated SiO2 nanostructure using rice husk as a source by microwave combustion for the development of a magnetically recoverable adsorbent,” Ceramics International 48(7), 10339-10345. DOI: 10.1016/j.ceramint.2022.02.001
Bangar, S. P., Whiteside, W. S., Kajla, P., and Tavassoli, M. (2023). “Value addition of rice straw cellulose fibers as a reinforcer in packaging applications,” International Journal of Biological Macromolecules 243, article 125320. DOI: 10.1016/j.ijbiomac.2023.125320
Bunmusik, W., Suttiarporn, P., Phankaew, T., Thitisut, P., and Seangwattana, T. (2023). “The effects of solvent–based ultrasonic–assisted extraction of bioactive compounds and antioxidant activities from pigmented rice bran,” Materials Today: Proceedings 77, 1073-1078. DOI: 10.1016/j.matpr.2022.11.391
Collard, F. X., Cooke-Willis, M., Pas, D. v. d., and Torr, K. (2022). “Optimising ex-situ catalytic fast pyrolysis of pine wood at pilot scale: Impacts on the energy content, chemical composition and stability of the liquid fuel product,” Journal of Analytical and Applied Pyrolysis 168, article 105725. DOI: 10.1016/j.jaap.2022.105725
Dessie, W., Luo, X., He, F., Liao, Y., Duns, G. J., and Qin, Z. (2023). “Lignin valorization: A crucial step towards full utilization of biomass, zero waste and circular bioeconomy,” Biocatalysis and Agricultural Biotechnology 51, article 102777. DOI: 10.1016/j.bcab.2023.102777
Djouonkep, L. D. W., Tamo, C. T., Simo, B. E., Issah, N., Tchouagtie, M. N., Selabi, N. B. S., Doench, I., Kamdem Tamo, A., Xie, B., and Osorio-Madrazo, A. (2023). “Synthesis by melt-polymerization of a novel series of bio-based and biodegradable thiophene-containing copolyesters with promising gas barrier and high thermomechanical properties,” Molecules 28(4), article 1825.
Dong, L., Cao, G., Wang, W., Luo, G., Yang, F., and Ren, N. (2023). “Improved biohythane production from rice straw in an integrated anaerobic bioreactor under thermophilic conditions,” Microorganisms 11(2), article 474.
Drobniak, A., Jelonek, Z., Mastalerz, M., and Jelonek, I. (2023). “Residential gasification of solid biomass: Influence of raw material on emissions. International Journal of Coal Geology 271, article 104247. DOI: 10.1016/j.coal.2023.104247
Echaroj, S., Pannucharoenwong, N., Ong, H. C., and Rattanadecho, P. (2021). “Production of bio-fuel from alcohothermal liquefaction of rice straw over sulfated-graphene oxide,” Energy Reports 7, 744-752. DOI: 10.1016/j.egyr.2021.07.081
Emmanuel, J. K., Nganyira, P. D., and Shao, G. N. (2022). “Evaluating the potential applications of brewers’ spent grain in biogas generation, food and biotechnology industry: A review,” Heliyon 8(10), article e11140. DOI: 10.1016/j.heliyon.2022.e11140
Essien, S. O., Udugama, I., Young, B., and Baroutian, S. (2021). “Recovery of bioactives from kānuka leaves using subcritical water extraction: Techno-economic analysis, environmental impact assessment and technology readiness level,” The Journal of Supercritical Fluids 169, article 105119. DOI: 10.1016/j.supflu.2020.105119
Fernández-Andrade, K. J., Fernández-Andrade, A. A., Zambrano-Intriago, L. Á., Arteaga-Perez, L. E., Alejandro-Martin, S., Baquerizo-Crespo, R. J., Luque, R., and Rodríguez-Díaz, J. M. (2023). “Microwave-assisted MOF@biomass layered nanomaterials: Characterization and applications in wastewater treatment,” Chemosphere 314, article 137664. DOI: 10.1016/j.chemosphere.2022.137664
Franco, A., De, S., Balu, A. M., Romero, A. A., and Luque, R. (2018). “Integrated mechanochemical/microwave-assisted approach for the synthesis of biogenic silica-based catalysts from rice husk waste,” ACS Sustainable Chemistry and Engineering 6(9), 11555-11562. DOI: 10.1021/acssuschemeng.8b01738
Gupte, A. P., Basaglia, M., Casella, S., and Favaro, L. (2022). “Rice waste streams as a promising source of biofuels: feedstocks, biotechnologies and future perspectives,” Renewable and Sustainable Energy Reviews 167, article 112673. DOI: 10.1016/j.rser.2022.112673
Haider, J. B., Haque, M. I., Hoque, M., Hossen, M. M., Mottakin, M., Khaleque, M. A., Johir, M. A. H., Zhou, J. L., Ahmed, M. B., and Zargar, M. (2022). “Efficient extraction of silica from openly burned rice husk ash as adsorbent for dye removal,” Journal of Cleaner Production 380, article 135121. DOI: 10.1016/j.jclepro.2022.135121
Hong, G.-B., and Wang, Y.-K. (2017). “Synthesis of low-cost adsorbent from rice bran for the removal of reactive dye based on the response surface methodology,” Applied Surface Science 423, 800-809. DOI: 10.1016/j.apsusc.2017.06.264
Hou, X., Wang, X., and Mi, W. (2018). “Progress in Fe3O4-based multiferroic heterostructures,” Journal of Alloys and Compounds 765, 1127-1138. DOI: 10.1016/j.jallcom.2018.06.287
Hu, Z., Li, Q., Chen, Y., Li, T., Wang, Y., Zhang, R., Peng, H., Wang, H., Wang, Y., Tang, J., Nauman Aftab, M., and Peng, L. (2023). “Intermittent ultrasound retains cellulases unlock for enhanced cellulosic ethanol with high-porosity biochar for dye adsorption using desirable rice mutant straw,” Bioresource Technology 369, article 128437. DOI: 10.1016/j.biortech.2022.128437
Hu, Z., Peng, H., Liu, J., Zhang, H., Li, S., Wang, H., Lv, Z., Wang, Y., Sun, D., Tang, J., Peng, L., and Wang, Y. (2023). “Integrating genetic-engineered cellulose nanofibrils of rice straw with mild chemical treatments for enhanced bioethanol conversion and bioaerogels production,” Industrial Crops and Products 202, article 117044. DOI: 10.1016/j.indcrop.2023.117044
Illankoon, W. A. M. A. N., Milanese, C., Collivignarelli, M. C., and Sorlini, S. (2023). “Value chain analysis of rice industry by products in a circular economy context: A review,” Waste 1(2), 333-369. https://www.mdpi.com/2813-0391/1/2/22
Innocenzi, P. (2023). “Sol-gel processing for advanced ceramics, a perspective,” Open Ceramics 100477. DOI: 10.1016/j.oceram.2023.100477
Jayakumar, M., Bizuneh Gebeyehu, K., Deso Abo, L., Wondimu Tadesse, A., Vivekanandan, B., Prabhu Sundramurthy, V., Bacha, W., Ashokkumar, V., and Baskar, G. (2023). “A comprehensive outlook on topical processing methods for biofuel production and its thermal applications: Current advances, sustainability and challenges,” Fuel 349, article 128690. DOI: 10.1016/j.fuel.2023.128690
Kee, S. H., Ganeson, K., Rashid, N. F. M., Yatim, A. F. M., Vigneswari, S., Amirul, A.-A. A., Ramakrishna, S., and Bhubalan, K. (2022). “A review on biorefining of palm oil and sugar cane agro-industrial residues by bacteria into commercially viable bioplastics and biosurfactants,” Fuel 321, article 124039. DOI: 10.1016/j.fuel.2022.124039
Kumchompoo, J., Kunthadee, P., Laorodphan, N., Kidkhunthod, P., Kuimalee, S., Tangkuaram, T., and Puntharod, R. (2023). “The solid-state reaction facilitated by a microwave-assisted method for lithium vanadium silicon oxide synthesis by incorporating pure silica and rice husk ash for the application as anode material in lithium-ion battery,” Radiation Physics and Chemistry 207, article 110863. DOI: 10.1016/j.radphyschem.2023.110863
Kwon, O., Kim, J., and Han, J. (2022). “Organic waste derived biodiesel supply chain network: Deterministic multi-period planning model,” Applied Energy 305, article 117847. DOI: 10.1016/j.apenergy.2021.117847
Le, A. H.Q., Hoang, H. Y., Le Van, T., Hoang Nguyen, T., and Uyen Dao, M. (2023). “Adsorptive removal of benzene and toluene from aqueous solutions by oxygen-functionalized multi-walled carbon nanotubes derived from rice husk waste: A comparative study,” Chemosphere 336, article 139265. DOI: 10.1016/j.chemosphere.2023.139265
Li, J., Zhang, X., Zhou, W., Tu, Z., Yang, S., Xia, T., Chen, Z., and Du, Y. (2023). “Intelligent films based on highland barley β-glucan/highland barley prolamin incorporated with black rice bran anthocyanins,” Food Packaging and Shelf Life 39, article 101146. DOI: 10.1016/j.fpsl.2023.101146
Li, P., Zhou, M., Jian, B., Lei, H., Liu, R., Zhou, X., Li, X., Wang, Y., and Zhou, B. (2023). “Paper material coated with soybean residue nanocellulose waterproof agent and its application in food packaging,” Industrial Crops and Products 199, article 116749. DOI: 10.1016/j.indcrop.2023.116749
Liu, Z., Zhen, F., Zhang, Q., Qian, X., Li, W., Sun, Y., Zhang, L., and Qu, B. (2022). “Nanoporous biochar with high specific surface area based on rice straw digestion residue for efficient adsorption of mercury ion from water,” Bioresource Technology 359, article 127471. DOI: 10.1016/j.biortech.2022.127471
Manzoor, A., Pandey, V. K., Dar, A. H., Fayaz, U., Dash, K. K., Shams, R., Ahmad, S., Bashir, I., Fayaz, J., Singh, P., Khan, S. A., and Ganaie, T. A. (2023). “Rice bran: Nutritional, phytochemical, and pharmacological profile and its contribution to human health promotion,” Food Chemistry Advances 2, article 100296. DOI: 10.1016/j.focha.2023.100296
Medina Litardo, R. C., García Bendezú, S. J., Carrillo Zenteno, M. D., Pérez-Almeida, I. B., Parismoreno, L. L., and Lombeida García, E. D. (2022). “Effect of mineral and organic amendments on rice growth and yield in saline soils,” Journal of the Saudi Society of Agricultural Sciences 21(1), 29-37. DOI: 10.1016/j.jssas.2021.06.015
Michailos, S., and Webb, C. (2020). “Chapter 10 – Valorization of rice straw for ethylene and jet fuel production: a technoeconomic assessment,” in: Food Industry Wastes, Second Edition, M. R. Kosseva and C. Webb (eds.), Academic Press, pp. 201-221. DOI: 10.1016/B978-0-12-817121-9.00010-3
Moirangthem, K., Ramakrishna, P., Amer, M. H., and Tucker, G. A. (2021). “Bioactivity and anthocyanin content of microwave-assisted subcritical water extracts of Manipur black rice (Chakhao) bran and straw,” Future Foods 3, article 100030. DOI: 10.1016/j.fufo.2021.100030
Morales-Paredes, C. A., Rodríguez-Linzán, I., Saquete, M. D., Luque, R., Osman, S. M., Boluda-Botella, N., and Joan Manuel, R.-D. (2023). “Silica-derived materials from agro-industrial waste biomass: Characterization and comparative studies,” Environmental Research 231, article 116002. DOI: 10.1016/j.envres.2023.116002
Mounika, A., Ilangovan, B., Mandal, S., Shraddha Yashwant, W., Priya Gali, S., and Shanmugam, A. (2022). “Prospects of ultrasonically extracted food bioactives in the field of non-invasive biomedical applications – A review,” Ultrasonics Sonochemistry 89, article 106121. DOI: 10.1016/j.ultsonch.2022.106121
Nandiyanto, A. B. D., Ragadhita, R., and Istadi, I. (2020). “Techno-economic analysis for the production of silica particles from agricultural wastes,” Moroccan Journal of Chemistry 8(4), 801-818. <Go to ISI>://WOS:000576293200003
Narzary, A., Brahma, J., and Das, A. K. (2023). “Utilization of waste rice straw for charcoal briquette production using three different binder,” Cleaner Energy Systems 5, article 100072. DOI: 10.1016/j.cles.2023.100072
Noori, S., Kiasat, A. R., and Mirzajani, R. (2023). “An eco-friendly and energy-efficient protocol for the Heck reaction under solar radiation catalyzed by rice husk silica‐anchored cinchonine.Pd nanocomposite,” Journal of Saudi Chemical Society 27(3), article 101625. DOI: 10.1016/j.jscs.2023.101625
Núñez-Delgado, A., Dominguez, J. R., Zhou, Y., and Race, M. (2022). “New trends on green energy and environmental technologies, with special focus on biomass valorization, water and waste recycling: Editorial of the special issue,” Journal of Environmental Management 316, article 115209. DOI: 10.1016/j.jenvman.2022.115209
Overturf, E., Ravasio, N., Zaccheria, F., Tonin, C., Patrucco, A., Bertini, F., Canetti, M., Avramidou, K., Speranza, G., Bavaro, T., and Ubiali, D. (2020). “Towards a more sustainable circular bioeconomy. Innovative approaches to rice residue valorization: The RiceRes case study,” Bioresource Technology Reports 11, article 100427. DOI: 10.1016/j.biteb.2020.100427
Pan, Z., Li, X., Fu, L., Li, Q., and Li, X. (2023). “Environmental sustainability by a comprehensive environmental and energy comparison analysis in a wood chip and rice straw biomass-fueled multi-generation energy system,” Process Safety and Environmental Protection 177, 868-879. DOI: 10.1016/j.psep.2023.07.027
Rajamani, S., Kolla, S. S. N., Gudivada, R., Raghunath, R., Ramesh, K., and Jadhav, S. A. (2023). “Valorization of rice husk to value-added chemicals and functional materials,” International Journal of Environmental Research 17(1), 22. DOI: 10.1007/s41742-023-00512-2
Ray, S. K., Pant, B., Park, M., and Bastakoti, B. P. (2023). “Rice husk-derived sodium hydroxide activated hierarchical porous biochar as an efficient electrode material for supercapacitors,” Journal of Analytical and Applied Pyrolysis 175, article 106207. DOI: 10.1016/j.jaap.2023.106207
Rojas, J., Zhai, S., Sun, E., Haribal, V., Marin-Quiros, S., Sarkar, A., Gupta, R., Cargnello, M., Chueh, W., and Majumdar, A. (2023). “Technoeconomics and carbon footprint of hydrogen production,” International Journal of Hydrogen Energy. DOI: 10.1016/j.ijhydene.2023.06.292
Roux, M., and Varrone, C. (2021). “Assessing the economic viability of the plastic biorefinery concept and its contribution to a more circular plastic sector,” Polymers 13(22), article 3883.
Saetiao, P., Kongrit, N., Cheng, C. K., Jitjamnong, J., Direksilp, C., and Khantikulanon, N. (2023). “Catalytic conversion of palm oil into sustainable biodiesel using rice straw ash supported-calcium oxide as a heterogeneous catalyst: Process simulation and techno-economic analysis,” Case Studies in Chemical and Environmental Engineering 8, article 100432. DOI: 10.1016/j.cscee.2023.100432
Saini, S., Kuhad, R. C., and Sharma, K. K. (2023). “Valorization of rice straw biomass for co-production of bioethanol, biopesticide and biofertilizer following an eco-friendly biorefinery process,” Process Safety and Environmental Protection 173, 823-836. DOI: 10.1016/j.psep.2023.03.044
Santana Costa, J. A., and Paranhos, C. M. (2018). “Systematic evaluation of amorphous silica production from rice husk ashes,”. Journal of Cleaner Production 192, 688-697. DOI: 10.1016/j.jclepro.2018.05.028
Sapna, I., and Jayadeep, A. (2022). “Cellulolytic and xylanolytic enzyme combinations in the hydrolysis of red rice bran: A disparity in the release of nutraceuticals and its correlation with bioactivities,” LWT 154, article 112856. DOI: 10.1016/j.lwt.2021.112856
Setiawan, J. V., Adhitama, R., Goeltom, M. T., Askitosari, T. D., Yang, D. C., and Sukweenadhi, J. (2022). “The potential of rice bran waste (Oryza sativa L.) and shrimp shell waste as chitin nanowhisker with glycerol plasticizer in the production of bioplastic,” IOP Conference Series: Earth and Environmental Science.
Shrestha, D., Nayaju, T., Kandel, M. R., Pradhananga, R. R., Park, C. H., and Kim, C. S. (2023). “Rice husk-derived mesoporous biogenic silica nanoparticles for gravity chromatography,” Heliyon 9(4), e15142. DOI: 10.1016/j.heliyon.2023.e15142
Sica, P., de Castro Mattos, E., Silveira, G. M., Abdalla, J. P., Alves, V. K., Borges, I. S., Landell, M., Xavier, M. A., and Baptista, A. S. (2023). “Quantitative and qualitative evaluation of novel energy cane accessions for sugar, bioenergy, 1 G, and 2 G ethanol production,” Industrial Crops and Products 203, article 117163. DOI: 10.1016/j.indcrop.2023.117163
Solieman, N. Y., Afifi, M. M. I., Abu-ElMagd, E., Baker, N. A., and Ibrahim, M. M. (2023). “Hydro-physical, biological and economic study on simply, an environment- friendly and valuable rice straw-based hydrogel production,” Industrial Crops and Products 201, article 116850. DOI: 10.1016/j.indcrop.2023.116850
Stančin, H., Strezov, V., and Mikulčić, H. (2023). “Life cycle assessment of alternative fuel production by co-pyrolysis of waste biomass and plastics,” Journal of Cleaner Production 414, article 137676. DOI: 10.1016/j.jclepro.2023.137676
Su, Y., and Xu, G. (2022). “Low-carbon transformation of natural resource industry in China: Determinants and policy implications to achieve COP26 targets,” Resources Policy 79, article 103082. DOI: 10.1016/j.resourpol.2022.103082
Sukatis, F. F., Wee, S. Y., and Aris, A. Z. (2022). “Potential of biocompatible calcium-based metal-organic frameworks for the removal of endocrine-disrupting compounds in aqueous environments,” Water Research 218, article 118406. DOI: 10.1016/j.watres.2022.118406
Tian, J., Xu, N., Liu, B., Huan, H., Gu, H., Dong, C., and Ding, C. (2020). “Interaction effect of silo density and additives on the fermentation quality, microbial counts, chemical composition and in vitro degradability of rice straw silage,” Bioresource Technology 297, article 122412. DOI: 10.1016/j.biortech.2019.122412
Tian, S., Sun, X., Xiao, H., Zhou, Y., Huang, X., An, X.-L., Liu, C., and Su, J.-Q. (2023). “Evaluation of rice straw and its transformation products on norfloxacin degradation and antibiotic resistome attenuation during soil incorporation. Chemosphere 313, article 137451. DOI: 10.1016/j.chemosphere.2022.137451
Torres-Mayanga, P. C., Lachos-Perez, D., Mudhoo, A., Kumar, S., Brown, A. B., Tyufekchiev, M., Dragone, G., Mussatto, S. I., Rostagno, M. A., Timko, M., and Forster-Carneiro, T. (2019). “Production of biofuel precursors and value-added chemicals from hydrolysates resulting from hydrothermal processing of biomass: A review,” Biomass and Bioenergy 130, article 105397. DOI: 10.1016/j.biombioe.2019.105397
Torres de Sande, V., Sadique, M., Pineda, P., Bras, A., Atherton, W., and Riley, M. (2021). “Potential use of sugar cane bagasse ash as sand replacement for durable concrete,” Journal of Building Engineering 39, article 102277. DOI: 10.1016/j.jobe.2021.102277
Vaštyl, M., Jankovská, Z., Cruz, G. J. F., and Matějová, L. (2022). “A case study on microwave pyrolysis of waste tyres and cocoa pod husk; effect on quantity and quality of utilizable products,” Journal of Environmental Chemical Engineering 10(1), article 106917. DOI: 10.1016/j.jece.2021.106917
Villar, M. A. L., Vidallon, M. L. P., and Rodriguez, E. B. (2022). “Nanostructured lipid carrier for bioactive rice bran gamma-oryzanol,” Food Bioscience 50, article 102064. DOI: 10.1016/j.fbio.2022.102064
Villota-Enríquez, M. D., and Rodríguez-Páez, J. E. (2023). “Bio-silica production from rice husk for environmental remediation: Removal of methylene blue from aqueous solutions,” Materials Chemistry and Physics 301, article 127671. DOI: 10.1016/j.matchemphys.2023.127671
Wancura, J. H. C., Brondani, M., Vezaro, F. D., Martins-Vieira, J. C., Moreira, B. P., dos Santos, M. S. N., Abaide, E. R., de Castilhos, F., and Mayer, F. D. (2023). “Motivations to produce biofuels from rice bran: An overview involving a recent panorama,” Industrial Crops and Products 203, article 117170. DOI: 10.1016/j.indcrop.2023.117170
Wang, E., Sun, H., Chen, P., Zheng, Y., Guo, J., and Dong, R. (2023a). “Two-step anaerobic digestion of rice straw with nanobubble water,” Bioresource Technology 376, article 128928. DOI: 10.1016/j.biortech.2023.128928
Wang, K., Peng, N., Zhang, D., Zhou, H., Gu, J., Huang, J., Liu, C., Chen, Y., Liu, Y., and Sun, J. (2023b). “Efficient removal of methylene blue using Ca(OH)2 modified biochar derived from rice straw,” Environmental Technology & Innovation 31, article 103145. DOI: 10.1016/j.eti.2023.103145
Wang, M., Wang, H., Zhang, X., Chen, D., Wang, N., Qin, M., and Yang, J. (2023c). “Co2SiO4/CoO heterostructure anchored on graphitized carbon derived from rice husks with hierarchical pore as electrode material for supercapacitor,” Applied Surface Science 636, article 157820. DOI: 10.1016/j.apsusc.2023.157820
Wang, S., Lee, Y.-R., Won, Y., Kim, H., Jeong, S.-E., Wook Hwang, B., Ra Cho, A., Kim, J.-Y., Cheol Park, Y., Nam, H., Lee, D.-H., Kim, H., and Jo, S.-H. (2022). “Development of high-performance adsorbent using KOH-impregnated rice husk-based activated carbon for indoor CO2 adsorption,” Chemical Engineering Journal 437, article 135378. DOI: 10.1016/j.cej.2022.135378
Wu, C.-Y., Lin, T.-Y., and Duh, J.-G. (2022). “Constructing cellulose nanofiber / Si composite 3D-Net structure from waste rice straw via freeze drying process for lithium-ion battery anode materials,” Materials Chemistry and Physics 285, article 126107. DOI: 10.1016/j.matchemphys.2022.126107
Xu, H., Cheng, S., Hungwe, D., Yoshikawa, K., and Takahashi, F. (2022). “Co-pyrolysis coupled with torrefaction enhances hydrocarbons production from rice straw and oil sludge: The effect of torrefaction on co-pyrolysis synergistic behaviors,” Applied Energy 327, article 120104. DOI: 10.1016/j.apenergy.2022.120104
Xu, J., Fan, Z., Yang, Q., Lu, G., Liu, P., and Wang, D. (2023). “Hydrothermal carbonization of waste wood: Sustainable recycling of biomass by-products and novel performance enhancer for bitumen,” Construction and Building Materials 404, article 133307. DOI: 10.1016/j.conbuildmat.2023.133307
Xu, Z., Hu, Y., Guo, Z., Xiao, X., Peng, C., and Zeng, P. (2022). “Optimizing pyrolysis temperature of contaminated rice straw biochar: Heavy metal(loid) deportment, properties evolution, and Pb adsorption/immobilization,” Journal of Saudi Chemical Society 26(2), article 101439. DOI: 10.1016/j.jscs.2022.101439
Yadav, M., Dwibedi, V., Sharma, S., and George, N. (2022). “Biogenic silica nanoparticles from agro-waste: Properties, mechanism of extraction and applications in environmental sustainability,” Journal of Environmental Chemical Engineering 10(6), article 108550. DOI: 10.1016/j.jece.2022.108550
Yaghoubi, H., Allahyari, M. S., Firouzi, S., Damalas, C. A., and Marzban, S. (2019). “Identifying sustainable options for rice husk valorization using the analytic hierarchy process,” Outlook on Agriculture 48(2), 117-125. DOI: 10.1177/0030727018821384
Yan, P., Ma, Z., Li, H., Gong, P., Xu, M., and Chen, T. (2023). “Laboratory tests, field application and carbon footprint assessment of cement-stabilized pure coal solid wastes as pavement base materials,” Construction and Building Materials 366, article 130265. DOI: 10.1016/j.conbuildmat.2022.130265
Yang, Y., Phuong Nguyen, T. M., Van, H. T., Nguyen, Q. T., Nguyen, T. H., Lien Nguyen, T. B., Hoang, L. P., Van Thanh, D., Nguyen, T. V., Nguyen, V. Q., Thang, P. Q., Yılmaz, M., and Le, V. G. (2022). “ZnO nanoparticles loaded rice husk biochar as an effective adsorbent for removing reactive red 24 from aqueous solution,” Materials Science in Semiconductor Processing 150, article 106960. DOI: 10.1016/j.mssp.2022.106960
Yashni, G., Al-Gheethi, A., Mohamed, R., Dai-Viet, N. V., Al-Kahtani, A. A., Al-Sahari, M., Hazhar, N. J. N., Noman, E., and Alkhadher, S. (2021). “Bio-inspired ZnO NPs synthesized from Citrus sinensis peels extract for Congo red removal from textile wastewater via photocatalysis: Optimization, mechanisms, techno-economic analysis,” Chemosphere 281, article 130661. DOI: 10.1016/j.chemosphere.2021.130661
Yieh, C. Z., Lee, X., Dua, Y. L., Yien, Y. S., Yee, Y. B. K., and Mubarak, N. M. (2019). “Pilot study of magnetic nanoparticles via SuperPro simulation using catalytic hydrothermal carbonization process,” Journal of Environmental Chemical Engineering, 7(1), article 102932. DOI: 10.1016/j.jece.2019.102932
Yoon, S.-M. (2022). “On the interdependence between biofuel, fossil fuel and agricultural food prices: Evidence from quantile tests,” Renewable Energy 199, 536-545. DOI: 10.1016/j.renene.2022.08.136
You, X., Zhou, R., Zhu, Y., Bu, D., and Cheng, D. (2022). “Adsorption of dyes methyl violet and malachite green from aqueous solution on multi-step modified rice husk powder in single and binary systems: Characterization, adsorption behavior and physical interpretations,” Journal of Hazardous Materials 430, article 128445. DOI: 10.1016/j.jhazmat.2022.128445
Zambrano-Intriago, L. A., Gorozabel-Mendoza, M. L., Córdova Mosquera, A., Delgado-Demera, M. H., Duarte, M. M. M. B., and Rodríguez-Díaz, J. M. (2022). “Kinetics, equilibrium, and thermodynamics of the blue 19 dye adsorption process using residual biomass attained from rice cultivation,” Biomass Conversion and Biorefinery 12(9), 3843-3855. DOI: 10.1007/s13399-020-00944-2
Zeghoud, S., Hemmami, H., Ben Seghir, B., Ben Amor, I., Kouadri, I., Rebiai, A., Messaoudi, M., Ahmed, S., Pohl, P., and Simal-Gandara, J. (2022). “A review on biogenic green synthesis of ZnO nanoparticles by plant biomass and their applications,” Materials Today Communications 33, article 104747. DOI: 10.1016/j.mtcomm.2022.104747
Zhang, X., Liu, P., and Zhang, Y. (2023). “The application of MOFs for hydrogen storage,” Inorganica Chimica Acta 557, article 121683. DOI: 10.1016/j.ica.2023.121683
Zheng, B., Wang, J., Wu, S., Wu, H., Xie, Z., and Wan, W. (2023). “Spatio-temporal patterns and driving mechanisms of rice biomass during the growth period in China since 2000,” Ecological Indicators 153, article 110389. DOI: 10.1016/j.ecolind.2023.110389
Zheng, H., Wang, Y., Feng, X., Li, S., Leong, Y. K., and Chang, J.-S. (2022). “Renewable biohydrogen production from straw biomass – Recent advances in pretreatment/hydrolysis technologies and future development,” International Journal of Hydrogen Energy 47(88), 37359-37373. DOI: 10.1016/j.ijhydene.2021.10.020
Article submitted: September 14, 2023; Peer review completed: October 14, 2023; Revised version received and accepted: October 28, 2023; Published: November 8, 2023.
DOI: 10.15376/biores.19.1.Sanoja-Lopez