MNPs were prepared using a modified chemical co-precipitation method. Two solutions with different molar ratio of ferric chloride (FeCl3·6H2O, Sigma–Aldrich):ferrous chloride (FeCl2·4H2O, Sigma–Aldrich) 2:1 and 3:2 were prepared. Each salt was mixed with 25ml of distilled water into a glass beaker in the required amount to provide molar ratios 2:1 and 3:2. Simultaneously, distilled water was heated up to 70°C and, under magnetic stirring, concentrated ammonium hydroxide (NH4OH, Sigma–Aldrich) was added at a required amount to obtain a 1.6 molar aqueous solution allowing enough time for the solution to stabilize at 70°C. Then, the chloride solution was added dropwise to the ammonia solution until obtaining a black precipitate, corresponding to magnetite, keeping the stirring for 30min. The precipitate was washed several times with distilled water to remove residual chlorides. The MNPs were air-dried at room temperature.

The obtained MNPs were analyzed by X-ray diffraction (XRD, Philips 3040) for the crystallographic structure identification and the crystallite size evaluation. The average crystallite size of samples was determined from the full-width at half-maximum (FWHM) of the strongest reflection, using the Scherrer equation. The morphology and grain size were determined by Transmission Electron Microscopy (TEM) (Titan 80300Kv). The magnetic properties of the samples were measured with a SQUID Quantum Design Magnetometer (VSM) in applied fields from −20 to 20kOe.

In order to determine if the MNPs have the ability to generate heat, certain quantities of MNPs were placed in a vial with distilled water. Each vial was stirred in a vortex and then placed in a magnetic induction in a solid state heating equipment (Ambrell, Easy Heat, 0224). The heating capacity of MNPs was measured under two different magnetic field strengths (10.2kAm−1; frequency of 362 and 200kHz), and the quantities of ferrite tested were 7, 9, 11, 13 and 15mg suspended in 2ml of distilled water. The resolution of the temperature sensor is ±0.1°C.

When the external membrane of the erythrocytes is destroyed, hemoglobin is released. It is possible to estimate the amount of destroyed erythrocytes in a given test by measuring the quantity of hemoglobin in a sample. This works as a reference to know the toxicity grade of a dispositive that will be in contact with human blood. The hemolytic activity of the nanoparticles was determined according to a previously reported method (Múzquiz-Ramos, Guerrero-Chávez, Macías-Martínez, López-Badillo, & García-Cerda, 2014).

Human blood was obtained from healthy donors, collected in heparinized-tubes and centrifuged at 3000rpm for 4min. The plasma was decanted, the erythrocytes were washed with Alsever's solution (dextrose 0.116M, sodium chloride 0.071M, sodium citrate 0.027M and citric acid 0.002M at pH 6.4) three times.

The erythrocytes solution was prepared with 100μl of purified erythrocytes diluted 1:99 with Alsever's solution. A quantity of 150μl of this solution was added to each individual tube with MNPs (0.25, 0.50 and 3.0mg/ml). The Alsever's solution and deionized water were used as negative (0% hemolysis) and positive (100% hemolysis) controls, respectively. The tubes were gently mixed using a rotator shaker and then incubated at 37±1°C within a shaking water bath for 30min. Finally, the tubes were centrifuged to measure the hemoglobin by UV–vis light spectrophotometry at a wavelength of 415nm (Spectronic, model Genesis 5). These tests were performed in triplicate.

Figure 1 shows the XRD patterns of MNPs obtained at two different molar ratios. The crystalline phase identified was magnetite. The main reflections at 30.1, 35.4, 42.9, 57.5 and 62.7 (2θ degrees), for (220), (311), (400), (511) and (440) Miller indexes, respectively (JCPDS card No. 19-0629).

Fig. 1.

XRD patterns of MNPs obtained at two different molar proportions of ferric chloride (FeCl3) and ferrous chloride (FeCl2) 2:1 and 3:2.

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Furthermore, the crystallite sizes (D) of the MNPs for the most intense peak (311) plane were calculated from the XRD data based on the Debye-Scherrer formula (Culity, 2001). The crystallite size rises from below to 12.5nm for the two molar proportions.

The magnetic hysteresis loops of the obtained MNPs are presented in Figure 2. As observed, the magnetic behavior was similar in both cases: low coercivity and high magnetic permeability.

Fig. 2.

Hysteresis loops of MNPs obtained at molar ratios 2:1 (a) and 3:2 (b).

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The obtained MNPs exhibit superparamagnetic behavior at room temperature, this phenomenon is due to their nanometric size and surface effects which dominate the behavior of the individual magnetic nanoparticles. Frenkel and Dorfman (1930) predicted that a particle of a ferromagnetic material, below a critical particle size (<15nm for common materials), consists of a single magnetic domain, that is, a particle is in a state of uniform magnetization in any field. In superparamagnetic particles, thermal fluctuations are strong enough to spontaneously demagnetize a previously saturated assembly; therefore, these particles have no hysteresis. Nanoparticles become magnetic in the presence of an external magnet, but they revert to a non-magnetic state when the external magnet is removed. This prevents an ‘active’ behavior of the particles from happening when there is no applied field. Once introduced in the living systems, particles are ‘magnetic’ only under the presence of an external field, which gives them a unique advantage when working in biological environments (Frenkel & Dorfman, 1930).

The size and morphology of the synthesized MNPs were performed by the TEM images shown in Figure 3. The results indicated that the nanoparticles are approximately spherical and the mean size is ranged between 8 and 12nm (Fig. 3a and c), which is consistent with the results obtained by XRD. These sizes are within the allowed range for magnetic hyperthermia applications (Veiseh, Gunn, & Zhang, 2010). Figure 3b and d shows the HRTEM micrograph, the corresponding electron-diffraction pattern indicates that the magnetite has a spinel-type structure. Furthermore, the interplanar distances observed d=0.148, 0.253, and 0.2967nm correspond to the crystallographic planes (440), (311) and (220) respectively, which is in line with standard JCPDS card No. 19-0629.

Fig. 3.

TEM images of MNPs obtained at molar ratios 2:1 (a) and 3:2 (c), and HRTEM micrograph of magnetite obtained at molar ratios 2:1 (b) and 3:2 (d).

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An important factor that must be considered is the heating ability of the MNPs when a magnetic field is applied; this according to the fact that magnetic hyperthermia consists of raising the temperature in the body through magnetic nanoparticles. When a magnetic nanoparticles system is subjected to an oscillating magnetic field, the absorbed energy is then converted into heat by several physical mechanisms (Neel relaxations and Brown rotation), and the transformation efficiency strongly depends on the frequency of the external field as well as the nature of the particles such as particle size and surface modification (Ma et al., 2004). The heating capacity of the magnetite nanoparticles was evaluated under an applied magnetic field of 10.2kAm−1 and frequencies of 200kHz (Fig. 4a) and 362kHz (Fig. 4b). Heating curves of the magnetite obtained at molar ratio 2:1 are shown in Figure 4, testing 7, 9, 11, 13 and 15mg of magnetite nanoparticles in 2ml of distilled water.

Fig. 4.

Magnetic heating of MNPs (7, 9, 11, 13 and 15mg) suspended in 2ml of distilled water at v∼362kHz and Hmax.∼10.2kAm−1 (a) and at v∼200kHz and Hmax.∼10.2kAm−1 (b).

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As expected, a more rapid increase in temperature is observed when higher concentrations of MNPs are used. Figure 4a shows that the suspension of 13mg/2ml reaches temperatures up to 41°C, in 15min. When a higher frequency is used (362kHz) at the same concentration, the 41°C was reached in just five minutes (Fig. 4b). The obtained temperature for the suspensions at the mentioned concentrations in both frequencies is suitable for magnetic hyperthermia treatment. It is important to highlight the feasibility of selecting between two different treatments: a fast one and a slower one, which may cause less health risk since it has a lower magnetic field.

Since these materials are most commonly used in biomedical applications, it is necessary to assess the biocompatibility of the synthesized samples. Thus, a hemolysis assay was conducted. The results of the hemolytic tests (Fig. 5) demonstrated that the hemolysis rates (HRs) of the samples were lower than 2%. These results indicate that the MNPs had non-hemolytic reaction at all tested suspension concentrations up to 3.0mg/ml. According to ASTM F 756-08 (ASTMF-756, 2009), HR<2% produced by any material could be considered as non-hemolytic.

Fig. 5.

Hemolysis (%) caused by different MNPs concentrations.

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