Mineralogical and chemical composition

The possible physical changes in the mineral matrix of the peloid and its mineral composition under different maturation conditions were conducted using an ultra-high resolution analytical scanning electron microscope (SEM), specifically the HR-FESEM Hitachi SU-70 (Tokyo, Japan).

The average clay-mineral compositions were calculated based on analyses by X-ray diffraction (XRD) using a Philips Panalytical X’Pert-Pro MPD diffractometer (Malvern Panalytical, Almelo, Netherlands). The instrument used CuKα (λ = 1.5405 Å) radiation and a goniometer speed of 0.02°2θ s^–1. Preferentially oriented samples were prepared by placing a suspension on a glass slide, then air drying it (Reference Quintela, Almeida, Terroso, Ferreira da Silva, Forjaz and RochaQuintela et al., 2015a). Subsequently, the samples were analyzed after glycerol saturation, followed by a final submission to heat treatment at 500°C (Reference Oliveira, Rocha, Rodrigues, Jouanneau, Dias, Weber and GomesOliveira et al., 2002).

The chemical composition with respect to major, minor, and trace elements in the samples was determined by X-ray fluorescence (XRF), using a Panalytical AXIOS PW 4400/40 fluorescence spectrometer (Malvern Panalytical, Almelo, Netherlands). The loss on ignition (LOI) values were determined by heating 1 g of each sample at 1000°C for 1 h in an oven.

The percent weight loss of all samples taken from the maturation tanks was measured after drying without any washing or removal of the maturation water.

Supernatant, pH, electrical conductivity, and Zeta-potential (or ζ-potential)

The concentrations of major and trace elements in the supernatant were measured using an Agilent Technologies 7700 Series Inductively Coupled Plasma-Mass Spectrometry (ICP-MS) instrument (Agilent, Santa Clara, California, USA). Precision was estimated by calculating the relative standard deviation of three replicate samples and was ≤10%. The detection limits (d.l.) were calculated as three times the standard deviations of the blanks.

The pH and electrical conductivity of the samples were measured before and after interactions with minerals, using a pH-conductivity meter, specifically the model EC 500, EXTech ExStik II (FLIR Commercial Systems, Inc., Nashua, New Hampshire, USA). Buffer solutions with pH values of 4, 7, and 10 were used for calibration.

The ζ-potential of the maturation samples was measured using a ZetaSizer Nano ZS instrument with software (nano, µV, APS) version 7.13, manufactured by Malvern Panalytical (Almelo, Netherlands). The measurements were performed in triplicate, and for each replicate, 20 data points were collected. The results are expressed in mV.

Cation exchange Capacity and Exchangeable Cations

The cation exchange capacity (CEC) was estimated using the ammonium acetate method. Exchangeable cations (Na⁺, K⁺, Mg²⁺, and Ca²⁺) were measured via ICP-MS using the method of Reference Quintela, Almeida, Terroso, Ferreira da Silva, Forjaz and RochaQuintela et al. (2015a).

Specific surface area (SSA)

The specific surface area (SSA) was estimated using the Brunauer-Emmet-Teller (BET) analysis of data acquired using the Gemini II 2370 analyser instrument manufactured by Micromeritics Instruments (Norcross, Georgia, USA) following the method of Reference Rebelo, Rocha and Ferreira da SilvaRebelo et al. (2010). The SSA of the peloids was performed using nine data points with N₂ as the adsorbate. The coefficient of determination (R²) for the linear BET for all samples was 0.999.

Cooling Kinetics

The cooling kinetics of the clay pastes were studied by mimicking the temperature changes during pelotherapy. Clay pastes that were matured for 90 days were used in the study. The samples were placed in a closed cylindrical Teflon container, with a volume of 50 mL, and heated until they reached and stabilized at 50°C. The container was then immersed in a 5 L thermostatic bath using a PRECISTERM model 6000138 (Selecta, Barcelona, Spain) at 32°C, which is the average temperature of the human epidermis (OECD, 2004). The temperature of the clay and the bath was measured using a digital thermometer Hanna HI 9043 (Hanna, Italy) until they reached the same temperature. According to Reference Cara, Carcangiu, Padalino, Palomba and TamaniniCara et al. (2000) and Reference Legido, Medina, Mourelle, Carretero and PozoLegido et al. (2007), the sample temperature (T) curves follow the function T = A + Be^−Kt , where A is the bath temperature, B is the difference between the starting temperature of the clay and the bath temperature (A), t is the cooling time, and K is the parameter that describe the thermal behavior of clay pastes based on temperature, calculated by the ratio between the instrumental constant of the apparatus and the heat capacity of the paste.

Capacity for absorbing jojoba pil

The oil obtained from seeds of the Jojoba plant (Simmondsia chinensis) finds applications in various pharmaceutical and cosmetic products. Due to its similarity to the natural sebum produced by the human body, it is highly regarded in these industries (Reference Gad, Roberts, Hamzi, Gad, Touiss, Altyar, Kensara and AshourGad et al., 2021; Reference Meier, Stange, Michalsen and UehlekeMeier et al., 2012). Furthermore, this substance is registered under the European Regulation on the Registration, Evaluation, Authorization and Restriction of Chemicals (REACH), ensuring its safe use in consumer cosmetics and personal care products (EC No. 1907/2006). To evaluate the sebum absorption capacity of the peloids, pure jojoba seed oil was utilized. 15 g of dry clay was placed on a glass plate, then jojoba oil was added dropwise to the clay from a known initial volume of oil until the desired consistency was achieved, resulting in a solid roll of clay. The amount of jojoba oil remaining was then weighed to determine the amount absorbed by the clay, allowing for the calculation of the oil absorption capacity.

Atterberg limits of peloids

The Atterberg limits were determined using the Casagrande Shell to obtain the liquid limit, and molding rolls on a glass plate were used to determine the plastic limit. The plasticity index was calculated following the guidelines of the Portuguese Standard, NP 143–1969. For analysis after 30 and 60 days of maturation, dried peloid samples were mixed with demineralized water for 24 h to allow absorption and to form a clay paste. Following this absorption period, the Atterberg limits were determined based on clay-paste samples.

Culturable microorganisms, coliform bacteria, and Escherichia coli

The concentration of culturable microorganisms was determined by immersion bath, using Plate Count Agar (PCA) (Liofilchem, Italy) and complying with the standard water quality – enumeration of culturable micro-organisms – colony count by inoculation in a nutrient agar culture medium (ISO 6222: 1999). The plates were incubated at 37°C for 48 h. Results were expressed as colony forming units per mL (CFU mL^–1). Three independent samples were analyzed on each sampling date and for each sample two replicated analyses were performed.

Coliform bacteria (total coliform and fecal coliform) and E. coli were enumerated by the filter membrane method (adapted ISO 9308–1: 2014 and ISO16649-2: 2001) using Chromocult selective culture medium M-FC (Merck, Germany) and Triptone Bile X-glucuronide (Merck, Germany), respectively. The plates were incubated at 37°C for total coliforms and at 44.5°C for fecal coliforms and E. coli for 24 h. The number of colony forming units per mL (CFU mL^–1) was determined. Three independent samples were analyzed on each sampling date and for each sample two replicate analyses were performed.

Yeasts and molds

Yeasts and molds were quantified using the spread-plate technique with Rose Bengal Chloride Agar from Lyophilchem, Italy. This method involves spreading a small volume of the sample onto the surface of a solid growth medium, the Rose Bengal chloride Agar (ISO 21527:2008). After incubation at 25 ± 1°C for 5 days, yeasts and molds present in the sample that have grown into visible colonies on the agar were subjected to morphology examination for identity confirmation. The number of colonies was then counted and reported as CFU mL^–1. Each sampling involved the analysis of three independent samples, and for each sample, two replicate analyses were performed, resulting in a total of six measurements per sample.

Chlorophyll a, b, and c

Chlorophyll a, b, and c concentrations were determined following the method described previously by Reference Jeffrey and HumpreyJeffrey and Humprey (1975). Water samples (50 mL) were filtered through 0.45 µm Whatman GF/F 47 mm Whatman filters (Giles, UK). To each filter, 10 mL of 90% acetone was added. The mixture was incubated at 4°C for 12-16 h. After incubation, the mixture was centrifuged at 2500 rpm for 10 min at 4°C. The absorbance of the supernatant was measured at 750, 664, 647, and 630 nm against a 90% acetone blank.

Chlorophyll a, b, and c (mg/m³) were estimated using the following equations:

(1) $\mathrm{chlorophyll}a=[11.85\left(A,664,-,A,750\right)-1.54\left(A,647,-,A,750\right)-0.08(A630-A750)]\times V1/(V2\times I)$

(2) $\mathrm{chlorophyll}b=[-5.43\left(A,664,-,A,750\right)+21.03\left(A,647,-,A,750\right)-2.66(A630-A750)]\times V1/(V2\times I)$

(3) $\mathrm{chlorophyll}c=[-1.67\left(A,664,-,A,750\right)-7.60(A647-A750)+24.52(A630-A750)]\times V1/(V2\times I)$

where: A630 = absorbance at 630 nm; A647 = absorbance at 647 nm; A664 = absorbance at 664 nm; A750 = absorbance at 750 nm; V1 = acetone volume at 90% used for extraction;

V2 = filtered sample volume; and I = spectrophotometer cell optical path (cm).

Microalgae

Microscopic analyses for the presence of green algae, cyanobacteria, and diatoms were performed using an optical microscope (Biomed Instruments, Guayaquil, Ecuador). The samples with the greatest chlorophyll contents, CR2 and CRO3, were subjected to analysis.