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Characterization and Assessment of Natural Amazonian Clays for Cosmetics-Industry Applications

Published online by Cambridge University Press:  01 January 2024

Antonio Claudio Kieling
Affiliation:
Department of Mechanical Engineering, Amazonas State University – UEA, Manaus, Brazil Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil
Cláudia Cândida Silva
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Chemical Engineering, Amazonas State University – UEA, Manaus, Brazil
Sérgio Duvoisin Júnior
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Chemical Engineering, Amazonas State University – UEA, Manaus, Brazil
José Costa de Macedo Neto
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Materials Engineering, Amazonas State University – UEA, Manaus, Brazil
Miécio de Oliveira Melquíades
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Mechanical Engineering, Federal University of São João del Rei – UFSJ, São João del Rei, Brazil
Gilberto Garcia del Pino
Affiliation:
Department of Mechanical Engineering, Amazonas State University – UEA, Manaus, Brazil Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil
Yago Ono de Souza Moreira
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Chemical Engineering, Amazonas State University – UEA, Manaus, Brazil
Túlio Hallak Panzera*
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Mechanical Engineering, Federal University of São João del Rei – UFSJ, São João del Rei, Brazil
Maria das Graças da Silva Valenzuela
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Metallurgical and Materials Engineering, University of São Paulo – USP, São Paulo, Brazil
Francisco Rolando Valenzuela Diáz
Affiliation:
Department of Education, Federal Institute of Amazonas – IFAM, Manaus, Brazil Department of Metallurgical and Materials Engineering, University of São Paulo – USP, São Paulo, Brazil
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Abstract

Clays are abundant materials in the Amazon region and have been used historically by ancient Amazonian people to produce ceramic and cosmetics products. The current study aimed to evaluate the potential of four clays from the metropolitan area of Manaus, each with a different color, for cosmetics applications. Two clays were collected in the Ponta Negra region (red and gray in color) in Manaus, one in Careiro (white), and one in Itacoatiara (black). After drying in an oven for 24 h at 105°C, the four clays were characterized by X-ray fluorescence (XRF), X-ray diffraction (XRD), infrared (IR) spectroscopy, thermogravimetry (TGA), differential thermal analysis (DTA), differential scanning calorimetry (DSC), scanning electron microscopy (SEM), particle-size analysis, and detection of microorganisms. The amounts of Al, Si, Cl, K, Ca, Ti, Cr, Fe, Zn, P, and S in all samples were below the limits for use in cosmetics. The main phases identified were kaolinite 1A, quartz, gibbsite, and the rare kaolinite 2M. Approximately 40 wt.% of each sample was in the < 20 μm particle-size range. Analyses by SEM revealed pseudo-hexagonal kaolinite structures with nano-islands and nanocrystallites. The low toxicity, mineralogic compositions, and particle-size findings suggest that Amazonian clays are promising for cosmetics applications.

Type
Original Paper
Copyright
Copyright © The Author(s), under exclusive licence to The Clay Minerals Society 2022

Introduction

Clays are fine-grained, natural soil materials that possess a range of peculiar chemical, mineralogic, and granulometric properties, as well as some plasticity in terms of mechanical properties when mixed with an appropriate amount of water. The structure, the colloid size of the particles, and their constitution give rise to the desired rheological characteristics and sorption capacities. Clays often contain minerals such as quartz, feldspar, carbonates, sulfates, and iron, aluminum, and titanium oxides. These minerals can affect the chemical (e.g. stability and purity), physical (e.g. texture, moisture content, and particle size), and toxicological requirements specified for each clay application (Morekhure-Mphahlele et al., Reference Morekhure-Mphahlele, Focke and Grote2017). In this context, the characterization of clays is essential as the ideal combination of composition and structure can lead to optimal performance for the target application (Bouna et al., Reference Bouna, Ait El Fakir, Benlhachemi, Draoui, Ezahri, Bakiz, Villain, Guinneton and Elalem2020).

The toxicological issue mentioned is linked directly to the application of clays in the pharmaceutical industry. The most common clays for pharmacological applications are kaolinite (Al2Si2O5), talc, smectites, palygorskite, and sepiolite (Massaro et al., Reference Massaro, Colletti, Lazzara and Riela2018). Kaolin (Al2H4O9Si2) with iron oxide was studied by Long et al. (Reference Long, Zhang, Huang, Chang, Hu, Yang, Mao and Yang2018) with a view to controlling bleeding and improving wound-healing performance. Those authors characterized its crystal structure, morphology, coagulation, adsorption, and toxicity by means of kaolin zeta potential, platelet aggregation, XRD, SEM, Fourier-transform infrared spectroscopy (FTIR), cytotoxicity, and hemolysis assays. Kaolinite is applied in gastrointestinal protectors, antidiarrheal products, dermatological protectors, local anesthetics, cosmetic creams, powders, anti-inflammatories, and emulsions (Carretero & Pozo, Reference Carretero and Pozo2010).

Among the range of possibilities cited by the pharmaceutical industry, the potential application of clays as cosmetic products, i.e. in which the material is placed in contact with the outside of the human body, was the focus of the current work. The motivation was linked to the high demand for raw materials in the global cosmetics market; western Europe and North America have the largest share of the world market for cosmetics ingredients, valued at > €30 billion annually. Europe was the world’s largest cosmetics market in 2019 when the price of cosmetics containing these ingredients reached €80 billion (Cosmetic Europe, 2019).

The present work focused on clay extracted from South America, especially kaolinite. Estimates of kaolinite production in the State of Amazonas, in the region of Manaus, Brazil, suggest a production of 500,000 tons/year of kaolin, with a useful production potential of $60 million and a life expectancy of 50 years (Reis et al., Reference Reis, Almeida, Riker and Ferreira2006). Official policy, however, allocates kaolin reserves to white ceramics, paint, and varnish manufacture, and to the electro-electronics industry (Reis et al., Reference Reis, Almeida, Riker and Ferreira2006). There is, therefore, a potential for trade in the cosmetics industry that has not yet been explored fully. Products composed of kaolinite are common in the global market: Aloe Vera and kaolinite have been combined to create peel-off mask gel compositions (Beringhs et al., Reference Beringhs, Rosa, Stulzer, Budal and Sonaglio2013); the potential of emulsions made with kaolin and an ethanolic extract of the Litchi chinensis leaf to inhibit UVB-induced photodamage was investigated by Thiesen et al. (Reference Thiesen, Bretzke, Bittencourt, Silva, Bresolin, Santin and Couto2020).

The literature on kaolinite in the Manaus region deals with mineralogic characterization and transformations (Chauvel et al., Reference Chauvel, Lucas and Boulet1987; Cornu et al., Reference Cornu, Lucas, Lebon, Ambrosi, Luizão, Rouiller, Bonnay and Neal1999; Horbe et al., Reference Horbe, Horbe and Suguio2004). The kaolinitic mineralogy of Manaus comprises kaolinite with low isomorphic substitution by iron and mixture with quartz, gibbsite, and goethite. As expected, the kaolinite from Manaus has a clay-mineral structure (1:1 layer type) with low isomorphic substitution and low cation-exchange capacity (Silva et al., Reference Silva, Lages and Santana2017). In addition, kaolin from the Manaus region is a poorly ordered clay mineral, retaining 2.21% of water (Couceiro & Santana, Reference Couceiro and Santana1999) and having low cation adsorption (Souza & Santana, Reference Souza and Santana2014). This set of properties seems suitable for pharmaceutical applications and has motivated this study to evaluate its potential for the cosmetics industry.

Here, the physical and chemical properties of four samples of clay minerals extracted from the State of Amazonas were studied. The new contributions compared to previous works are based on a broad characterization of clays from the largest biome in the world, carefully evaluating their properties from a pharmacological point of view.

Materials and Methods

Materials

The clays were collected at four locations in Amazonas, Brazil (Fig. 1), at 1–2 m of soil depth. The geographical coordinates were identified on a GPS device (GPS Data-Smart):

  • Ponta Negra clay 1 (red): collected at Manaus, Amazonas, in the Ponta Negra region (3°02′53.6" S, 60°05′22.4" W). Code: APN-1.

  • Ponta Negra clay 2 (gray): collected at Manaus, Amazonas, in the Ponta Negra region (3°03′26.5" S, 60°06′20.0" W). Code: APN-2.

  • Kaolin AM (white): collected at Careiro, Amazonas, (3°49′10.0" S, 60°21′40.4" W). Code: Kaolin.

  • Black clay AM (black): collected at Itacoatiara, Amazonas, (3°08′58.9" S, 58°6′13.5" W). Code: AN-Am.

Fig. 1 Locations and colors of the clay samples

Sieve Analysis

Initially, the sample material was oven dried for 24 h at 105°C. Then the material was passed through a tower of sieves consisting of 11 screens with the following mesh sizes (in mm): (1) 2.00; (2) 1.41; (3) 1.00; (4) 0.59; (5) 0.42; (6) 0.35; (7) 0.25; (8) 0.18; (9) 0.125; (10) 0.075; (11) (pan). The set of sieves was vibrated for 2 h until the material passed through all the sieves and reached the bottom. Then the amount retained on each sieve was weighed and the values were noted and tabulated for each sample. The standard for particle-size analysis was ASTM D6913/D6913M (2017).

Moisture Analysis

The humidity content was calculated by Eq. 1:

(1) Humidity = wet weight - dry weight dry weight × 100

Approximately 16 g of each wet material was placed in an oven at 105°C for 24 h. Then the material was placed in a desiccator to cool. An analytical balance with a resolution of 0.0001 g (TW223L, Shimadzu, Tokyo, Japan) was used according to ASTM D2216 (2019) protocols.

X-ray Fluorescence Analysis

Three samples (1.5 g) of each material were packed in an Eppendorf tube, and each sample was run 18 times. Prior to WD-XRF testing, 0.4 g of boric acid was added and mixed with the sample material. Subsequently, tablets with uniform granulometry were prepared by uniaxial pressing at 98 kPa. The mixture comprised 1000 g of the sample homogenized with 4000 g of high-purity H3BO3 in an agate mortar. All samples were analyzed in triplicate.

Analyses were performed using an XRF instrument (Rigaku, supermini model, Wilmington, Delaware, USA) using wave dispersion (WD-XRF) and a palladium tube, with an exposure time of 200 s at a power of 200 W. All elements were identified by their Kα and/or Kß energies (Ma & Allen, Reference Ma and Allen2004). Equipment calibrations were carried out using LIF 200, PET, and RX25 crystals with scintillation (SC) and proportional (PC) counter detectors. Geological reference standards such as GBW 3125, 7105, and 7113 were also used for equipment calibration.

Each element was quantified using patterns of external salts of known purity diluted in boric acid. Quantifications were performed based on their intensities (cps/uA) using the ZSX-spectrometer Status program (Rigaku Corporation, 2008), considering the recommendations of the ASTM E1621 (2013) and ASTM C114 (2013) standards. At least six predetermined concentrations submitted to the same analysis conditions were considered.

X-ray Diffraction Analysis

Kaolin samples Ponta Negra clay 1 (APN-1), Ponta Negra clay 2 (APN-2), Black clay AM (AN-Am), and Kaolin AM were evaluated. The clays were ground in an agate mortar before pressing in the sample holder. A diffractometer (Empyrean, Malvern Panalytical, Malvern, UK) with CuKα radiation (λ = 0.1541838 nm), and an angular range of 5–85°2θ, with acceleration voltage and current of 40 kV and 40 mA, respectively, was used. The step size and the time per step were 0.02°2θ and 2 s, respectively. The X-ray photons were detected by an area detector (PIXcel3D-Medipix3 1 × 1).

The diffractograms obtained were indexed against the patterns of the Inorganic Crystal Structure Database – ICSD. All patterns were submitted to the Rietveld method and the GSAS-EXPGUI program package (Larson & Von Dreele, Reference Larson and Von Dreele2004) to refine the structural parameters and, thus, obtain the crystalline cell for the synthesized phase, lattice parameters, crystallite size, and micro tension, and to quantify the current phases. An 8th-order Chebyshev polynomial was chosen. The pseudo-Voigt function convoluted with an asymmetric function of Finger, Cox, and Jephcoat was used to adjust the profile (Larson & Von Dreele, Reference Larson and Von Dreele2004), based on Stephens' phenomenological model, which considers anisotropic line broadening from microstrains (Paiva-Santos, Reference Paiva-Santos2001). The Crystallographic Information File (CIF), corresponding to the identified phases, was used to refine the sample. Due to the instrumental contribution, broadening corrections were made by refining a pattern of lanthanum hexaboride (LaB_6) obtained under the same sample conditions.

The broadening of the peaks was analyzed by the single-line method to calculate the crystallite size and lattice microtension (Ferreira et al., Reference Ferreira, Rovani, de Lima and Pereira2015; Michielon De Souza et al., Reference Michielon de Souza, Ordozgoith da Frota, Trichês, Ghosh, Chaudhuri, dos Santos, Gusmao, de Figueiredo Pereira, Couto Siqueira, Daum Machado and Cardoso de Lima2016; Yadav et al., Reference Yadav, Mukhopadhyay, Tiwari and Srivastava2005). The average size of the crystallites was calculated using the Scherrer formula (Muniz et al., Reference Muniz, Miranda, Morilla dos Santos and Sasaki2016), as follows:

(2) D = 0.91 λ / ( β _ L cos θ )

and the microtension was estimated by the Stokes and Wilson (Reference Stokes and Wilson1944) equation as follows:

(3) ε = β _ G / ( 4 tan θ )

In these Eqs. (2 and 3), λ is the wavelength used in diffraction measurements, and θ is the Bragg angle, while ß_L and ß_G are the Lorentzian and Gaussian contributions, respectively. Through the pseudo-Voigt function they can be calculated using the maximum width up to half-height (Γ), and the mixture coefficient parameter (η) can be obtained directly from the analysis using the Rietveld method (Michielon De Souza et al., Reference Michielon de Souza, Ordozgoith da Frota, Trichês, Ghosh, Chaudhuri, dos Santos, Gusmao, de Figueiredo Pereira, Couto Siqueira, Daum Machado and Cardoso de Lima2016), as follows:

(4) β _ G = Γ / 2 [ π ( 1 - 0.74417 η - 0.24781 η 2 - 0.00810 η 3 ) / ln 2 ] ( 1 / 2 )
(5) β _ L = π Γ / 2 ( 0.72928 η + 0.19289 η 2 + 0.07783 η 3 )

All samples were submitted to a conventional X-ray diffractometer with a copper source (Cu), and the results were tabulated and transformed into a ‘.txt’ format for analysis. Origin™ software was used along with the crystallinity analysis taken from XRD patterns. Three points were considered: baseline, number of peaks, and integration interval. The Adjacent-Averaging method performs normalization and smoothing of the data, considering five points. Data were scored from 0 to 100% to improve visualization and accuracy. The baseline was the parameter for all calculations; thus, it was modeled to fit the peaks and obtain the areas of the crystalline peaks. The ‘peak analysis’ feature was used, and each peak was labeled. Then, the integration region was defined based on where each peak began and ended. Crystallinity was obtained by the percentage ratio between the area of crystalline peaks and the total area.

The presence of minerals was identified by visualizing the highest-intensity peaks with a mineral file obtained from the American Mineralogist Crystal Structure Database (http://rruff.geo.arizona.edu/AMS/amcsd.php). The main procedures were based on ASTM C1365 (2006) protocols.

Fourier-Transform Infrared Spectroscopy Analysis

Samples of 10–20 mg were characterized using an FTIR spectrophotometer (IRAffinity-1S, Shimadzu, Tokyo, Japan) according to ASTM E1252-98 (2021). The analysis was performed on the attenuated total reflectance (ATR) module (%T as a function of the wavenumber in cm–1). The spectra were obtained in the MIR region from 4000 to 500 cm–1 and from 1550 to 1850 cm–1.

Thermal Analysis

The TGA/DTA/DSC analysis was performed using a Mettler Toledo device (Columbus, Ohio, USA) from 30 to 1200°C with an increment of 10°C/min. N2 at a flow rate of 50 mL/min was used according to ASTM E1131 (2020).

Scanning Electron Microscopy Analysis

Samples were prepared using a solution consisting of 10 mL of ethyl alcohol and 100 mg of material to be analyzed mixed in a 10 mL beaker. The solution was stirred until the clay was dispersed completely, and a homogeneous solution was formed. Subsequently, the solution was applied to the sample holders (stubs) using a graduated pipette. Samples were dried at room temperature. The sample was then sputter coated with Au alloy using a DII-29010SCTR (Jeol, Tokyo, Japan) instrument for 4 min. The microstructural analysis was conducted using a JSM-IT500HR microscope (Jeol), according to ASTM E986 (2004).

Particle-Size Distribution

After manual homogenization, the sample was mixed in 20 mL of distilled water (samples B, C, D, F). One drop was placed on the slide using a pipette and spread with a glass slide. Three drops of Tween 80 were used for complete dispersion for samples A, E, and H.

Optical microscopy analysis was performed to obtain two-field images of the sample at magnifications of 50, 100, 200, and 500 × using dark field incident light mode. Samples dispersed in water were characterized at magnifications of 50, 100, and 200 × . A laser diffraction particle-size analyzer (MAZ3000, Malvern Panalytical, Malvern, UK) was used with distilled water to disperse the particles, considering a refractive index of 1.56, absorption of 0.1, stirring and pumping at 1750 rpm. Samples C and D were kept for 3 and 1 min, respectively, in ultrasound (100%) before testing.

Mie's mathematical model was used, considering that the particles were not opaque and had a spherical shape. This model finds the diffraction and diffusion of light in the particle and the medium. The analysis was performed following ASTM D4464 (2015).

Microbiological Analysis

The microorganisms were detected by placing the samples in an autoclave for 3 h at a pressure of 120 kPa. Then, the samples were sent to a continuous air circulation oven for 24 h at 105°C. Subsequently, the sample containers were placed in an autoclave at a pressure of 150 kPa for 15 min. Then they were dried for 30 min using an ultraviolet chamber. The samples were packed into appropriate containers and placed in a desiccator. These procedures followed Brazilian Resolutions 481/99 (BRAZIL, 1999) and (PHARMACOPEIA, 2008) and Favero et al. (Reference Favero, dos Santos, Weiss-Angeli, Gomes, Veras, Dani, Mexias and Bergmann2019).

Results

Sieve Analysis

The sieve distribution of clays collected in Amazonas is shown in Table 1. Kaolin, AN-Am, APN-1, and APN-2 have mass fractions of < 20% above the 200-mesh sieve (0.075 mm). The mass fraction that passed through the 0.420 mm sieve ranged from 68 to 97%, which shows that the material collected from this region is composed of fine particles.

Table 1 Particle-size distribution

Commercial products are generally composed of a fine-grained powder (no more than 0.5% of particles were > 75 μm) and aggregates ranging from 50 to 300 μm; however, fine particles should be < 2 μm (López-Galindo et al., Reference López-Galindo, Viseras and Cerezo2007).

Moisture Analysis

The moisture percentages in kaolin, APN-1, APN-2, and AN-Am clays are listed in Table 2. The moisture content of kaolin is substantially less (0.40%) than the others, possibly because its source is relatively well protected from the natural moisture of the soils. The AN-Am sample, collected in Itacoatiara city, has the greatest moisture content (38.6%), followed by APN-1 and APN-2, collected near the Negro River in Manaus.

Table 2 Moisture content in the investigated clays

X-ray Fluorescence Analysis

The data obtained using the X-ray fluorescence by wave dispersion (WD-XRF) technique are shown in Table 3. Seventeen (17) different elements were observed, with emphasis on Al, Si, Cl, K, Ca, Ti, Cr, Fe, Zn, P, and S. The compositional, technical, and safety specifications of clays for use as pharmaceutical and cosmetic products show that the permissible limits for elements traditionally considered toxic (As, Sb, Cd, Co, Cu, Pb, Ni, Zn, Hg, Se, Te, TL, Ba, etc.), and other less dangerous elements (Li, Rb, Sr, Cr, Mo, V, Zr), must be strictly controlled, as reported by López-Galindo et al. (Reference López-Galindo, Viseras and Cerezo2007). All clays are within the permitted limits, except for Cr, for which the recommended limit of 50 ppm is met by the kaolin sample only.

Table 3 X-ray fluorescence analysis

ND = Not detected, average ± std, in triplicate

The results were recalculated with respect to the loss on ignition (LOI) at 1000°C

Elements present at lower concentrations, such as Cu, Mg, Ni, Mn, and Sr, were observed in a few samples. Kaolin contains no Mg, Ni, Mn, or Sr. The AN-Am sample contains no Ni, Mn, or Sr, and APN-2 contains no Cu, Ni, Mn, or Sr. APN-1 does not contain Mn. This implies that these clays must possess unique properties that would be suitable for various cosmetics applications.

The presence of Al or Si was expected as all phases observed by XRD contain these elements. However, the Si/Al ratio for the three types of kaolinites is as follows: Kaolin < APN-1 ≈ APN-2 < AN-Am. All elements observed have already been reported, to a greater or lesser extent, as associated with the soils where the samples were obtained (Horbe et al., Reference Horbe, Horbe and Suguio2004).

X-ray Diffraction Analysis

The XRD results are shown in Fig. 2. The dominant phase in the clays belongs to the triclinic crystalline system and P1 space group (No. 1), known as the 1A kaolinite mineral. Other than for CI and kaolin samples, it was also possible to identify the existence of a special clay, which is commercially rare, known as kaolinite 2M, which has a partial dickite-type structure with monoclinic symmetry and C1c1 space group (No. 9) (Vieira Coelho et al., Reference Vieira Coelho, Santos and Santos2007). A quartz phase, belonging to the trigonal crystalline system and space group P3121 (No. 152), is present in the clays. A gibbsite phase was also identified in the APN-1 and kaolin samples. Gibbsite has a monoclinic crystalline system with a P121/n (No. 14) space group 1.

Fig. 2 Phase identification of kaolin, APN-1, APN-2, and AN-Am

All samples underwent refinement using the Rietveld method. Minimum residual and statistical parameters, χ 2 and Rwp, show proper adjustments (Fig. 3) (Toby, Reference Toby2006). The deconvolution of the existing phases in the samples and their respective mass percentages are shown in Fig. 3. The network parameters of the unit cell of the phases were obtained after refinement and are listed in Table 4.

Fig. 3 Refinement using the Rietveld method along with statistical parameters of refinement quality (χ2 and Rwp) and phase deconvolution of samples a kaolin, b APN-1, c APN-2, and d AN-Am

Table 4 Parameters obtained after the Rietveld refinement method

D = < D > (nm), ɛ = < ɛ > (%), and a, b, c = lattice parameters

The mean value of crystallite size and microtension was calculated for the dominant phase of the samples, i.e. kaolinite 1A (Table 4). The phase has crystallite sizes with nanometric dimensions and microtension with values between 0.3 and 1.0%. Microtension is associated directly with the density of defects in the sample (Melquiádes et al., Reference Melquíades, de Oliveira, Rebelo, Chaudhuri, Leite, Trichês and Michielon de Souza2019; Soares de Oliveira et al., Reference Soares de Oliveira, de Oliveira Melquiades, da Costa Pinto, Trichês and Michielon de Souza2020). Materials with nanometric dimensions may have differentiated properties compared to bulk materials and be of interest for possible use in various technological applications (Das et al., Reference Das, Sen and Debnath2015; Zhao et al., Reference Zhao, Cai, Tang, Tong and Liu2014). The values obtained for the crystallinity calculations of the evaluated materials are listed in Table 4. These results are similar to those of Couceiro and Santana (Reference Couceiro and Santana1999) and Silva et al. (Reference Silva, Lages and Santana2017).

X-ray diffraction shows the existence of practically homogeneous clays formed by clay minerals with low cation exchange capacity values, with results similar to those obtained by Souza and Santana (Reference Souza and Santana2014). In this way, these samples, when manipulated for the production of cosmetics and commercialization, offer a low risk of contamination (Mattioli et al., Reference Mattioli, Giardini, Roselli and Desideri2016).

Fourier-Transform Infrared Spectroscopy Analysis

For clarity, the combined spectra for the samples are shown in Fig. 4 and Table 5. The FTIR spectra of clay mineral samples revealed kaolinites with crystalline structure defects (Silva et al., Reference Silva, Lages and Santana2017). The FTIR spectra generally show O–H stretch bands of medium to strong intensities between 3700 and 3300 cm–1. Si–O stretching bands occurred between 1095 and 1009 cm–1 in the clay minerals, and Si–O–Si bands of quartz and Al–O fold were at 1200–700 cm–1. SiO2 had a strong band at ~ 1100 cm–1, bending bands at 600–150 cm–1, and medium SiO2 bands at ~ 470 cm–1. O–H metal bands were seen in folded mode between 950 and 600 cm–1. Water absorbs below 800 cm–1, and strong infrared transitions of metal-to-metal groups occurred at 800–200 cm–1 (Ihekweme et al., Reference Ihekweme, Shondo, Orisekeh, Kalu-Uka, Nwuzor and Onwualu2020).

Fig. 4 FTIR spectra of samples kaolin, APN-1, APN-2, and AN-Am

Table 5 Frequencies and absorbance for various stretching and bending bands (cm–1)

Thermal Analysis

The results are shown for differential scanning calorimetry (DSC-Fig. 5a), thermogravimetric analysis (TGA-Fig. 5b) and differential thermal analysis (DTA-Fig. 5c) of kaolin, APN-1, PN-2) and AN-Am.

Fig. 5 a DSC, b TGA, and c DTA curves of the studied clays

The thermal behavior of the various clay samples was quite similar. The first endothermic peak occurred near 100°C (DTA curve), where free water was lost between the particles. At ~ 220°C (DSC curve), the endothermic peak occurred due to the combustion of organic matter and water loss from the hydroxides attributed to the gibbsite.

The presence of hydroxides requires additional energy for their decomposition. The highest-intensity endothermic peak occurred at ~ 500°C, due to the loss of hydroxyl in the kaolinite group. Above 500°C, the crystallinity disappeared with the water loss and metakaolinite began to form; this is amorphous and metastable. The graph does not show the vitrification phase which should start at ~ 900°C with spinel formation; neither does it show mullite nucleation, which should have begun at 970°C (Macedo et al., Reference Macedo, Menezes, Neves and Ferreira2008).

The TGA analysis showed the loss of mass with increasing temperature. Note that the most significant mass loss was due to the dehydroxylation of kaolinite at ~ 500°C, and the total value of the mass loss was ~ 14% (kaolin sample), 13% (APN-1), 10% (APN-2), and 25% (AN-Am). These values are consistent for kaolin clays and corroborate the values found in the XRF analysis (e.g. Macedo et al., Reference Macedo, Menezes, Neves and Ferreira2008).

Scanning Electron Microscopy Analysis

The microstructural analysis of kaolin (a–b), APN-1 (c–d), AN-Am (e–f), and APN-2 (g–h) (Fig. 6) revealed a hexagonal shape for kaolinite in the kaolin sample (Fig. 6a) and the presence of a nanocrystallite (Fig. 6b), similar to that reported by Lebedeva and Fogden (Reference Lebedeva and Fogden2011). The presence of pseudo-hexagonal lamellae in APN-1 (Fig. 6cd) is a characteristic of kaolinite minerals (Otieno et al., Reference Otieno, Kengara, Kemmegne-Mbouguen, Langmi, Kowenje and Mokaya2019). Likewise, the AN-Am sample exhibited pseudo-hexagonal lamellae (Fig. 6e). The lamellae are slightly bent with a concave shape (Fig. 6f). This morphology is probably due to the loss of tension in the crystalline structure of the lamellae (Neto et al., Reference Neto, Kimura, Adeodato, Neto, Nascimento and Lona2017). The Ponta Negra (APN-2) sample also contained pseudo-hexagonal lamellae characteristic of kaolinite (Otieno et al., Reference Otieno, Kengara, Kemmegne-Mbouguen, Langmi, Kowenje and Mokaya2019).

Fig. 6 SEM images of: a-b kaolin, c-d APN-1, e-f AN-Am, and g-h APN-2 clays

The use of kaolin in semi-solid cosmetics and medicinal formulations in the form of peloids has been reported in the literature. According to Viseras et al. (Reference Viseras, Carazo, Borrego-Sánchez, García-Villén, Sánchez-Espejo, Cerezo and Aguzzi2019), this structure allows pharmacological functions, being applied in pelotherapy, wound healing, regenerative medicine, antimicrobial activity, and dermo-cosmetics. Only a few clay minerals with lamellar structures, including kaolin, can be used as excipients in formulations of various solid, liquid, or semi-solid dosages in pharmaceutical and cosmetics products (Kim et al., Reference Kim, Choi, Elzatahry, Vinu, Choy and Choy2016). Regarding textural findings, despite presenting some mineralogical differences, Amazonian clays can be recommended as raw materials for cosmetics applications.

Particle-Size Distribution

Particle-size analysis of kaolin, APN-1, AN-Am, and APN-2 samples (Fig. 7a) revealed a normal particle-size distribution generally, except for the kaolin sample. Peaks in the particle-size range of 6.4 to 100.2 μm corresponded to a volume ratio of 6.9 to 8.6. Kaolin shows a bimodal curve with a peak grain size of 5.8 μm and a volume ratio of 7.3. This peak indicates a smaller particle size compared to the monomodal samples.

Fig. 7 a particle-size distribution, and b accumulated volume of kaolinite for APN-1, AN-Am, and APN-2 minerals

Figure 7b shows the particle size curves based on accumulated volume. These curves were obtained based on the effective diameter (d10). The diameter on the particle-size distribution curve corresponding to 10% finer is defined as the effective size. Effective diameters (d10) were: kaolin 0.61 μm, APN-1 2.27 μm, AN-Am 9.36 μm, and APN-2 10.64 μm.

Between 1.6 and 10.7%, all particles were < 2 μm, except for kaolin. From 11.6% to 42.5%, all particle sizes were between 2 and 20 μm; and from 46.8% to 86.8%, > 20 μm, which indicated that the minerals other than kaolin have a small ‘clay fraction’ (particles < 2 μm). The results suggest that kaolin can be used as an emulsifying, pelletizing, granulating, and suspending agent in pharmaceutical formulations (Awad et al., Reference Awad, López-Galindo, Setti, El-Rahmany and Iborra2017).

Microbiological Analyses

Tests were run for mesophilic bacteria, molds, and yeasts, fecal coliforms, total coliforms, Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureusKlebsiella spp is a pathogen, as it is usually involved in several infections, especially in the hospital environment. Its presence is prohibited for products that may be in contact with human skin (Favero et al., Reference Favero, dos Santos, Weiss-Angeli, Gomes, Veras, Dani, Mexias and Bergmann2019). As shown in Table 6, all samples comply with the legislation for use in products for cosmetics applications.

Table 6 Results of microbiological tests

Conclusions

The results indicated that the Amazonian clays offer promise for application in cosmetics materials, such as emulsifying, pelletizing, granulating, and suspending agents. Permissible limits for primary and toxic heavy metals were met for possible application in cosmetics, especially kaolin clay exhibiting a Cr content of < 50 ppm. The dominant phase of the clays belonged to a crystalline triclinic system and the P1 space group, known as kaolinite 1A. Other than for the kaolin samples, the existence of a special, commercially rare kaolinite, called kaolinite 2M, was also found, which is part of a dickite-type structure with a monoclinic structure within the C1c1 space group. A quartz phase, belonging to the P3121 space group, was also noted in the clays. In addition, a gibbsite phase was identified in the APN-1 and kaolin samples. Gibbsite is monoclinic in the P121/n1 space group. Based on the crystallographic information file, the clays contained adequate amounts of quartz and iron. The samples revealed a particle-size distribution with a small clay-fraction content, except for the kaolin sample. The samples showed significant plasticity, as demonstrated in the microstructural analysis, mainly for samples APN-1 and APN-2 collected at Manaus. This behavior highlights a possible application in the production of composite materials. Based on microbiological studies, the clays are promising for application in cosmetics products as they meet Brazilian regulations, i.e. Resolution 481/99.

Acknowledgements

The authors thank the Brazilian Research Agency (CNPq) for financial support.

Data Availability

All data generated or analysed during this study are included in this published article.

Declarations

Conflict of Interest

The authors declare that they have no conflict of interest.

Footnotes

Associate Editor: F. Javier Huertas

Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.

References

ASTM C1365 (2006). Standard Test Method for Determination of the Proportion of Phases in Portland Cement and Portland-Cement Clinker Using X-Ray Powder Diffraction Analysis. ASTM International. West Conshohocken, PA, USA.Google Scholar
ASTM C114 (2013). Standard Test Methods for Chemical Analysis of Hydraulic Cement. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM D2216 (2019). Standard Test Methods for Laboratory Determination of Water (Moisture) Content of Soil and Rock by Mass. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM D4464 (2015). Standard Test Method for Particle Size Distribution of Catalytic Materials by Laser Light Scattering. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM D6913/D6913M (2017). Standard Test Methods for Particle-Size Distribution (Gradation) of Soils Using Sieve Analysis. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM E1131 (2020). Standard Test Method for Compositional Analysis by Thermogravimetry. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM E1252–98 (2021). Standard Practice for General Techniques for Obtaining Infrared Spectra for Qualitative Analysis. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM E1621 (2013). Standard Guide for Elemental Analysis by Wavelength Dispersive X-Ray Fluorescence Spectrometry. ASTM International, West Conshohocken, PA, USA.Google Scholar
ASTM E986 (2004). Standard Practice For Scanning Electron Microscope Beam Size Characterization. ASTM International, West Conshohocken, PA, USA.Google Scholar
Awad, M. E., López-Galindo, A., Setti, M., El-Rahmany, M. M., & Iborra, C. V. (2017). Kaolinite in pharmaceutics and bio-medicine. International Journal of Pharmaceutics, 533(1), 3448. https://doi.org/10.1016/j.ijpharm.2017.09.056CrossRefGoogle Scholar
Beringhs, A. O., Rosa, J. M., Stulzer, H. K., Budal, R. M., & Sonaglio, D. (2013). Green clay and Aloe Vera peel-off facial masks: Response surface methodology applied to the formulation design. An Official Journal of the American Association of Pharmaceutical Scientists, 14, 445455. https://doi.org/10.1208/s12249-013-9930-8Google Scholar
Bouna, L., Ait El Fakir, A., Benlhachemi, A., Draoui, K., Ezahri, M., Bakiz, B., Villain, S., Guinneton, F., & Elalem, N. (2020). Synthesis and characterization of mesoporous geopolymer based on Moroccan kaolinite rich clay. Applied Clay Science, 196, 120. https://doi.org/10.1016/j.clay.2020.105764CrossRefGoogle Scholar
BRAZIL (1999). Brazilian resolution 481/99: Microbiological control parameters for personal care products and cosmetics. National Health Surveillance Agency ANVISA. Accessed 05/03/2022 https://bvsms.saude.gov.br/bvs/saudelegis/anvisa/1999/res0481_23_09_1999_rep.htmlGoogle Scholar
British Pharmacopeia (2008) Accessed10/12/2021 https://www.pharmacopoeia.com/Google Scholar
Carretero, M. I., & Pozo, M. (2010). Clay and non-clay minerals in the pharmaceutical and cosmetic industries Part II Active Ingredients. Applied Clay Science, 47(3–4), 171181. https://doi.org/10.1016/j.clay.2009.10.016CrossRefGoogle Scholar
Chauvel, A., Lucas, Y., & Boulet, R. (1987). On the genesis of the soil mantle of the region of Manaus, Central Amazonia, Brazil. Experientia, 43, 234241. https://doi.org/10.1007/BF01945546CrossRefGoogle Scholar
Cornu, S., Lucas, Y., Lebon, E., Ambrosi, J., Luizão, F., Rouiller, J., Bonnay, M., & Neal, C. (1999). Evidence of titanium mobility in soil profles Manaus, Central Amazonia. Geoderma, 91(3–4), 281295. https://doi.org/10.1016/S0016-7061(99)00007-5CrossRefGoogle Scholar
Cosmetic Europe (2019). Cosmetic Europe-the personal care association. Cosmetics and personal care industry overview. Accessed 15/03/2022 https://cosmeticseurope.eu/cosmetics-industry/Google Scholar
Couceiro, P. R. C., & Santana, G. P. (1999). Caulinita em solo da Amazônia: Caracterização e permutabilidade. Acta Amazônica, 29(2), 265275. https://doi.org/10.1590/1809-43921999292275CrossRefGoogle Scholar
Das, S., Sen, B., & Debnath, N. (2015). Recent trends in nanomaterials applications in environmental monitoring and remediation. Environmental Science and Pollution Research, 22, 1833318344. https://doi.org/10.1007/s11356-015-5491-6CrossRefGoogle ScholarPubMed
Favero, J. S., dos Santos, V., Weiss-Angeli, V., Gomes, L. B., Veras, D. G., Dani, N., Mexias, A. S., & Bergmann, C. P. (2019). Evaluation and characterization of Melo Bentonite clay for cosmetic applications. Applied Clay Science, 175, 4046. https://doi.org/10.1016/j.clay.2019.04.004CrossRefGoogle Scholar
Ferreira, A. S., Rovani, P. R., de Lima, J. C., & Pereira, A. S. (2015). High-pressure study of Ti50Ni25Fe25 powder produced by mechanical alloying. Journal of Applied Physics, 117, 075901. https://doi.org/10.1063/1.4907386CrossRefGoogle Scholar
Horbe, A. M. C., Horbe, M. A., & Suguio, K. (2004). Tropical Spodosols in northeastern Amazonas State, Brazil. Geoderma, 119, 5568. https://doi.org/10.1016/S0016-7061(03)00233-7CrossRefGoogle Scholar
Ihekweme, G. O., Shondo, J. N., Orisekeh, K. I., Kalu-Uka, G. M., Nwuzor, I. C., & Onwualu, A. P. (2020). Characterization of certain Nigerian clay minerals for water purification and other industrial applications. Heliyon, 6, e03783. https://doi.org/10.1016/j.heliyon.2020.e03783CrossRefGoogle ScholarPubMed
Kim, M. H., Choi, G., Elzatahry, A., Vinu, A., Choy, Y. B., & Choy, J.-H. (2016). Review of Clay-Drug Hybrid Materials for Biomedical Applications: Administration Routes. Clays and Clay Minerals, 64, 115130. https://doi.org/10.1346/CCMN.2016.0640204CrossRefGoogle ScholarPubMed
Larson, A. C., & Von Dreele, R. B. G. (2004). General structure analysis system. Kaos GL Dergisi, 748, 121.Google Scholar
Lebedeva, E. V., & Fogden, A. (2011). Wettability alteration of kaolinite exposed to crude oil in salt solutions. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 377, 115122. https://doi.org/10.1016/j.colsurfa.2010.12.051CrossRefGoogle Scholar
Long, M., Zhang, Y., Huang, P., Chang, S., Hu, Y., Yang, Q., Mao, L., & Yang, H. (2018). Emerging Nanoclay Composite for Effective Hemostasis. Advanced Functional Materials, 28(10), 1704452. https://doi.org/10.1002/adfm.201704452CrossRefGoogle Scholar
López-Galindo, A., Viseras, C., & Cerezo, P. (2007). Compositional, technical and safety specifications of clays to be used as pharmaceutical and cosmetic products. Applied Clay Science, 36, 5163. https://doi.org/10.1016/j.clay.2006.06.016CrossRefGoogle Scholar
Ma, G., & Allen, H. C. (2004). Handbook of Spectroscopy, Volumes 1 and 2 Edited by Günter Gauglitz (University of Tübingen) and Tuan Vo-Dinh (Oak Ridge National Laboratory). Wiley-VCH Verlag GmbH & Co. KGaA: Weinheim. Germany. 1168 pp. Journal of the American Chemical Society, 8859–8860 pp. https://doi.org/10.1021/ja033666cGoogle Scholar
Macedo, R. S., Menezes, R. R., Neves, G. A., & Ferreira, H. C. (2008). Estudo de argilas usadas em cerâmica vermelha (Study of clays used in red ceramic). Cerâmica, 54, 411417. https://doi.org/10.1590/S0366-69132008000400005CrossRefGoogle Scholar
Massaro, M., Colletti, C., Lazzara, G., & Riela, S. (2018). The use of some clay.minerals as natural resources for drug carrier applications. Journal of Functional Biomaterials, 9, 122. https://doi.org/10.3390/jfb9040058CrossRefGoogle ScholarPubMed
Mattioli, M., Giardini, L., Roselli, C., & Desideri, D. (2016). Mineralogical characterization of commercial clays used in cosmetic and possible risk for health. Applied Clay Science, 119(2), 449454. https://doi.org/10.1016/j.clay.2015.10.023CrossRefGoogle Scholar
Melquíades, M. O., de Oliveira, L. S., Rebelo, Q. H. F., Chaudhuri, P., Leite, E. R., Trichês, D. M., & Michielon de Souza, S. (2019). Structural and optical properties of a mechanically alloyed thermoelectric lamellar SnSeS solid solution. Journal of Applied Physics, 126, 135707. https://doi.org/10.1063/1.5120033CrossRefGoogle Scholar
Michielon de Souza, S., Ordozgoith da Frota, H., Trichês, D. M., Ghosh, A., Chaudhuri, P., dos Santos, S., Gusmao, M., de Figueiredo Pereira, A. F. F., Couto Siqueira, M., Daum Machado, K., & Cardoso de Lima, J. (2016). Pressure-induced polymorphism in nanostructured SnSe. Journal of Applied Crystallography, 49, 213221. https://doi.org/10.1107/S1600576715023663CrossRefGoogle Scholar
Morekhure-Mphahlele, R., Focke, W. W., & Grote, W. (2017). Characterization of vumba and ubumba clays used for cosmetic purposes. South African Journal of Science, 113, 26. https://doi.org/10.17159/sajs.2017/20160105CrossRefGoogle Scholar
Muniz, F. T. L., Miranda, M. A. R., Morilla dos Santos, C., & Sasaki, J. M. (2016). The Scherrer equation and the dynamical theory of X-ray diffraction. Acta Crystallographica Section a: Foundations and Advances, 72, 385390. https://doi.org/10.1107/S205327331600365XGoogle ScholarPubMed
Neto, J. C. M., Kimura, S. P. R., Adeodato, M. G., Neto, J. E., Nascimento, N. R., & Lona, L. M. F. (2017). Intercalation and exfoliation mechanism of kaolinite during the emulsion polymerization. Chemical Engineering Transactions, 57, 14531458. https://doi.org/10.3303/CET1757243Google Scholar
Otieno, S. O., Kengara, F. O., Kemmegne-Mbouguen, J. C., Langmi, H. W., Kowenje, C. B., & Mokaya, R. (2019). The effects of metakaolinization and fused-metakaolinization on zeolites synthesized from quartz-rich natural clays. Microporous and Mesoporous Materials, 290, 109668. https://doi.org/10.1016/j.micromeso.2019.109668CrossRefGoogle Scholar
Paiva-Santos, C. O. (2001) Aplicações do método de rietveld e potencialidades do método de scarlett-madse. 1–42. Accessed 13/03/2021 http://noxconsultoria.com.br/labcacc/aulas/textos/Aplicacoes_do_metodo_de_Rietveld.pdfGoogle Scholar
Reis, N. J., Almeida, M. E., Riker, S. L., & Ferreira, A. L. (2006). Geologia e recursos minerais do estado do Amazonas. Rio de janeiro: CPRM; CIAMA, 2006. Accessed 02/03/2022 https://rigeo.cprm.gov.br/handle/doc/2967Google Scholar
Silva, M. S., Lages, A. S., & Santana, G. P. (2017). Physical and chemical study of lattice kaolinites and their interaction with orthophosphate. Anais Da Academia Brasileira De Ciências, 89(3), 13911401. https://doi.org/10.1590/0001-3765201720160519CrossRefGoogle ScholarPubMed
Soares de Oliveira, L., de Oliveira Melquiades, M., da Costa Pinto, C., Trichês, D. M., & Michielon de Souza, S. (2020). Phase transformations in a NiTiGe system induced by high energy milling. Journal of Solid State Chemistry, 281, 18. https://doi.org/10.1016/j.jssc.2019.121056CrossRefGoogle Scholar
Souza, W. B., & Santana, G. P. (2014). Mineralogy, zinc kinetic adsorption and sequential extraction of contaminated soil in Manaus Amazon. Ciencia Rural, 44(5), 788793. https://doi.org/10.1590/S0103-84782014000500005CrossRefGoogle Scholar
Stokes, A. R., & Wilson, A. J. C. (1944). The diffraction of X-rays by distorted crystal aggregates – I. Proceedings of the Physical Society, 56, 174181. https://doi.org/10.1088/0959-5309/56/3/303CrossRefGoogle Scholar
Thiesen, L., Bretzke, P. E., Bittencourt, C. M., Silva, R. M. L., Bresolin, T. M. B., Santin, J. R., & Couto, A. G. (2020). Litchi chinensis leaf extract provides high in vitro photoprotection associated to a natural mineral clay. Photodermatology, Photoimmunology and Photomedicine, 36, 6162. https://doi.org/10.1111/phpp.12488CrossRefGoogle ScholarPubMed
Toby, B. H. (2006). R factors in Rietveld analysis: How good is good enough? Powder Diffraction, 21, 6770. https://doi.org/10.1154/1.2179804CrossRefGoogle Scholar
Vieira Coelho, A. C., Santos, P. D. S., & Santos, H. D. S. (2007). Argilas especiais: O que são, caracterização e propriedades. Quimica Nova, 30, 146152. https://doi.org/10.1590/S0100-40422007000100026CrossRefGoogle Scholar
Viseras, C., Carazo, E., Borrego-Sánchez, A., García-Villén, F., Sánchez-Espejo, R., Cerezo, P., & Aguzzi, C. (2019). Clay Minerals in Skin Drug Delivery. Clays Clay Minerals, 67, 5971. https://doi.org/10.1007/s42860-018-0003-7CrossRefGoogle Scholar
Yadav, T., Mukhopadhyay, N., Tiwari, R., & Srivastava, O. (2005). Studies on the formation and stability of nanocrystalline Al50Cu28Fe22 alloy synthesized through high-energy ball milling. Materials Science and Engineering A, 393, 366373. https://doi.org/10.1016/j.msea.2004.11.002CrossRefGoogle Scholar
Zhao, X., Cai, B., Tang, Q., Tong, Y., & Liu, Y. (2014). One-dimensional nanostructure field-effect sensors for gas detection. Sensors (switzerland), 14, 1399914020. https://doi.org/10.3390/s140813999CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Locations and colors of the clay samples

Figure 1

Table 1 Particle-size distribution

Figure 2

Table 2 Moisture content in the investigated clays

Figure 3

Table 3 X-ray fluorescence analysis

Figure 4

Fig. 2 Phase identification of kaolin, APN-1, APN-2, and AN-Am

Figure 5

Fig. 3 Refinement using the Rietveld method along with statistical parameters of refinement quality (χ2 and Rwp) and phase deconvolution of samples a kaolin, b APN-1, c APN-2, and d AN-Am

Figure 6

Table 4 Parameters obtained after the Rietveld refinement method

Figure 7

Fig. 4 FTIR spectra of samples kaolin, APN-1, APN-2, and AN-Am

Figure 8

Table 5 Frequencies and absorbance for various stretching and bending bands (cm–1)

Figure 9

Fig. 5 a DSC, b TGA, and c DTA curves of the studied clays

Figure 10

Fig. 6 SEM images of: a-b kaolin, c-d APN-1, e-f AN-Am, and g-h APN-2 clays

Figure 11

Fig. 7 a particle-size distribution, and b accumulated volume of kaolinite for APN-1, AN-Am, and APN-2 minerals

Figure 12

Table 6 Results of microbiological tests