The sustainable development goals (SDGs 2030), enshrine through goal six a declaration that clean water and sanitation are pivotal to human development [1]. This is because waterborne infections caused by microorganisms are a leading cause of death worldwide [2, 3]. Therefore, the need to find affordable, efficient, versatile, and sustainable technologies to control and eliminate microbes from drinking water is inevitable [3]. The implementation of water disinfection technologies to eliminate pathogens in centralized and some decentralized water treatment systems is achieved through conventional methods that include chlorination, ozonation, and ultraviolet treatment [3, 4]. However, chlorination is limited by the formation of toxic byproducts, while ozonation and ultraviolet offer no protection against recontamination in the distribution systems [4, 5]. Therefore, this necessitates the deployment of alternative treatment technologies.
In recent years, nanotechnology through nanomaterials has emerged as an effective and versatile tool for water disinfection through its ability to cope with resistant pathogens. Normally, microbes adapt to drug resistance by protecting themselves against all odds and mutating to enable them to survive and reproduce even in harsh environments [6]. Nanomaterials have been studied as a potential solution to water disinfection challenges [4, 7] because pathogens find it hard to acquire resistance to nanoparticles that target multiple bacterial components, compared to the use of bulk materials during conventional treatment techniques. The application of silver metal as an antimicrobial agent has been documented since ancient times [8]. Since the 19th century, silver ions have been associated with bactericidal effects [9]. Recently, the prevalence of antimicrobial drug resistance to antibiotics has been increasing therefore, the use of silver as a disinfectant is inevitable. Silver is now used in consumer products such as textiles, cosmetics, and medical instruments [10–12] in the form of nanoparticles, which are prepared by the chemical reduction of silver salts [13]. Furthermore, studies have documented its potential in water disinfection [14–17]. Therefore, silver is a fascinating and promising candidate to be explored due to its inhibitory and antibacterial capabilities among various metal nanoparticles [6, 18]. However, silver nanoparticles can aggregate when their size is much reduced, which limits their chemical and antimicrobial properties. Therefore, to address this challenge, silver can either be capped with polymers to make polymeric nanocomposites [6, 18] or with a layer of metal oxide, like magnesium oxide, calcium oxide, and zinc oxide, to form a core-shell shape that provides a high surface area [6]. Moreover, when nanomaterials are synergized, hybrid nanocomposites that are more powerful than the individual nanoparticles can be produced; these are expected to combine the properties of the constituent elements [19].
Various studies have indicated the antimicrobial efficacy of ZnO nanoparticles against both gram-positive and gram-negative bacteria [20–22]. The antibacterial properties of ZnO nanoparticles have been geared toward various applications that include controlling foodborne pathogens [23], and waterborne pathogens from drinking water [4], due to their high biocompatibility and bactericidal effects [19]. ZnO has lately been acknowledged by the United States Food and Drug Administration (21CFR182.8991) (FDA, 2011) as a safe material [6, 24] with a short lifespan in the body that lasts for only some hours [25]. ZnO nanoparticles suppress bacterial growth by a variety of processes, including cell penetration, electrostatic adhesion to the bacterial surface, and the formation of reactive oxygen species [26]. In this regard, ZnO nanoparticles can be considered viable and effective nanomaterials to be used for protection against antibacterial infections [27]. Therefore, synergizing Ag nanoparticles with ZnO nanoparticles will yield a nanocomposite material with stronger antibacterial properties for both gram-positive and gram-negative bacteria [18].
Metal and metal oxide nanoparticles have gained much attention as antibacterial materials because of their high reactivity, which is related to their very high surface area to volume ratio [28]. As a consequence, the potential of Ag–ZnO nanocomposites can be harnessed and applied in the field of environmental health for the development of antimicrobial compounds in view of water disinfection. In order to exploit synergies, different alloys have been synthesized and shown a superior antimicrobial effect during water disinfection against bacterial drug resistance [29, 30]. The Ag-ZnO nanocomposites display a fascinating efficiency ascribed to their plasmonic properties and interfacial electron exchange process. Furthermore, when compared to pure ZnO nanoparticles, the efficacy of Ag-ZnO nanocomposites has been assessed based on their silver and zinc ion release in aqueous solution, stability, reusability, and lasting bactericidal effect, which are all significantly higher [19].
Several methods have been employed for the synthesis of Ag–ZnO nanocomposites, which include co-precipitation [31], sol-gel [32], and hydrothermal synthesis [33], to mention just a few. However, the application of high temperatures and pressures, longer reaction times, and the generation of chemical waste hamper their application in large-scale production. Therefore, the development of an environmentally benign technology in material synthesis is inevitable. The green synthesis of nanomaterials by using natural biogenic materials such as fungi, bacteria and plant parts is growing. The literature survey reports the green synthesis of Ag-ZnO nanocomposites from different medicinal plant parts such as moringa oleifera seeds [34], Azadirachta indica leaf extract [35], Zingiber zerumbet rhizome [36], potato peeland [37], and guajava leaves [38]. In green synthesis, the properties of nanomaterials are influenced by the plant extract because each plant extract contains a specific concentration and combination of biomolecules [39]. Therefore, nanomaterials synthesized from different plant exhibit different antimicrobial efficacy. This motivates more exploration of plant species for the synthesis of nanomaterials [18, 35, 40].
In this regard, the use of plant extracts via biosynthetic pathways is regarded as the most viable approach for the synthesis of nanomaterials. The plant extracts contain active compounds such as alkaloids, flavonoids, proteins, tannins, terpenoids, saponin, and polyphenols [35, 36, 41]. These phytocompounds act as reducing agents for metal ions and capping agents for the nuclei to prevent the agglomeration of nanoparticles, thus improving their reactivity. To harness the potential of the aforementioned phytocompounds, this study reports a green route for the synthesis of Ag-ZnO from silver and zinc salts using leaf extract from the medicinal plant Tetradenia riperia (TR). Tetradenia riperia (TR) belongs to the family Lamiaceae and is found abundantly in the northern regions of Tanzania. The plant has been used for medicinal purposes to treat diarrhea, indigestion, constipation, malaria, coughs, and sore throats by ethnic groups that include Meru, Maasai, Pare, and Chaga from the northern regions of Tanzania [42]. TR leaves are also being reported to show antibacterial, anti-inflammatory, and anticancer properties [43, 44] Phytochemical analysis revealed the presence of active compounds such as alkaloids, flavonoids, phenols, saponins, tannins, steroids, and reducing sugar [42, 44], which can be used as reducing agent and stabilizing agents for nanomaterials. The spatial distribution of Tetradenia riperia has been documented in various areas of African countries such as Rwanda [45], Madagascar [46], South Africa [47], Uganda [48] and Tanzania [49] in which its medicinal potential has been attributed to abundant phytocompounds with antimicrobial effects [43]. Literature has reported the use of Tetradenia riperia leaves in the synthesis of various nanoparticles such as silver [50, 51]. To the best of our knowledge, no study has reported on the synthesis of Ag-ZnO nanocomposites by using the aqueous leaf extract of Tetradenia riperia. Therefore, this work presents a novel Ag-ZnO synthesized by Tetradenia riperia leaf aqueous extract and evaluates its antibacterial activity against antibiotic-resistant bacterial strains. The Ag-ZnO nanocomposite will later be used for the development of water filters for the disinfection of water at the point of use.