Recent Advances in Covalent Organic Frameworks for Heavy Metal Removal Applications

Covalent organic frameworks comprise a unique class of functional materials that has recently emerged as a versatile tool for energy-related, photocatalytic, environmental, and electrochromic device applications. A plethora of structures can be designed and implemented through a careful selection of ligands and functional units. On the other hand, porous materials for heavy metal absorption are constantly on the forefront of materials science due to the significant health issues that arise from the release of the latter to aquatic environments. In this critical review, we provide insights on the correlation between the structure of functional covalent organic frameworks and their heavy metal absorption. The elements we selected were Pb, Hg, Cr, Cd, and As metal ions, as well as radioactive elements, and we focused on their removal with functional networks. Finally, we outline their advantages and disadvantages compared to other competitive systems such as zeolites and metal organic frameworks (MOFs), we analyze the potential drawbacks for industrial scale applications, and we provide our outlook on the future of this emerging field.


Introduction
The rapid increase in human consumption and tremendous growth of human population, industrial production, and urbanization during the last decades has led to a high concern regarding water pollution worldwide [1,2].
Wastewater containing high concentrations of heavy metal ions (e.g., Hg 2+ , Pb 2+ , Cd 2+ , Cr 6+ , etc.) deriving from industries, such as mining, metal smelting, electroplating, battery manufacturing, and refineries, are directly or indirectly discharged into the environment [3]. This results in excessive heavy metal loads in water bodies that can reach hundreds of milligrams per liter, by far exceeding the acceptable threshold set at 5 mg/L for the human body [4][5][6].
Heavy metal ions, contrary to organic compounds, cannot be reduced or alleviated through physicochemical or biological treatment in nature [7]. Therefore, they are not biodegradable, in this way reducing the quality of water, and they are easily accumulated in aquatic living organisms, imposing a severe threat through the food chain to other species and humans [1,7,8].
Certain heavy metals can interact instantly with proteins and enzymes inside the human body, resulting in an inactivation and accumulation in essential organs. This disruption leads to various diseases and disorders, such as tremors, renal lesions, or even cancer [1,9]. blocks into long ordered 2D layers or 3D networks, precisely [8]. Azine-linked COFs present robust linkage, enhanced porosity, and improved thermal and chemical stability [25,29].
COFs characterized with imide linkages have been synthesized through the condensation of amine and dianhydride in various reports [29,49], also as materials with phenazine linkages through condensation reactions [29].
COFs have also been synthesized through condensation of hydrazine and aldehyde based on azine linkage, in order to improve the pore size and integrate organic building blocks into long ordered 2D layers or 3D networks, precisely [8]. Azine-linked COFs present robust linkage, enhanced porosity, and improved thermal and chemical stability [25,29]. Compared to imine-, azine-, and hydrazone-linked covalent organic frameworks, those having triazine or phenazine linkages present improved chemical stability, as well as extended conjugated networks, features that offer them the potential to be utilized in photocatalytic applications [34].
The double bond between carbon atoms in linking groups has also been explored regarding the development of fully conjugated COFs [29,43,[50][51][52][53][54]. The resulting sp 2 -c COFs consist of all sp 2 carbon backbones and constitute ultra-stable frameworks that maintain both their crystallinity and porosity in water, harsh acidic or alkaline media, and extended exposure to air [29,34,40]. As compared with COFs possessing imine linkages, sp 2c COFs are attractive because of their stability and the development of conjugated structures, in order to increase electron delocalization, as well as charge transfer. Nevertheless, the synthesis of crystalline sp 2 -c covalent organic frameworks with optative conjugation is complicated owing to the insignificant reversibility of C=C bonds [29,34].
It is worth mentioning that post-synthetic modifications can be utilized, in order to alter one type of COFs' linkage to another one, which is inaccessible to direct polycondensation [34,55]. These modifications can be fulfilled by (i) the introduction of metal complexes, (ii) the development of covalent linkages with incoming groups, (iii) a monomer truncation strategy, and (iv) the chemical alteration of linkages [34]. For instance, COFs presenting imine linkages can be oxidized (hydrogen perchloride-mediated oxidation) into amide linkages [29,56], while the reduction of imine linkages, using sodium borohydride, leads to the development of amine-linked covalent organic frameworks [29,34,57]. Moreover, imine-linked COFs have been altered to oxazole-and thioazole-linked ones. In the latter case, the alteration is conducted through the reaction of COFs with sulfur at a high temperature (350 • C) [29,46,58]. Table 1. Main benefits and drawbacks of COFs' linkages.

Type of Linkage Benefits Drawbacks
Boronate Boroxine Thermal stability [28] Prone to amorphization or disintegration upon contact with water or protic solvents [59].
Exfoliation into thin films under mild conditions, due to weak interlayer interactions [34].
The majority of COFs are synthesized under solvothermal conditions, which is similar to the synthesis of metal organic frameworks (MOFs) and inorganic zeolites in autoclave [31]. Most of the COFs synthesized through solvothermal routes often require heating at elevated temperature (usually 120 • C) for several days under Schiff-base chemistry [60], while ligand exchange has also been explored [61]. The solvothermal method involves a mixed reaction founded on organic or non-aqueous solution that comprises the solvent and takes place in a closed system under a given temperature and pressure [62]. Both temperature and pressure of the reaction system strongly affect COFs' crystallinity and porosity [34,35]. The reaction process is usually conducted under heating at temperatures varying from 80 to 120 • C, depending on the chemical reactivity of building units [62], in a sealed vessel for two to nine days [31,34,36,62]. For obtaining improved yield and performance, the reaction time for COFs' synthesis is three days minimum [62]. Finally, the precipitate is collected, suitable solvents are used for washing, and then it is dried under vacuum, in order to obtain solid powder of COFs [31,63].
Another crucial parameter for the formation of COFs is the selection of the solvent since it has a strong impact on the reactant solubility, which can be related to the rate of the reaction and the crystal growth, crystal nucleation, as well as the self-healing structure [34,64]. Mixtures containing two solvents are usually used, in order to fabricate COFs utilizing an acidic catalyst [34,65]. However, the appropriate selection of a suitable solvent system for the development of crystalline-structured COFs is still a challenge [34].
Despite the fact that the solvothermal synthetic route is widely applied for the development of COFs and frequently results in satisfactory quality of the products, it presents some limitations. The main drawback is the difficult scale-up to industrial applications, due to the high temperature/pressure and the very slow reaction rates in many COFs' syntheses [31,34]. Additionally, some COFs, featuring borate or boroxine linkages, are not stable in moist environments, comprising a challenge for application in this field [31,34].

Ionothermal Synthesis
In the ionothermal synthetic method, COFs are fabricated utilizing molten salts or ionic liquids that act as solvents or catalysts [34,66]. Ionic liquids present a plethora of benefits regarding other organic solvents for the development of COFs characterized by high periodicity and stability, because of their reusability. These properties can be modified through counter anions [34,67,68].
Ionothermal interaction usually takes place at high temperatures (about 400 • C), which restricts the application of various monomers [66]. In addition, building monomers can be decomposed at high temperatures, while unwanted side reactions and by-products can be produced too [34,66]. Another drawback regarding this synthetic approach is that the applied monomers are amorphous and do not possess molecular orderings [66]. Thus, ionothermal synthesis has not yet been well-applied in large-scale practical production so far [31].

Microwave-Assisted Synthesis
Microwave-assisted synthesis constitutes an alternative synthetic method towards solvothermal and ionothermal methods, which utilizes microwave irradiation as an alternative energy source [66]. It has already been found that microwaves can be used in the synthesis of crystalline COF materials [31,69,70]. Microwave heating presents several benefits in comparison to conventional heating methods, including accelerated reaction rates, higher product yields, cleaner products, lower energy usage, milder reaction conditions, as well as enhanced selectivity during the chemical reactions [31,34,62,66], offering the possibility for industrialized production of COFs in the future.
Using the microwave method, it is possible to follow the reaction's progress and control the reaction temperature and pressure simultaneously [66]. With respect to the Energies 2021, 14, 3197 7 of 26 above, COFs characterized by high crystallinity and high stability have been successfully synthesized through microwave-assisted solvothermal and ionothermal methods [31].

Room-Temperature Synthesis
Room-temperature synthetic routes exhibit a plethora of advantages, particularly in the case of sensitive monomers or substrates [34]. More specifically, the as-synthesized COFs are characterized by thermal and acid-base stability, high surface area, and enhanced adsorption capacity [62,66]; however, despite the feasibility of preparing COFs under ambient conditions, the large-scale synthesis and application of these COFs is limited and challenging, due to the use of expensive reagents, such as ionic liquids and metal-triflate catalysts [34,62].
Room-temperature synthesis consists mainly of two techniques, the mechanochemical grinding and the solvent method. Mechanochemical synthesis constitutes a facile, economical, solvent-free, and environmentally friendly method [34,71]. COFs, developed through mechanochemical grinding, are characterized by poor crystallinity, porosity, and surface areas, compared to those synthesized via the solvothermal synthetic route [34].

Other Methods
The sono-chemical synthetic route constitutes an alternative approach to the solvothermal synthesis [29]. More specifically, ultrasounds are applied to the reaction system for the development and the collapse of bubbles in the solution, which can affect the cavities of the COFs' structure, as well as they have the ability to accelerate the crystallization process rate, because of the acoustic cavitation [29,66]. Acoustic cavitation produces extremely high local temperatures (>5000 K) and pressures (>1000 bar), leading to exceedingly fast heating and cooling rates [66]. In addition, the reaction can be conducted on a relatively large scale (0.5 L), that is quite larger than the conventional batches (1-40 mL), which are being utilized in the solvothermal method [29]. Inferentially, this method is fast, as it can shorten the reaction time from 3 days to 1-2 h, due to the absence of an induction period [29,66], it is economical, and it consists of a green synthetic method.
For the synthesis of covalent organic frameworks, a vapor-assisted solid-state technique has also been developed [29]. During this synthetic route, the monomers are dissolved in a polar solvent and the resulting mixture is placed dropwise on a glass substrate. Afterwards, the substrate is placed in a desiccator, at room temperature, that contains a vessel of reaction solvent. After approximately 72 h, the glass substrate is covered with the COF layer. The film's thickness can be precisely regulated, indicating a range from a few hundred nanometers to several microns [29].
Ionic liquids have been utilized as a reaction media for the development of both 2D and 3D covalent organic frameworks featuring imine linkages and displaying enhanced crystallinity under moderate conditions [29,31,35]. Ionic liquids comprise molten organic salts that are characterized by low melting points. They are environmentally friendly, non-volatile, and non-flammable, while their physicochemical properties can be easily modified through careful selection of their counter ions. The usage of ionic liquids as reaction media may derive from the fact that an ionic environment facilitates the alignment of aromatic building blocks to an ordered structure. Relatively to the solvothermal synthetic route that is quite time-consuming, the synthesis utilizing ionic liquids is facile, fast, and cost-effective [29].
The Knoevenagel condensation constitutes a widely utilized organic process for the conversion of aldehydes or ketones (C=O) to preferential olefins in the cyano-substituted and cis-configurations, as the base for the catalyst [31]. Very recently, the synthesis of cyanovinylene-linked covalent organic frameworks through Knoevenagel condensation of multidentate benzylcyanides (acting as C-H acids) with dialdehydes has been reported [31,54,72].

Removal of Mercury
Taking into account the exceptional binding affinity between sulfur derivatives and Hg 2+ , various kinds of sulfur-containing COFs have been synthesized and characterized by good adsorption capacities and selectivity for Hg 2+ ions [27] (Table 2). Hg 2+ tends to form stable compounds with electron-donating elements (e.g., S to form HgS), as well as ligands containing phosphorus, nitrogen, and oxygen, in order to fill the vacant 6s orbital; however, at high temperatures (>400 • C), mercury sulfide is not stable and decomposes to its metallic form [73,74].
According to the theory of hard-soft acid and base, soft bases tend to develop stable complexes with soft acids, while hard bases tend to form stable complexes with hard acids. As for mercury and sulfur, the latter constitutes a soft base that binds covalently to mercury, which comprises the soft acid, as it is characterized by a relatively large ionic size, low electro-negativity, and high polarizability [73,75].
In 2017, Merí-Bofí and coworkers [76] studied a well-designed COF, characterized by the presence of triazole and thiol groups in its cavities, as a potential sorbent material for Hg 2+ . Triazole and thiol groups were incorporated under moderate conditions into a highly porous organic polymer TPB-DMTP-COF (TPB, triphenylbenzene; DMTP, dimethoxyterephthaldehyde), with good yield. The as-prepared novel material had the ability to adsorb Hg 2+ ions, both from low and highly concentrated solutions, with exceptional efficiency. More specifically, the material could efficiently reduce mercury concentration from 10 mg/L to 1.5 µg/L, a value that is lower than the acceptable limits in drinking water standards (2 µg/L); inferentially, the synthesized imine-based COF indicated an ultra-high affinity for Hg 2+ ions with outstandingly fast kinetics. This material is offering new perspectives for the utilization of such covalent organic frameworks in mercury removal and environmental remediation applications.
During the same year of 2017, Sun et al. [77] developed a two-dimensional mesoporous covalent organic framework featuring dense and flexible thiol and thioether chelating arms. The as-synthesized COF indicated very high Hg 0 and Hg 2+ adsorption capacity, 863 and 1350 mg/g respectively, a high affinity for Hg 2+ with impressive distribution coefficient values at a wide pH range from 3 to 10, as well as exceptionally fast kinetics for the adsorption of Hg 2+ . Their results verified the great potential of covalent organic frameworks as an adsorbent material towards Hg 2+ .
Leus and co-workers in 2018 [78] synthesized a composite material consisting of a covalent triazine framework (denoted as CTF-1) hosting Fe 2 O 3 (in the maghemite γ-Fe 2 O 3 phase) nanoparticles. The adsorption capacity of γ-Fe 2 O 3 @CTF-1 reached 165.8 mg/g for Hg 2+ , which is significantly higher compared to pure covalent triazine frameworks and other iron-based materials. The as-prepared composite material could also be reused for several cycles, maintaining good adsorption capacity.
Moreover, Fu et al. [79] presented a novel technology for the fabrication of porous covalent polytriazines with rich sulfur contents (13.2 wt%). The synthesized networks were characterized by enhanced physical and chemical stability, as well as high adsorption capacity and removal efficiency towards mercury ions, even at very low initial concentrations; thus, these CTFs constitute promising adsorbent materials for wastewater treatment and water decontamination applications.
In 2019, Mondal and co-workers [80] fabricated a thioether-functionalized covalent triazine network (SCTN-1) through an ionothermal method, which indicated an exceptionally high Hg 0 and Hg 2+ adsorption capacity (813 and 1253 mg/g, respectively). These researchers demonstrated that the removal of toxic mercury, using the synthesized organic porous material, is subserved by a facile operational process, fast adsorption kinetics, high distribution coefficients, as well as ease of regeneration of the adsorbent. The aforementioned characteristics render these COFs a quite promising adsorbent material towards Hg 2+ (Figure 2). tionally high Hg 0 and Hg 2+ adsorption capacity (813 and 1253 mg/g, respectively). These researchers demonstrated that the removal of toxic mercury, using the synthesized organic porous material, is subserved by a facile operational process, fast adsorption kinetics, high distribution coefficients, as well as ease of regeneration of the adsorbent. The aforementioned characteristics render these COFs a quite promising adsorbent material towards Hg 2+ ( Figure 2). Additionally, Wang et al. [81] used a porous covalent organic framework as a support for the in-situ growth of silver (Ag) nanoparticles through a facile one-step solution infiltration method. The as-prepared AgNPs@COF material proved to be a quite promising adsorbent for Hg 2+ ions from an acidic solution, regarding its fast adsorption kinetics, its high adsorption capacity, its very high Ag atom utilization, its enhanced stability and selectivity, as well as its reusability; therefore, this material offers new prospects for the utilization of covalent organic frameworks as supporting platforms for the immobilization of metal nanoparticles that could be used in acidic wastewater treatment applications.
He et al. [82] fabricated a novel covalent organic framework polymer through Suzuki polymerization of two monomers based on triarylamine derivatives. On the basis of that polymer, they further developed a Schiff base COF polymer fluorescent sensor for efficient detection and removal of Hg 2+ ions.
Tao and his co-workers, in 2020, reported the synthesis of a porous SO3-anchored covalent organic framework for Hg 0 and Hg 2+ adsorption [83]. The results indicated that the as-prepared material presents ultrahigh adsorption capacity for both Hg 0 and Hg 2+ fast adsorption kinetics, strong binding affinity, high selectivity, and good reusability.
Moreover, Panda et al. [84] developed a novel, metal-free, fluorescent covalent organic framework acting as a chemosensor for the simultaneous detection and removal of Hg 2+ ions ( Figure 3). More specifically, the fabricated COF was characterized by extended π-conjugation and large pore size, presenting the ability to act as a highly durable sensor for the detection of Hg 2+ , as well as high removal efficiency equal to 99.8% (pH = 7, 273 K) Additionally, Wang et al. [81] used a porous covalent organic framework as a support for the in-situ growth of silver (Ag) nanoparticles through a facile one-step solution infiltration method. The as-prepared AgNPs@COF material proved to be a quite promising adsorbent for Hg 2+ ions from an acidic solution, regarding its fast adsorption kinetics, its high adsorption capacity, its very high Ag atom utilization, its enhanced stability and selectivity, as well as its reusability; therefore, this material offers new prospects for the utilization of covalent organic frameworks as supporting platforms for the immobilization of metal nanoparticles that could be used in acidic wastewater treatment applications.
He et al. [82] fabricated a novel covalent organic framework polymer through Suzuki polymerization of two monomers based on triarylamine derivatives. On the basis of that polymer, they further developed a Schiff base COF polymer fluorescent sensor for efficient detection and removal of Hg 2+ ions.
Tao and his co-workers, in 2020, reported the synthesis of a porous SO 3 -anchored covalent organic framework for Hg 0 and Hg 2+ adsorption [83]. The results indicated that the as-prepared material presents ultrahigh adsorption capacity for both Hg 0 and Hg 2+ , fast adsorption kinetics, strong binding affinity, high selectivity, and good reusability.
Moreover, Panda et al. [84] developed a novel, metal-free, fluorescent covalent organic framework acting as a chemosensor for the simultaneous detection and removal of Hg 2+ ions ( Figure 3). More specifically, the fabricated COF was characterized by extended πconjugation and large pore size, presenting the ability to act as a highly durable sensor for the detection of Hg 2+ , as well as high removal efficiency equal to 99.8% (pH = 7, 273 K). Additionally, this material currently constitutes one of the few metal-free sensors and adsorbents available, able to be utilized in several industrial wastewater treatment applications.
Furthermore, in 2020, Ma and his research team [85] developed a sulfhydryl (-SH)modified COF by a one-step reaction for the removal of Hg 2+ ions from water. The synthesized covalent organic framework exhibited high adsorption capacity (1283 mg/g) towards Hg 2+ ions, with a value more than 25 times higher than that of the COF without the presence of -SH. The material exhibited fast adsorption kinetics, attaining removal equal to 95% of 1000 µg/L Hg 2+ within 30 min and above 99% after 2 h. Furthermore, it exhibited removal efficiency of more than 99%, under a wide pH range, as well as selectivity towards Hg 2+ ions' adsorption in the presence of other metal cations. As a result, the aforementioned COF-SH material has great potential for Hg 2+ removal from water and wastewater samples under complex conditions (Figure 4). Additionally, this material currently constitutes one of the few metal-free sensors and adsorbents available, able to be utilized in several industrial wastewater treatment applications. Furthermore, in 2020, Ma and his research team [85] developed a sulfhydryl (-SH)modified COF by a one-step reaction for the removal of Hg 2+ ions from water. The synthesized covalent organic framework exhibited high adsorption capacity (1283 mg/g) towards Hg 2+ ions, with a value more than 25 times higher than that of the COF without the presence of -SH. The material exhibited fast adsorption kinetics, attaining removal equal to 95% of 1000 μg/L Hg 2+ within 30 min and above 99% after 2 h. Furthermore, it exhibited removal efficiency of more than 99%, under a wide pH range, as well as selectivity towards Hg 2+ ions' adsorption in the presence of other metal cations. As a result, the aforementioned COF-SH material has great potential for Hg 2+ removal from water and wastewater samples under complex conditions (Figure 4).   Furthermore, in 2020, Ma and his research team [85] developed a sulfhydryl (-SH)modified COF by a one-step reaction for the removal of Hg 2+ ions from water. The synthesized covalent organic framework exhibited high adsorption capacity (1283 mg/g) towards Hg 2+ ions, with a value more than 25 times higher than that of the COF without the presence of -SH. The material exhibited fast adsorption kinetics, attaining removal equal to 95% of 1000 μg/L Hg 2+ within 30 min and above 99% after 2 h. Furthermore, it exhibited removal efficiency of more than 99%, under a wide pH range, as well as selectivity towards Hg 2+ ions' adsorption in the presence of other metal cations. As a result, the aforementioned COF-SH material has great potential for Hg 2+ removal from water and wastewater samples under complex conditions ( Figure 4).  Finally, Yu et al. [86] reported the synthesis of a reaction-based recyclable fluorescent covalent organic framework, functionalized by allyl together with hydroxy groups (AH-COF), for the detection and effective removal of Hg 2+ ions and suitable for utilization in noxious wastewater treatment applications.

Removal of Lead
The main anthropogenic sources of lead ions (Pb 2+ ) are battery, smelting, mining, and plating industries, plus ceramic glass industries [87][88][89]. The reported Pb 2+ toxicity is fatal to living organisms, damaging human brain, liver, kidneys, and reproductive system [87,88]. Higher amounts of lead accumulation in fresh water may pose health risks and an increase in diseases, such as encephalopathy and hepatitis [87,90,91]. The acceptable limits are 0.05 mg/L, as set by the US Environmental Protection Agency, and 0.01 mg/L, which is regulated by the European Union Countries [87].
In 2018, Gupta and co-workers [92] synthesized an ionic covalent organic framework for the removal of Pb 2+ ions from aqueous solutions through an ion exchange process. Their study suggested that the synthesized COF material might be an intriguing candidate for water-decontamination applications (Table 2).
Additionally, in 2018, Zhang et al. [93] synthesized a TAPB-DMTP-COF (TAPB, 1,3,5tris (4-aminophenyl)benzene; DMTP, 2,5-dimethoxyterephaldehyde) as a novel electrochemical sensor for the detection of Pb 2+ ions in an aqueous medium. Pb 2+ ions were bound to the TAPB, DMTP-modified covalent organic framework's surface through complexation with amine groups. Given the COFs' exceptional structural characteristics, the designed sensor demonstrated both fast electron transfer rate and high lead adsorption capacity. The as-developed composite COF material indicated a broad linear range, low detection limit, improved sensitivity, good stability, as well as reproducibility, due to its active sites and high surface area. The authors concluded that the aforementioned features suggest that COF-based sensors will constitute an asset in clinical diagnostics and environmental remediation.
Li et al. [26] fabricated two amide-based covalent organic framework materials through a polymerization reaction of acyl chloride and amino groups via mechanochemical ball-milling at room temperature, in order to be utilized as Pb 2+ adsorbents. More specifically, for the COFs' synthesis, two types of diamine monomers were chosen, characterized by different framework structure, as well as functional groups (i.e., COF-TP from aromatic diamine monomer of p-phenylenediamineand COF-TE from linear diamine monomer of ethylenediamine). The as-developed COF materials presented a typical lamellar structure, while the amide groups on COFs' skeleton were confirmed to act as active adsorption sites for Pb 2+ ions. COF-TE presented greater Pb 2+ adsorption capacity than COF-TP, due to the fact that the smaller aromatic skeleton and weak π-π stacking of the former facilitates higher internal diffusion of Pb 2+ . In addition, COF-TE was characterized by a higher amide group content, which led to an improved saturated adsorption capacity (185.7 mg/g), compared to that of COF-TP (140 mg/g). Finally, they concluded that the enhanced recyclability of Pb 2+ adsorption facilitates amide-based covalent organic frameworks as promising Pb 2+ -adsorbent materials.
Xu and co-researchers [94] suggested a facile method for the development of covalent organic framework, modified with PVDF (poly (vinylidene fluoride)) ultra-filtration membranes of high Pb 2+ removal ability. The removal efficiency of the synthesized COF membranes was equal to 92.4%, while it was determined at 87.5% during the fourth reusability cycle. Thus, this novel composite material comprises an efficient medium for the treatment of Pb 2+ -containing water and wastewater.
Finally, Cao et al. [95] fabricated a novel covalent organic framework via a moderate solvothermal solution-suspension synthetic route for efficient Pb 2+ removal from aqueous solution. The synthesized COF material was characterized by a typical lamellar structure, while the sulfhydryl groups on the COF's skeleton were confirmed to act as active Pb 2+ adsorption sites. The sulfhydryl-functionalized COF material reached an adsorption equilibrium within 48 h and presented a maximum Pb 2+ adsorption capacity of 239 mg/g, a value much higher than that of conventional adsorbent materials.

Removal of Chromium
Chromium (VI) constitutes one of the major water pollutants, and when it is found at a concentration higher than 100 ppb in drinking water, it is very likely to cause severe damage to living organisms, because of its carcinogenic and mutagenic properties, as well as strong oxidizing power [96].
Taking into consideration the increasing demand for functional materials, which can achieve fast and efficient removal of noxious heavy metals from groundwater and industrial wastewater, Jansone-Popova and co-researchers in 2018 synthesized [96] a novel covalent organic framework solvothermally in a one-step method through a polycondensation reaction. The combination of its building blocks was selected, in order to promote the formation of 2D sheets, in which guanidinium groups were located on the edges of the hexagonal pores. Guanidinium, a positively charged nitrogen analogue of urea, was utilized as it is known to develop strong ion pairs with oxoanions due to electrostatic forces and non-covalent hydrogen-bonding interactions. The as-prepared COF material could adsorb 90-200 mg/g of Cr 6+ ion, depending on the solution's pH, displaying advanced characteristics among known ion exchange materials and conventional adsorbents.
Cui et al. [97] developed a novel dual-pore covalent organic framework possessing hydroxyl groups, in order to remove hexavalent chromium from aqueous solutions. The prepared material presented fast adsorption kinetics (272 mg/g Cr 6+ within 10 min), as well as a maximum adsorption capacity of the order of 384 mg/g Cr 6+ , and this value is among the highest ones reported for porous materials so far.
In 2020, Zhong and co-workers [98] fabricated a magnetic covalent organic framework with β-ketoenamine linkage through a hydrothermal synthetic route characterized by facile preparation, high stability, enhanced Cr 6+ adsorption capacity (245.45 mg/g) and good reusability ( Figure 5). These features make the aforementioned material a potential candidate in environmental remediation applications. Taking the aforementioned into account, Leus et al. [78] developed a composite material consisting of a covalent triazine framework (CTF-1) and γ-Fe2O3 nanoparticles. The resulting γ-Fe2O3@CTF-1 was examined for the adsorption of As 3+ and As 5+ from synthetic solutions, as well as real surface-, ground-, and wastewater. The prepared composite material indicated great removal efficiency towards both arsenite (198 mg/g) and arsenate (102.3 mg/g), which is quite higher than conventional adsorbents, demonstrating its applicability in water decontamination and wastewater treatment applications.
Yang et al. [103] synthesized an EB (Ethidium Bromide)-COF:Br material ( Figure 6) as an arsenate adsorbent with high adsorption capacity, while Liu and co-workers [104] fabricated Fe 0 /COFs that exhibited good performance in As 3+ adsorption, and the maximum adsorption capacity was 135.78 mg/g. Such composites exhibit a great potential for As removal in wastewater treatment applications. Finally, also in 2020, Zhu and co-workers [99] successfully synthesized two COFs with different hydroxyl group distributions (COF1 and COF2). Both covalent organic frameworks indicated good Cr 6+ adsorption capacity (Table 2) within a wide pH range and enhanced Cr 6+ selectivity in mixed ion solutions, rendering them potential materials for adsorption applications.

Removal of Arsenic
Arsenic (As) constitutes a harmful metalloid and well-known carcinogen, and it is considered one of the most abundant elements in the Earth's crust [100,101]. The major sources of arsenic contamination in ecosystems originate from both geogenic and anthropogenic activities, such as natural deposits in rocks and sediments, geothermal water, and environmental pollution. The presence of arsenosulfides and arsenides in the geothermal and marine environments result to the uninterrupted accumulation of noxious As species (organic and inorganic), which comprise a potential threat to terrestrial and aquatic flora and fauna [100]. The distribution and speciation of arsenic in the groundwater is driven by a biological oxidation/reduction process (geochemical cycle) of organic substrates that releases arsenic from the hydro-geosphere environments [100,102]. Inorganic arsenite As 3+ (reducing) and arsenate As 5+ (oxidizing) can induce chronic toxicity to human health through mitigation to food chains, depending on the surrounding geochemical equilibrium systems [100,102]. Considering the negative physiological effect of As-exposure on human health and its frequent detection in the groundwater above the World Health Organization maximum contaminant level (>10 µg/L), it is necessary to develop novel materials for arsenic-decontamination applications.
Taking the aforementioned into account, Leus et al. [78] developed a composite material consisting of a covalent triazine framework (CTF-1) and γ-Fe 2 O 3 nanoparticles. The resulting γ-Fe 2 O 3 @CTF-1 was examined for the adsorption of As 3+ and As 5+ from synthetic solutions, as well as real surface-, ground-, and wastewater. The prepared composite material indicated great removal efficiency towards both arsenite (198 mg/g) and arsenate (102.3 mg/g), which is quite higher than conventional adsorbents, demonstrating its applicability in water decontamination and wastewater treatment applications.
Yang et al. [103] synthesized an EB (Ethidium Bromide)-COF:Br material ( Figure 6) as an arsenate adsorbent with high adsorption capacity, while Liu and co-workers [104] fabricated Fe 0 /COFs that exhibited good performance in As 3+ adsorption, and the maximum adsorption capacity was 135.78 mg/g. Such composites exhibit a great potential for As removal in wastewater treatment applications. Taking the aforementioned into account, Leus et al. [78] developed a composite material consisting of a covalent triazine framework (CTF-1) and γ-Fe2O3 nanoparticles. The resulting γ-Fe2O3@CTF-1 was examined for the adsorption of As 3+ and As 5+ from synthetic solutions, as well as real surface-, ground-, and wastewater. The prepared composite material indicated great removal efficiency towards both arsenite (198 mg/g) and arsenate (102.3 mg/g), which is quite higher than conventional adsorbents, demonstrating its applicability in water decontamination and wastewater treatment applications.
Yang et al. [103] synthesized an EB (Ethidium Bromide)-COF:Br material ( Figure 6) as an arsenate adsorbent with high adsorption capacity, while Liu and co-workers [104] fabricated Fe 0 /COFs that exhibited good performance in As 3+ adsorption, and the maximum adsorption capacity was 135.78 mg/g. Such composites exhibit a great potential for As removal in wastewater treatment applications.

Removal of Cadmium
Among heavy metals, cadmium (Cd) constitutes one of the most dangerous heavy metals, as its solubility is greater compared to other heavy metals and it can be easily transferred to the biosystem [105]. Cadmium has been listed as a category-I carcinogen by the International Agency for Research on Cancer and as a group-B1 carcinogen by the US Environment Protection Agency (EPA) [106,107]. Its compounds are noxious and can accumulate in several parts of the human body, such as the nervous, reproductive, renal, and skeletal system, leading to cadmium-related diseases, such as emphysema, kidney failure, itai-itai disease, hypertension, and testicular atrophy [106,108].
In 2019, Liu et al. [108] synthesized a novel heteropore covalent organic framework, in order to be utilized for the adsorption of Cd 2+ from aqueous solutions. The produced COF presented ultra-high chemical stability towards water under several pH values, while it also exhibited hierarchical porosity, enhanced crystallinity, high surface area (1476.5 m 2 /g), as well as a plethora of accessible metal ion chelating sites. The as-mentioned COF that Liu and his co-researchers developed indicated good recyclability, fast adsorption rates (39.6 mg/g at 1 min and 95.6 mg/g in 20 min), and an exceptional Cd 2+ adsorption capacity (116 mg/g).

Removal of Iodine
Water contamination with radioactive iodine derives mainly from two sources. The first source is atomic reactors which depend on the fission of uranium atoms, including the production of radioactive iodine as a by-product material [109]. Radioactive iodine is released to the environment from operating nuclear reactors. The second source of radioactive iodine-contaminated wastewater is hospitals, because they use large amounts of radioactive isotopes for diagnostic and therapeutic applications [109].
Yin et al. [110] demonstrated that covalent organic frameworks presented a very high adsorption capacity towards volatile iodine (4810 mg/g) because of the encapsulation of iodine into the inner cavities and porous shells of the microspheres. Almost 96% of iodide was adsorbed by COFs after the fifth adsorption-desorption cycle, displaying adequate selectivity and reusability. Additionally, in 2017, Lin and co-researchers [111] synthesized a network with a microporous elastic hydrogen-bonded cross-linked organic framework (H C OFs). The material demonstrated high adsorption capacity equal to 2900 mg of I 2 vapor per gram, as well as a fast equilibrium rate (~30 min).
Moreover, in 2018, Wang et al. [112] fabricated five different kinds of two-dimensional covalent organic frameworks with various pore sizes, ranging from 2.2 to 3.3 nm, and observed that the adsorption capacities were improved with the increase of the pore size. Almost 70 wt% of iodine vapor was captured by COFs, even under moderate temperature, indicating an exceptional adsorption performance. In general, according to their research, the iodine's adsorption mechanism on covalent organic frameworks was mainly induced by Van der Waals interaction and the hydrophobic nature of inner cavities of porous COFs' microspheres.
Then, in 2018 [113], the synthesis of novel COFs was characterized by good stability upon irradiation. The extremely high COFs' uptake capacity (5.43 g/g) was attributed to the nitrogen-rich groups and electron-rich π-conjugated interaction. According to their study, volatile I 2 was converted into I 5 − due to an electron transfer. Li and co-researchers [114], utilizing a rapid cryogenic reaction, covalently functionalized an imine-linked two-dimensional covalent organic framework with cotton fiber through an imine condensation reaction. The as-developed COF@cotton fiber material was characterized by a plethora of imine functional groups and dispersed mesoporous holes, features that resulted in the fast adsorption rate and high iodine affinity, characterized by uptake capacities up to 533.9 mg/g.
In 2021, Chen et al. [115] synthesized a crystalline mesoporous nitrogen-containing covalent organic framework through an imine condensation reaction, in order to be utilized as a highly efficient iodine adsorbent (Figure 7). The as-synthesized COF material exhibited a porous structure with high BET surface area (1082 m 2 /g), exceptional thermal and chemical stability, and a plethora of nitrogen sites in its skeleton, where an excellent adsorption of iodine (up to 988.17 mg/g) took place at room temperature. These results suggest the great potential of the developed COF for addressing the problem of nuclear fission waste contamination that threatens human health. covalent organic framework through an imine condensation reaction, in order to be utilized as a highly efficient iodine adsorbent (Figure 7). The as-synthesized COF material exhibited a porous structure with high BET surface area (1082 m 2 /g), exceptional thermal and chemical stability, and a plethora of nitrogen sites in its skeleton, where an excellent adsorption of iodine (up to 988.17 mg/g) took place at room temperature. These results suggest the great potential of the developed COF for addressing the problem of nuclear fission waste contamination that threatens human health.
Li et al. [118] proved that PAF-1-CH2-AO (amidoxime-functionalized PAF-1) indicated a high adsorption capacity equal to 300 mg/g, while the uranyl concentration decreased from 4.1 ppm to less than 1.0 ppb, which was quite below the acceptable limit of the US EPA.
Additionally, in 2018, Wen et al. [119] synthesized AO-COF/graphene composites (oxime-modified graphene-synergized COF or o-GS-COF) characterized by high irradiation and acid stability, because of the π-π interaction of intra-and inter-layer reactive groups. Their results indicated that AO-modified COFs could constitute potential candidates for enhanced selective adsorption of U(VI) in real environmental remediation applications.
Li et al. [118] proved that PAF-1-CH 2 -AO (amidoxime-functionalized PAF-1) indicated a high adsorption capacity equal to 300 mg/g, while the uranyl concentration decreased from 4.1 ppm to less than 1.0 ppb, which was quite below the acceptable limit of the US EPA.
Additionally, in 2018, Wen et al. [119] synthesized AO-COF/graphene composites (oxime-modified graphene-synergized COF or o-GS-COF) characterized by high irradiation and acid stability, because of the π-π interaction of intra-and inter-layer reactive groups. Their results indicated that AO-modified COFs could constitute potential candidates for enhanced selective adsorption of U(VI) in real environmental remediation applications.

Other Metals
In this section, we will emphasize on the removal of various other metals, except the aforementioned which were the focus of the article (Table 2). In 2018, Zhou and his co-researchers [121] designed a fluorescent covalent organic framework characterized by an accurate distribution of thioether pendant arms inside its cavities as binding sites for Au 3+ ions. The COF was solvothermally fabricated through a reversible imine condensation reaction of 2,5-bis(2-(ethylthio)ethoxy) terephthalohydrazide (BETH) and 1,3,5-triformylbenzene (TFB). The as-mentioned thioether-functionalized COF (TTB-COF) exhibited selective sensing, as well as capture of Au 3+ ions at ultra-trace levels in water ( Figure 8). It is important to highlight that it presented selective attraction of Au 3+ ions over other metal ions, even at very low concentration levels, through significant luminescence quenching via the strong and selective affinity of sulfur atoms towards Au 3+ ions.
In addition, in 2018, Lu et al. [122] reported the fabrication of a 3D carboxy-functionalized covalent organic framework (3D-COOH-COF) by post-synthetic alteration of a hydroxyfunctionalized COF, in order to be utilized for the selective extraction of lanthanide ions (Nd 3+ , Sr 2+ , and Fe 3+ ). The 3D-COOH-COF indicated enhanced adsorption capacity of the examined lanthanide ions, according to the Langmuir adsorption isotherms, while reusability experiments confirmed that the adsorption uptake of the as-mentioned COF is sparsely decreased. accurate distribution of thioether pendant arms inside its cavities as binding sites for Au 3+ ions. The COF was solvothermally fabricated through a reversible imine condensation reaction of 2,5-bis(2-(ethylthio)ethoxy) terephthalohydrazide (BETH) and 1,3,5-triformylbenzene (TFB). The as-mentioned thioether-functionalized COF (TTB-COF) exhibited selective sensing, as well as capture of Au 3+ ions at ultra-trace levels in water ( Figure  8). It is important to highlight that it presented selective attraction of Au 3+ ions over other metal ions, even at very low concentration levels, through significant luminescence quenching via the strong and selective affinity of sulfur atoms towards Au 3+ ions. In addition, in 2018, Lu et al. [122] reported the fabrication of a 3D carboxy-functionalized covalent organic framework (3D-COOH-COF) by post-synthetic alteration of a hydroxy-functionalized COF, in order to be utilized for the selective extraction of lanthanide ions (Nd 3+ , Sr 2+ , and Fe 3+ ). The 3D-COOH-COF indicated enhanced adsorption capacity of the examined lanthanide ions, according to the Langmuir adsorption isotherms, while reusability experiments confirmed that the adsorption uptake of the as-mentioned COF is sparsely decreased.
Cai et al., in 2019 [123], fabricated a fluorescent covalent organic framework utilizing Q-graphene scaffolds through melamine-aldehyde and phenol-aldehyde polycondensation reactions (Figure 9). Cai and his co-researchers found that the synthesized COF displayed high green fluorescence, as well as enhanced stability and Cu 2+ ions adsorption capacity. As a result, they developed a fluorimetric strategy, in order to probe Cu 2+ ions in blood and wastewater. The prepared covalent organic framework presented improved removal efficiency regarding Cu 2+ ions, and low detection limit of Cu 2+ ions (0.50 nM for blood samples and 24 nM for wastewater samples). They assumed that the novel synthetic route they proposed could pave the way towards the development of covalent organic frameworks to be used in metal removal applications, environmental monitoring, and biomedical sensing. Cai et al., in 2019 [123], fabricated a fluorescent covalent organic framework utilizing Q-graphene scaffolds through melamine-aldehyde and phenol-aldehyde polycondensation reactions (Figure 9). Cai and his co-researchers found that the synthesized COF displayed high green fluorescence, as well as enhanced stability and Cu 2+ ions adsorption capacity. As a result, they developed a fluorimetric strategy, in order to probe Cu 2+ ions in blood and wastewater. The prepared covalent organic framework presented improved removal efficiency regarding Cu 2+ ions, and low detection limit of Cu 2+ ions (0.50 nM for blood samples and 24 nM for wastewater samples). They assumed that the novel synthetic route they proposed could pave the way towards the development of covalent organic frameworks to be used in metal removal applications, environmental monitoring, and biomedical sensing. The following year, Li and his team (2020) [124] prepared, through the solvothermal method, a magnetic Fe3O4-MOF-COF composite material for the selective adsorption of Cu 2+ ions. The composite material showed fast separation, enhanced stability, and high adsorption capacity (37.29 mg/g) towards Cu 2+ ions. Li et al. proposed that the COF addition in the composite material improved the Cu 2+ adsorption capacity. As a result, the prepared novel Fe3O4-MOF-COF material could be utilized for the rapid and sensitive detection and adsorption of Cu 2+ ions. The following year, Li and his team (2020) [124] prepared, through the solvothermal method, a magnetic Fe 3 O 4 -MOF-COF composite material for the selective adsorption of Cu 2+ ions. The composite material showed fast separation, enhanced stability, and high adsorption capacity (37.29 mg/g) towards Cu 2+ ions. Li et al. proposed that the COF addition in the composite material improved the Cu 2+ adsorption capacity. As a result, the prepared novel Fe 3 O 4 -MOF-COF material could be utilized for the rapid and sensitive detection and adsorption of Cu 2+ ions.
In 2021, Liu et al. [125] utilized a facile and effective reaction process, in order to develop an adenine-grafted COF to be used for the adsorption of Ag + ions. Due to the coordination between Ag + ions and adenine groups, the moderate pore structure, and the good surface area, the as-synthesized covalent organic framework showed a high Ag + selectivity and adsorption capacity (40 mg/L), as well as good recyclability. The authors concluded that the proposed adenine-grafted COF could provide a novel prospect for the utilization of such COF materials in water purification and environmental restoration. Moreover, the derived Ag-COF material could be used for antimicrobial applications since it is well-known that silver is an excellent antimicrobial agent.

Comparison of Covalent Organic Frameworks with the Competitive Systems
Covalent organic frameworks are an emerging class of functional materials. Due to their functionality and potential of bearing a wealth of side groups, they have found applications, such as adsorption, catalysis, sensing, electronics, and energy storage. Their directly competitive systems are the metal-organic frameworks, graphene oxide, the activated carbons, and the zeolites. For instance, metal organic frameworks (MOFs) constitute versatile materials, utilized in different fields, due to high surface area and adsorption capacity [8,126]. In spite of applicability, MOFs face a number of disadvantages, such as ions leakage, low stability, and low conductivity [5]. As a consequence, it is necessary to continuously develop alternative advanced materials, in order to achieve efficient and high-capacity adsorption.
Compared to other materials, COFs possess unique properties, such as high adsorption capacity (Table 3), low density, high specific surface area (for 2D COFs is 711-2160 m 2 /g and for 3D COFs is 1360-4210 m 2 /g), tunable, ordered, and stable structure, exceptional physical, chemical stability and pore structure, modularity, low mass densities, facile functional design, as well as luminous characteristics in some cases, after the integration of luminescent units into COFs' skeleton [7,8,24,25,127,128]. The topological frameworks of the COFs result in their exceptional porous structure, while porosity and crystallinity constitute the main attributes affecting the quality of COFs [24].
The outstanding stability of COFs is ascribed to the high-energy linkage (50-110 kcal/mol), as well as to the strong intermolecular force, due to the nodes-layers interaction, which prevents the collapse of the crystallography even at severe conditions [25]. The majority of COFs exhibit moderate thermal stability; thus, their stability in aqueous and acidic/alkaline solutions retains a crucial drawback for some types of COFs (e.g., Boron-based), precluding their utilization in water treatment applications. Worldwide, researchers implement various strategies, in order to refine the structural stability of COFs. Some of these strategies include linkage conversion [24,47], linkers' modifications [24,45], and blending [24,120]. In addition, the softened force of covalent bonds between layers enhances the entire connection structure for 3D COFs, due to the resonance effect of long-pair oxygen [25,68].
The aforementioned advantages along with the development of stable COFs in water medium and even in harsh conditions have resulted in the extension of COFs' application from gas storage to other fields, while their environmental application potentials are gradually noticed and highly valued [29,38,83,87,129].
In addition, they consist of light elements only, C, Si, O, B, and N, while no metals are required for the formation of COFs, which makes them appealing in terms of biocompatibility and low production cost. However, in contrast with their competitors, no COF has been commercially available until now. Furthermore, very high absorption values have been reported for MOFs, composite materials based on MOFs, zeolites, and functionalized graphene oxide surfaces [130][131][132][133]. Table 3. Summary of the values for lead and mercury adsorption between three main classes of materials.

Perspectives on the Large-Scale Industrial Applications-Room for Improvement
For a material that can be applied in real-life applications regarding the removal of toxic metals from aquatic environments, the ease of preparation, low cost, processability, and recyclability are of paramount importance. In general, the yields of condensation reactions for the synthesis of covalent organic networks are particularly high. As an example, an imine-based COF reported by Huang et al. [41] was synthesized with a yield of 84%, while Bourlinos et al. reported a yield of 90% for the same product [139]. Therefore, the presence of by-products is minimized, and the materials can be synthesized on a large, industrial scale. The only drawback is that, for certain materials, a bespoke ligand is required, hence more delicate organic synthesis methods with higher costs and lower yields need to be employed. Zhao et al. summarized the perspective on the industrial applications of COFs [140]. The review covered aspects such as the continuous flow synthesis by utilizing microfluidic devices, catalysis, carbon dioxide capture, and energy storage applications. From the different systems that we have already discussed, the imine-based frameworks appear to be the most promising candidates for industrial-level production and applications. Karak et al. [141] demonstrated methodologies to synthesize covalent organic frameworks on a large scale. The use of certain additives such as ptoluenesulfonic acid was found to be critical for the industrial applications of the derivatives. For a large-scale application of a material, a certain control on the morphology, size, and shape is necessary. The growth mechanism and reaction parameters for their synthesis were studied in detail by Huang's group [142]. They found that initial precipitates of irregular nanoparticles are produced in the initial stages of the reaction, and subsequently, the nanoparticles evolve to microspheres and finally to nanofibers with a simultaneous amorphous-to-crystalline change. An extruder can also be used to produce kg per hour of COFs for a continuous synthesis process, and this appears as a very promising step for scaled-up synthetic pathways. They have also developed a liquid-assisted grinding (LAG) method [31] and synthesized crystalline COFs. The reaction took place at a faster rate and in high yield by optimizing the reaction conditions [143].
A drawback is that mechanochemically synthesized COFs do not have high crystallinity and porosity. Furthermore, kinetic trapping in certain morphologies is leading to limited topologies and lack of sufficient understanding on the growth mechanisms [144]. This kinetic trapping of amorphous structures can be overcome through effective catalysts for nucleation inhibition and hence increased crystallinity.

Biocompatibility of COFs: Are There Any Dangers/Drawbacks When Using Them in Aquatic Environments?
The emphasis of this review was placed on the detection and the adsorption as well as the extraction of heavy metals with a variety of COFs in different environments. The physicochemical properties, surface area, stability, and modularity are a few of the positive aspects that the COFs provide for these applications. A plausible point of controversy exists and the question that arises is if in their purely organic components, there is a possibility of noxious substances constituting and decomposing from the COFs in the biological systems, in this way refuting their utility to deliver environmentally friendly applications.
COFs are designed in precision from chosen initial molecules and are constructed from synthetic routes that are highly controllable, as referred to before. The selection of biocompatible core and linkages for their production is the primary and necessary step to ensure the biosafety of the networks. They are composed from lightweight elements that are abundant in nature, such as C, O, N, and B, and one of their assets is the lack of inorganic substances composing their frameworks. As metal-free materials, they also reduce the levels of toxicity in comparison to the heavy metal-involved nanomaterials and other composites [145]. Then, a top-down approach is needed to obtain COFs at the nanoscale, as the size determines its reactivity, its cellular uptake, distribution, cytotoxicity, and excretion from the human body [146]. Any difficulty of the COFs dispersion in aqueous solutions is addressed by functionalization with hydrophilic groups or encapsulation with other organic derivatives. A restriction that must be taken into consideration is that some of the COFs are unstable in harsh environments. The materials must be tested prior to their incorporation in environmental applications, in highly acidic and alkaline environments, as, for example, the pH of wastewater is not neutral. Their recyclability is successful, but as the COFs sector is still in its infancy, there is a lot to anticipate in the next years. Even though there are studies proving their efficiency in different applications, we did not find a dedicated research of the COFs' hazardous risks in aqueous environments. On the other hand, biosafety is referred to in the biomedical area [147]. Recently, appropriate COFs were developed for pre-treatment of chlorinated drinking water [148], for water treatment [149], for separation membranes [150], adsorption [151], and extraction of organic substances, among all [152,153]. Furthermore, biocompatible COFs for biomedicine [154,155], cancer diagnosis, and treatment in vitro and in vivo (rats and human serums) have been reported [156][157][158].
Herein, we will only report an example of applicable COFs for photothermal therapy, where with further modification and encapsulation with PEG of their 2D COF, biosafety was ensured in vivo (mice) and the framework was metabolized 24 h after injection. In this last section, we have defined what was already achieved and what remains to be for the application of COFs nanoplatforms in aqueous environments.

Conclusions
In this critical review, we discussed the applications of covalent organic frameworks for the removal of heavy metals from aquatic environments. Furthermore, we presented a comparison with their main competitive systems (zeolites and metal-organic frameworks), regarding their adsorption ability towards heavy metals. The COFs' adsorption capacity is comparable to that of zeolites and MOFs. The ability of the COFs to bear a wealth of functional binding groups and to tune their porous structure is their main advantage. Very high values have been reported for the removal of several heavy metals, and coupled with their biocompatibility, this makes them very promising candidates for large-scale industrial applications when certain improvements in the mechanistic study of their growth are made.