Emulium 3.1. Pre-experimental condi

Emulium

3.1. Pre-experimental condition
Each emulsion was prepared by using the same method and condition. Emulium Kappa –Propylene glycol with kojic dipalmitate was dissoived in the VCO-Squalene mixture at 65 C by stirring it with a magnetic whisk at 250 rpm for 10 min. Water could be added only after solubilization of the mixture in order to form a clear transparent solution.
3.2. Nano-emulsion
During the addition of water, the emulsion passed through two stages. The first stage include the incorporation of waterin-oil (w/o). During this stage, the emulsion become irregular inappearance with a large fraction that could be observed by eye. Conductivity during the first stage fluctuated at the beginning since the water a large fraction could conduct electricity; but after 2-3 min of the addition of the addition of the water, the conductivity was zero because the water had completely incorporated into the oil phase and the amulsion appeared homogenous. The second stage of emulsifiacation was the incorporation of oil-in-water (inversion of w/o to o/w). This stage also began with the presence of a large, distinct water fraction and an apparently non-homogeneous emulsion. At the beginning of stage two, i.e. the point of transition, the conductivity change from 0 to 100%. The emulsion was homogenized by mixing it with a magnetic whisk until it turned completely homogeneous (Fig.2). After homogenization, the emulsion was cooled to room temperature. The resulting emulsion was viscous (viscous cream) which was due to the proportion of surfactant and the lower proportion of water used. After cooling to room temperature, sufficient water was added to make it 100% (w/w) and the water and emulsion were mixed by using a hand spatula until homogenization process was complete
As noted above, the conditions under which Emulium Kappa was dissolved in the oil phase was 12.8% (w/w). In order to study the effect of squalene oil on stability , the ratio of surfactant to oil was kept consistent (1.4:1.2) Sevan ratios of VCO:squalene (as mentioned in Section 2.2.1) were evaluated. The quantity of water added for the inversion of formulations was almost equal to 12 ml.

3.3 Particle size
with the increasing squalene ratios, i.e. the stability of the emulsion imbroved with the addition of The resulting average droplet diameters of nano-emulsions with different squalene concentrations listed in Table 1 are given inFig.3.It was discovered that as the sequalene concentration increased, the Ostwald ripening however decreased and this in turn decreased the droplet growth. The droplet growth actually depends on the VCO:squalene ratio. The changes in droplet size as a function of storage time for the nano-emulions with different VCO:squalene ratios are given in Fig.3. Droplet size increased very slowly and the growth rate decreased squalene.The primaryb droplet size was not affected by the squalene ratios as shown in Fig.4. The addition of up to 20% squalene to the oil phase systematically had reduced the rate of droplet growth from 14.94 to 09 nm day-1 as shown in Fig.5. If squalene alone had been used as the
Oil phase,the system would be very unstable and the creaming would begin within 1-2 h.Thes the surfactant is discovered to be not suitable for the emulsification of squalene (Tadros et al., 2004).

3.4 Zeta- potential
The resulting zeta-potentials of nano-emulsions with different squalene concentrations listed in Table 1 are given in Fig.6.The droplets of the nano-emulsions were negatively charged. The zeata potential was -65.1mv for formulation (i) and increased dramatically to -101.8mV for formulaton(iv)as shown in Fig. 6. The stabiliy of the emulsion could be increased by expanding the surfact flocculation (Liu et al.,2006). In the system studied,it was revealed that the surface charges of the droplets increased as the squalene percentage increased (Table 1). The negative charges on the surface of VCO droplets covered with EK were the result fo tho adsortion of OH-ions on the o/w interface through hydrogen bounding.


4.Discussion
Nano-emulsions in the form of cream Wene prepared using Emulsion Inversion Point method.In order to explain the mecha-nism thai happened during the process of this Emulsion Inversion Point method,the steps of ultrafine-droplet formation in this low energy method is described as follows.When the water was added into the oil phase,the system wouly form the w/o emulsion, but with the increasing water volume.water droplets started to assemble and merge together to form bicintinous or lamellar stuctures(Fernandez et al..2004).These structues would decompose into small oil droplets with the increasing water volume (i.e.after ElP).These decompositions occurred due to the fact thai the interfacial tension at the inversion point was at the minimun.Basically because the study had used a higher surfactant concentrton(14%), this solubilized all the oil near the EIP that produced monomodal emulsion with ultrafine-sized droplet. On the other hand this higher surfactant concentrtion.however would enhance the stability of the emulsion by increasingthe viscosity of the external phase.During the emulsification process.the volume of water was considered a critical factor in the process of inversion and at the same time. the rate of water flow was also considered an important factor because the experiment was ren under higher tempertue (65°c)and this would increase the evaporation rate of water leading to the decrease water volume. For this reason,amodified system was used to decrease the rate of evaporation.The electrical circut was used to determine exactly the point of inversion as shown in Fig.1.The stages of nano-emulsion formation of EK/PG/VCD/ Squalene syatem by emulsion Inversion Point method was shown in Fig.2. The radius of droplets as a function of time for formulations with 14% (w/w) surfactant and 12.8% (w/w) oil wits different squalene proportions was shown in Fig.3.
The primary droplet diameter centered around 171.3-240.2 nm was not affected by the squalene ratio as shown in Fig.4.m on the other hand, it appeared that the higher the squalene the concentration was, the smaller the Ostwald ripening that could occur. The Ostwald ripening decreased dramatically from 14.94 to 0.97 nm day-1 when the squalene concentration was incr eased frn 2 to 20%, i.e., the growth rate was decreased approximately 15th times as shown in Fig.5 and this finding corresponded with thai as reported before (Fernandez et al.,2004:Tadros et al.,2004). Since the objective of the study was to identify the most stable nano-emulsions, it was observed that the differences between the Ostwald ripening of the formulation vi and vii was very small (1.7-0.97 nm day-1) but the differences in the squalene concentration was the double (10-20%), therefore vi would by considered best than vii from the economical point of view. The zeta potential for the for mulation shown in Table 1 shows that the charge increased from-65.1 to 101.8 mV with the increased squalene ratio as shown in Fig.6. Thus the repulsion forces betweem the droplets would be increased: this would lead to the enhancement of the stability of the nano-emulsions. The droplet charge was negative and this was due to the adsorption of hydroxyl ions ot the non-polar VCO droplet by the hydrogen bound. These results correspond with the work reportrd before (Liu et al., 2006).
The addition of squalene in our study was compatible with the Ostwald ripening theory which suggests that stable systems would produce results if a second insoluble or very poorly soluble oil phase was added to the system. This finding correspond with those of other reports (Tadros et al., 2004).This addition caused significant partitioning between different droplets and results in an equilibrium due to the differences in droplet size and chemical potential. If one component were to have zero solubility in the continuous phase, then the size distribution will not deviate from the initial one,i,e., the growth rate is zeso (Tadros et al.,2004).

5.Conlusions
Nano-emulsion whitening cream made from VCD and EK could be obtained by using the Emulsion Inversion Point method. Ostwald ripening (the main instability mechanism). Could be reduced by adding insoluble oil (squlene ) to the system.This phenomenon may be explained by tho equilibroium that was established between the differences of chemical potentioal of different droplet size and the differences of chemical potentioal of the two oils. The results of the zeta potential and the particle sizes well correlated with each othr.