Bioactivities, Biomedical and Pharmaceutical Applications of Raw and Functionalized Clay Minerals: A Review

Clay minerals are alumino-silicates that are relatively abundant in nature and materials derived from them are usually of low cost. The chemical and biogeochemical properties of clay minerals are of interests to researchers. Several nanostructured clay hybrid materials resulting from ion exchange and covalent bonding have been synthesized for environmental use, like removal of inorganic pollutants, herbicides, and pesticides from solution. Clay minerals and derived materials possess diverse biological properties. They play a vital role in microbial inhibition that is driven by different factors such as pH, presence of metals and metal ions and accompanied by several mechanisms. Biomedical and pharmaceutical applications of clay materials have grown in recent years due to interests of researchers in finding low cost alternative materials for problem solving in the field of medicine and pharmaceutical sciences. In these fields, clay minerals and their derived materials are often used as dietary supplements, widely applied in drug formulations and delivery systems, dermatology, pelotherapy or fangotherapy. Clay minerals are also ingested to soothe intestinal tracts and to remove toxins. This review discusses comprehensively the bioactivities, biomedical and pharmaceutical applications of clay minerals and their derived materials.

of clay minerals greatly influences the type of microorganism that can inhabit the minerals phyllo sphere and environment.  [7].
The chemical and geobiological properties of clay minerals mediate the interactions between clays and microorganisms, giving rise to diverse mechanisms of interactions. Clay minerals are known to be biocidal in nature and are capable of inhibiting several microorganisms. Mineral pH, presence of metals and metal ions, ion exchange and adsorption properties are common factors that promote inhibition of microorganisms [11][12][13][14]. Clay minerals have been widely applied in the field of biomedical science most especially in the areas of drug delivery system, healing of various kinds of disease and ailments, source of dietary supplements, dermatology and in drug formulations [15][16][17]. Clay minerals are usually employed in drug formulations in order to increase drug solubility, stabilize photo-unstable drugs under ultraviolet radiation, and retard the release rate [18,19]. They are thus considered biomaterials with mild biological activities.Among

Clay Minerals and Mineralogy
Clay mineralogy has been studied for several years by many researchers which have led to advances in their applications. Recent advances in characterization and mineralogical evaluation of clay has led to the general classifications of clay minerals into three based on layer types [20]. This is also discussed in the recent work reported by Adekeye, et al. [7] on physicochemical and mineralogical evaluation of a Nigeria clay mineral. The classification of clay minerals is based upon the number and arrangement of tetrahedral and octahedral sheets in the basic structures of clay minerals. They are: 1:1 (e.g. kaolinite), 2:1 (e.g. smectite and vermiculite groups) and 2:1:1 (e.g, chlorite) clay minerals [20]. Instrumentation in characterization and mineralogical evaluation of clay has also enabled and enhanced the grouping of clay minerals into five. They are: Kaolinite, illite, chlorite, smectite and vermiculite [21]. Clay minerals are composed of hydrous aluminium layer silicates with structures similar to those of micas [22]. Unlike the micas, however, interlayers of clay minerals contain a low cationic charge that binds adjacent silicate sheets and can allow free flow of water molecules through the interlayer regions [23].
The arrangement of chemical components of clay minerals is responsible for their different chemical characteristics which include plasticity, ion exchange and adsorption [24]. The plasticity, ion exchange and adsorption characteristics of clay minerals differ from minerals to minerals [6].

BIO-CLAYS
Bio-clays are clays minerals derived from biological origin. They are usually formed as a result of metabolic actions of biological organisms, e.g, microorganisms [25]. Some researchers have been able to show the formation of clay minerals by microorganisms.
Ueshima and Tazaki [26] showed the formation of nontronite by mixing a natural ferrosiliceous groundwater with polysaccharides (dextrin and pectin). Fiore, et al. [27] also observed the formation of kaolinite in a solution containing oxalate and bacteria from peatmoss soil. In an experiment by Tazaki [28], he noticed the formation of biofilms on a glass slide leaned against the internal walls of an incubation vessel containing incubated sediment derived from the Passo Real Dam located in Portalegre, Brazil. The biofilms formed on the glass slide were free of pre-existing sediment (original sediment used in the experiment) and contained only newly formed minerals.
The incubated sediment consisted mainly of kaolinite, cristobalite, quartz and feldspar in contrast to the observed newly formed mineral which is composed of spheres of a Si-Fe-rich mineral, with little Al. The newly formed mineral was later characterized to be halloysite formed and developed on the bacterial cell walls, to mature there and then detach [28]. Sometimes, formation of a clay mineral by microorganism may involve biotransformation of one clay mineral to the other which might be as a result of microbial weathering.
Microbial weathering of clay minerals is the physical erosion of the mineral grainsby microbial growth and movements. Microbial weathering fosters process of clay minerals weathering by exposing fresh surfaces to chemical attack [29,30]. The evidence of biotransformation of clay minerals is seen in the study reported by Kim,et al. [31] who demonstrated a significant role of microbes in promoting the smectite-to-illite reaction at room temperature and one atmosphere within two weeks of experiment. Zhang, et al. [3] also reported that smectite-to-illite reaction can be catalyzed by thermophilic bacteria at diagenetically relevant temperatures. Up till date, there has been limited information on the bioactivity of microbial synthesized clay minerals and this could be an area for further research in bioapplication of clay minerals.

Inhibitory Activities of Clay Minerals and Derived Materials on Microorganisms
The activities of clay minerals on microorganisms have been  its mode of action [35]. It has been suggested that antibacterial activities of most naturally occurring clays that are of hydrothermal origin, containing illite-smectite (expandable clay) and reduced Fe phases are antibacterial in nature [36]. Several clay minerals have been successfully modified for improved physical, chemical and geotechnical properties for several applications including architecture,agriculture, pharmaceutical, medical, and other industrial applications [37][38][39]. Also, several materials have been synthesized from clay for similar applications. Synthetic antimicrobial clay materials prepared by exchanging their native ions with known antibacterial ions such silver ion Ag+have been reported [40][41][42]. The principle involves gradual release of the novel bioactive exchanged ions from the synthetic clay for longterm antibacterial effectiveness.
Thus far, silver-loaded clays have been the most investigated material and pursued more aggressively than other antibacterial chemical ion options, although there have been efforts on investigating copper-loaded clay mineral substrates as effective antimicrobial agents in recent times [43]. Copper-loaded vermiculite has been reported to have good antifungal and antibacterial activity Li, et al. [9]. Also, antimicrobial activities of tetracycline (TC) and minocycline-montmorillonites have been demonstrated by [4]. The   Marco, et al. [46] and greenhouse cucumbers in Canada [47].
Elizabeth, et al. [48] also reported the potential use of kaolin clay for disease control in greenhouse cucumbers. Up till date, there is still little information on the use of natural clay and derived materials in treating and managing plants pathogenic diseases caused by microorganisms. This could be an area for further investigation.

Healing and Medicinal Activities of Natural Clay Minerals and Derived Materials
The use of natural clay minerals as bioactive agents according  [55]. The physical adsorption of water and organic matter has been suggested to be the most common attribute of the healing properties of clays [56]. It was reported that the Uitoto people of the Colombian Amazon recognized and employed the curative properties of a naturally occurring clay majorly composed of kaolinite and smectite in the Colombian Amazon region.
They ingest the clay to alleviate diarrhea and digestive discomfort [57]. The clay was shown to be antibacterial using standard antimicrobial susceptibility testing [57]. Conversely, living things including microorganisms also require metal nutrients for proper functioning of the cells which are either derived from minerals, colloids, solutions or decaying organic matter. Clay minerals contain many of these bioactive metals in different concentrations [5]. Dissolution of the metals in runoff or underground water is a possible way by which human can absorb these essential minerals water. Also, microorganisms in the soil may benefit from these minerals either by dissolution, ion exchange mechanism or absorption for their biological functioning. The order of decreasing required amounts of metal nutrient requirements that can typically be provided by clay minerals have been shown to be K > Na > Mg > Ca > Fe >> Mn, Co, Zn, Cu, Si, Ni and Mo [8,58].  [59,60]. The resultant 5-FU/Mnt hybrid was expected to achieve in situ release for colorectal cancer therapy.
Organically modified montmorillonite has also been reported to have found application in bone-related biomedical in form of bonecement [61].

Clay Minerals as Dietary Supplements
The ingestion of natural clay minerals usually in form of suspension is commonly used as a source of dietary mineral supplement, as a detoxifying agent, and as an allopathic treatment of acute and chronic diarrhea [62]. The intentional consumption of soil materials, such as clays, by animals and humans is known as geophagy [63]. Geophagy is a poorly understood practice that is largely attributed to cultural practices, religious beliefs, medicinal benefits, psychological disorders, and dietary/nutritional needs [64,65]. Historically, it is believed to be practiced to remedy a physiological response to mineral nutrient deficiencies, such as calcium, magnesium, iron or zinc, to satisfy dietary nutritional requirement; to ease obsessive-compulsive disorder and psychosocial problems including anxiety [66,67]. However, studies and medical reports have shown that ingesting large amounts of clay (>200 grams per day) with high cation-exchange capacity can impede absorption of iron, zinc, and potassium, leading to iron, zinc, or potassium deficiencies [68][69][70][71][72][73]. Moderate ingestion of clays like kaolin containing minerals like iron, copper, zinc, calcium, and manganese and lacking high cation-exchange capacities could serve as nutritional supplements. In Nigeria, it has been reported that Women of the Tiv tribe eat sub-surface clay, particular during and shortly after pregnancy [74].

Mineralogical investigation of the clay found in this region
showed a higher concentration of calcium and magnesium relative to the surface soil [75]. The Tiv people are known as one of the only tribes that do not drink animal milk because milk-producing animals are susceptible to parasitic infections that are endemic in the area. The dietary intake of calcium and magnesium through clay minerals is thought to be minimal. It was reported that in 2014, the Department of Soil Science at Bihar Agricultural University, India discovered that Karu Paswan who is more than 100 years of age at a village of Babupur (Bakharpur) in Pirpainti Block of Bhagapur District in Bihar (India), has been daily eating a type specific soil of Ganga flood plain for over last 60 years as daily dietary supplements and for its therapeutic reasons [16].

Clay Minerals as Detoxifying Agents
It has been shown by several researchers that, in the acidic environment of the stomach, clay minerals could adsorb or bind directly with positively and negatively charged toxins, thereby serving as detoxifying agents [76][77][78][79]. There are drug formulations that have been reportedly sold over-the-counter that originally contained clay minerals such as kaolinite and attapulgite, for the treatment of diarrhea and intestinal illnesses and soothe gastrointestinal ailments Vermeer and Ferrell [74] but some of these drugs were reformulated and now contain bismuth subsalicylate instead of kaolinite or attapulgite [62]. Biological applications of natural clay minerals as detoxifying agents may be attributed to their ability to adsorb lipids, proteins, bacteria, and viruses [15,74,80,81]. Also, clays can externally adsorb toxins from skin and are used to catalyze rheumatism treatment [62,82].
Furthermore, Mishra, et al. [83] explained that clay crystals are negatively charged and can attract bacteria and toxins in human body that are positively charged and thus become electrically satisfied holding the materials until the human body is able to excrete them. The properties of montmorillonite clay, such as its ability to absorb and remove various types of toxins and the ability to cross the digestive tracts have been reported [84,85].

Clays in Drug Delivery and Pharmaceutical Formulations
Choy et al. [17] identified some advantages of clay minerals approach to improve drug release was made by using kaolinite pellets through extrusion-spherization and subsequently the drug molecules were loaded by a vacuum impregnation technique [95].
The drug molecules loaded in the pellets were reported to exhibit a prolonged-release profile following an 'initial burst' release as a result of entrapment within the porous structure of the pellets [95].
Kevadiya and Bajaj [96] showed a possible mechanism (Figure 4) by which monmorillonite could be released and absorbed in the body. and Cacium (Ca) rich smectite clay as anti-diarrhea agents, via oral administration have been reported in the past century [106,107].
Clay minerals are also used as gelling, emulsifying, and thickening agents in pharmaceutical formulations for various oral medications because of their high water and oil adsorption as well as their ability to modulate viscosity efficiently [108,109]. Organoleptic qualities such as unpleasant taste, colour and smells of pharmacological formulations can be corrected and improved by the use of clay mineral [110].
For instance, the intercalation of Aripiprazole (APZ) into montmorillonite clay was carried out in order to improve the tasteblocking efficiency and also to control the release kinetics [111].
The aim of the study was achieved by cation exchange reaction that occurred between the APZ and the montmorillonite clay to yield a clay-drug nanohybrid, [111]. In the year 2012, Lee et al. also reported the improved taste of sildenafil by masking the drug with clay nanoparticles to form a nanohybrid [110].

Dermatological Application
Clay minerals naturally occur and are found in abundance in different parts of the world. Man has used since antiquity, in different ways, clays and mud or for therapeutic purposes, either by ingesting them or applying it topically in the form of cataplasms, patches, or mud-baths [112,113]. Clay minerals are widely applied in mud therapy, pelotherapy or fangotherapy [114][115][116]. In dermatology, clay minerals are useful for the production of ointment to treat oily skin and acne as well being used to release drugs at a controlled kinetics to systemic circulation through passive diffusion across the skin [17]. Clay minerals have also been employed as pharmaceutical ingredients for transdermal drug delivery systems (TDDS) [87].