Preparation of 3D Print Scaffolds Fe3O4@ Food Oils/Chitosan/Polylactic Acid/Polyurethane Modied Natural Protein Pegylated for Cardiovascular Blood

Food oils used in 3D polysaccharides modied with natural protein polymer modied polymer scaffolds can help to reduce blood pressure. This study aimed to use food oils as blood pressure-reducing medicine, bind them to magnetic iron nanoparticles, then bind them to polymeric 3D scaffolds (chitosan, polylactic acid and polyurethane), modied with natural protein and nally separate them. This method made it possible to investigate different variables for nanoparticles. In this project, synthesis polymer, food medicinal oils, modied gelatin, PEGylation, food loading and release process in nanocarrier with different concentrations were examined and cell proliferation was optimized. The results show that 75% of the medicine loaded on iron magnetic NPs containing PEGylated polymer scaffolds was released. Cell proliferation was performed for the sample. In this process, modication of scaffolding with polysaccharides modied with natural protein and food oil increased the eciency of nanoparticles among the studied Allium sativum oil and Zingiber ocinale oils. These behaved very similarly to each other and A. sativum had the biggest effect in lowering blood pressure. The application of food medicine oils in 3D mode scaffolding has not been studied before and this is the rst analysis to do so, using nanoparticles.


Introduction
Today, there is a growing demand for woven vascular engineering, that is effective in the long-term for replacing or bypassing damaged arteries in various cardiovascular diseases. Ideal tissue engineering vessels should be biocompatible, blood compatible, and resistant to the spread of aneurysms, and be easily implantable in the body [1,2]. Research has shown that scaffolds are made from degenerated natural tissue or biodegradable biopolymers and synthetic polymers to make vascular bonds for tissue engineering. Polysaccharides are biological polymers that play a key role in improving health. Polylactic acid is considered to be one of the most widely used materials in 3D printing. Rapid decomposition in the environment (in just a few years) and use in medical products are among the features of this valuable substance [3]. The use of biocompatible and non-toxic substances chemically improves arti cial scaffolds and improves their mechanical properties, which is one of the requirements for the production of ideal vascular grafts [4]. Gelatin is a solid, semi-transparent, and insoluble substance derived from bovine bone or collagen in pig skin, and because of its resemblance to collagen and its biological origin, it has been introduced as an attractive polymer for tissue engineering applications [5]. Ganji et al.,[6] used castor oil and polyethylene glycol to produce a plant-based scaffold that was able to produce blood vessels in the animal phase without regurgitation and infection under rabbit skin. Mozumder et al., [7] studied biomedical applications of polymeric nanobiocomposites. Pourfarhangi et al.,[8] proposed a new way to build a polymer scaffold consisting of a decomposed cell network of the heart for use in cardiac tissue engineering. Khalili and Esmaeili2 were able to synthesize polyurethane for use in tissue engineering. They explained hybrid polymer properties of nano bers in anticoagulant drugs. O'Brien [9] explained different materials application in scaffolds concerning the tissue engineering eld. Tissue engineering with 3D printing can produce and repair damaged tissues engineering by combining cellular parts of the body with biocompatible materials. An [10] explained that -compared to synthetic polymers − 3D technical natural polymers can provide good biocompatibility for cells. The ability of natural polymers to print in 3D is usually weak so for this reason, indirect 3D printing was created for porous 3D scaffolds.
In this project, we tried to replace two food medicine oils (A. sativum oil and Z. o cinale oils) with chemical drugs and connect them to Fe3O4@NPs in the rst stage. Then we set out to connect them with polymer 3D scaffolds, and at the end of their PEGylation, ensure their effectiveness in gradually reducing blood pressure. Scheme 1 illustrates the steps for producing Fe3O4@ food medicine oil /CS/PLA/PU-Mo Ge-PEGylated.

Synthesis of magnetic iron oxide nanoparticles
307.2 g of hexahydrate of iron chloride, 97.7 g of short-grained iron chloride were dissolved in 100 ml distilled water to make magnetic NPs. The subsequent product was placed in a bathroom sonicator for 30 min, then stirred for 2 h under a stream of nitrogen gas. Concentrated ammonia was used as the precipitating agent. Following the reaction, the sediments were separated by a magnetic separation method with a 1.3 T magnet [and washed with distilled water and ethanol. The sediment was then dried in an oven at 40 0 C.

Connection of A. sativum oil and Z. o cinale oils to magnetic nanoparticles
In order to take advantage of the antihypertensive properties of medicinal plants, various food oils were used, including olive oil, sesame, coconut, almond, A. sativum oil and Z. o cinale oils, lavender and coriander. In this way, 0.5 g of each of the above oils was mixed with 0.5 g of iron magnetic NPs and the solvent was stirred on a magnetic stirrer for 24 h in the solvent. After this the obtained products were extracted. Fe 3 O 4 @ A. sativum oil and Fe 3 O 4 @ Z. o cinale oil formed in the section.

Preparation of CS/PLA/PU solutions for scaffolding
Polymeric scaffolding was done using solutions with concentrations of 4-8%. The best scaffolding was obtained from a solution of 6% of each, which was prepared from 2 g of polymer in 3.33 ml of formic acid. In the process Fe 3 O 4 @ A. sativum oil /CS/PLA/PU and Fe 3 O 4 @ Z. o cinale/CS/PLA/PU were produced.

Scaffolding Method
6% solutions of each polymer were scaffolded with a 3D printer and kept at 80 0 C temperature for 10 d.
After the solvent dried, they were placed in the freezer for 5 d.

Stabilization of scaffolding
In order to establish a connection between the molecules, polymer scaffolds were placed in a 2% volumetric GA solution for 4 h. They were then removed from the solution and rinsed with deionized water and nally placed in a freezer for 24 h. 2.7. Placing iron magnetic nanoparticles containing food oils on polymer scaffolds 0.5 g of each of the above extracted products was mixed with 0.5 g of modi ed polymer 3D scaffold and dissolved in a solvent for 24 h on a magnetic stirrer, after which the obtained products were extracted.

Modi cation of scaffolding containing magnetic nanoparticles of iron and medicine by Gelatin
In order to improve the adhesion of the cell to the scaffold's surface and to increase its surface properties for use in tissue engineering, 3D polymer scaffold containing magnetic iron NPs and drug was reacted with gelatin. In this way, 1g from the scaffold was mixed with 0.5 g gelatin in 100 ml water for 24 h and then the resulting sediments were collected. In the process  (Figure 1). In Figure 1A and D, the signal of iron magnetic NPs is seen at 500 cm −1 . The speci c peaks at 476 and 578 cm −1 may be due to O-Fe stretching vibration and 1645 cm −1 is related to H 2 O deformation, respectively [11]. In Figure 1B

XRD analysis
In order to evaluate suitable particle size and morphology, we used XRD analysis to con rm the results with SEM images. Figure Figure 2A and 2B indicates the most obvious changes in the XRD pattern of A. sativum oil (Figure 2A). The average crystalline size was obtained from X-ray diffraction data using Scherrer's formula: Where k=0.94, λ=0.154056 nm, and β is the full width at half maximum in radians [13,14]. XRD pattern of documented [15]. The results show that the two A. sativum oil and Z. o cinale oil indicate the closest behavior to other oils. Of these, A. sativum oil shows the most obvious changes (Figure 2A and 2B). In Figure 2A, which refers to the XRD analysis of the sample containing A. sativum oil, it clearly shows the changes in increasing both the NPs and polymers, and PEGylating the sample (Figure 2A). The XRD patterns exhibited peaks corresponding to  Figure 2B(c)], is shown in Figure 2B.  (575), which are similar to those reported before for Fe3O4 NPs [18,19]. The XRD of patterns showed signals at 14 to 30, related to polymers as indicated in other studies [20]. Figure  2B PLA and PU, respectively [21]. Figure 2B(c) show XRD of patterns revealed signals at 19 and 23, related to polyethylene glycol, after PEGylation, which is similar to previous studies [17]. The results show that A. sativum oil and Z. o cinale oil behave very similarly to other food oils and among these, A. sativum oil shows the most obvious changes ( Figure 2B(b) and Figure 2B(c)). In Figure 2A, which illustrates the XRD analysis of the sample containing A. sativum oil, it clearly depicts the changes involved in: rstly, increasing the NPS and the polymers; and secondly, PEGylating the sample.

SEM analysis
Morphological analysis was undertaken with the help of electron microscopic images. Figure 3A-C shows the SEM images of the samples. Figure 3A relates to Fe 3 O 4 @ A. sativum oil and Figure 3B illustrates the combination of Fe 3 O 4 @ A. sativum oil/CS/PLA/PU. Figure 3C corresponds to the combination Fe 3 O 4 @ A.
sativum oil /CS/PLA/PU-Mo Ge-PEGylated. In the SEM image of iron magnetic NPs connected to Fe 3 O 4 @ A. sativum oil, it can be seen clearly that the particles are uniformly aggregated, spherical shaped with a size of 6-30 nm [22]. Figure 3B shows the SEM image of Fe 3 O 4 @ A. sativum oil /CS/PLA/PU-Mo Ge-PEGylated, and it can be seen clearly that the particles are uniformly aggregated, spherical shaped with a size of 50-350 μm [2], [23,24]. Figure 3B shows the PEGylation of the 3D polymers (CS/PLA/PU) attached to the magnetic iron NPs containing the gelatin-coated A. sativum oil. In this study we attempted to examine the image with an electronic microscope. Since the sample was very thick and oily and did not dry completely even under vacuum, we had to dissolve it in a little methanol and then take a picture of it. Measurement of the sample when using scanning electron microscopy (SEM) revealed that the sample was 100 to 135 nm in size.

ZPS analysis
The particle has a surface charge inside the uid, and an increase in the concentration of ions with the opposite charge to the surface of the particle is always seen around the surface of the particle inside the uid. Thus, an additional layer of these ions surrounds the surface of the particle and forms an additional layer around the particle. When a particle moves in a uid, the surrounding layer also moves with the particle and moves with the particle, and it can be assumed that a hypothetical distance between the particle and the uid environment is the hypothetical distance of the extra layer that surrounds the particle. This distance is called the hydrodynamic distance and the potential at this distance is known as the zeta potential. In fact, the zeta potential is a parameter for the potential stability of the colloidal system. If all the particles in the suspension are negatively or positively charged, the particles tend to repel each other and show no tendency to coalesce.
The tendency of particles to repel each other is directly related to the zeta potential. In general, the limit of the suspension's stability and instability can be determined in terms of zeta potential.Show more Esmaeili and Khodaei [25] reported the negative ZPS of PU. They showed PU can be used as a conductive solution in the double-needled electrospinning method. The negative charge of the PU surface led to a better conduction of ions in the electrospinning device. It also caused better blood compatibility with PU than other polymers. They showed that the negative and positive numbers obtained can be effective in clinical tests [3]. So, we decided to do this test on our sample that contained the three polymers (CS/PLA/PU).
The results show that the zeta potential is -1.29 mV, the zeta deviation is 0 mV and the ion conductivity is 13.  Table 1 shows the results of light absorption of the studied groups for MTT solution in a period of 24 h. Each drug concentration was repeated three times. The results show that the drug used in 5 concentrations is not signi cantly different from the control group without the drug and the combination does not show a cytotoxic effect.

Conclusion
The aim of this study was to use food medicine oil as a blood pressure-reducing medicine. The polymeric 3D print concerned the scaffolds process (Fe 3 O 4 @ food medicine oil /CS/PLA/PU-Mo Ge-PEGylated). UV-Vis, FT-IR spectra, ZPS, XRD, SEM, MTT test served to determine the data. The results show that 75% of the medicine loaded on iron magnetic NPs containing PEGylated polymer scaffolds was released. Finally, the product obtained was PEGylated and this increased its durability and stability. The best results were obtained at pH = 7.4. This examination show 3D print in the scaffolds process can be more effective for the drug delivery system. It is suggested that future research could investigate industrial synthesis with food medicinal oils for scaffolds.