Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019                           RESEARCH 
DOI: 10.17482/uumfd.560358 
 
 
INVESTIGATION OF THE EFFECTS OF SOME PROCESS 
PARAMETERS ON THE MORPHOLOGICAL PROPERTIES OF 
POLYURETHANE NANOFIBROUS MATS CONTAINING BLACK 
SEED OIL 
 
 
 
* 
Cansu ARAS
*
Şebnem DÜZYER GEBİZLİ  
** 
Elif TÜMAY ÖZER
*
Esra KARACA  
 
 
Alınma: 03.05.2019 ; düzeltme: 25.06.2019 ; kabul: 27.06.2019 
 
 
Abstract: Black seed and its extracts have been used in alternative medicine since ancient times. The aim 
of this study is to produce and characterize composite nanofibrous surfaces by electrospinning with the 
addition of black seed oil (BSO) with different concentrations into the thermoplastic polyurethane 
polymer for wound dressings. During electrospinning the flow rate, and the distance between the needle 
and the collector were changed. The morphologies of the surfaces were analyzed by scanning electron 
microscopy (SEM). The nanofiber diameters, pore size and porosity of the nanofibrous mats were 
determined. The presence of black seed oil was investigated by FTIR analysis and the wettability of the 
surfaces was examined by contact angle measurements. As a result, optimum electrospinning process 
parameters and the most appropriate black seed oil concentration were determined to produce continuous, 
uniform and bead-free nanofibers. 
Keywords: Polyurethane, black seed oil, electrospinning, composite nanofiber 
 
Çörekotu Yağı İçeren Poliüretan Nanolifli Yüzeylerin Morfolojik Özellikleri Üzerine Bazı Proses 
Parametrelerinin Etkilerinin Araştırılması 
Öz: Çörekotu tohumu ve ondan elde edilen ekstraktlar antik çağlardan beri alternatif tıp alanlarında 
uygulanmaktadır. Bu çalışmada, termoplastik poliüretan polimeri içerisine farklı konsantrasyonlarda 
çörek otu yağı ilave edilerek, elektro çekim yöntemi ile yara örtüsü amaçlı nanolifli kompozit yüzeyler 
üretilmesi ve karakterize edilmesi amaçlanmıştır. Üretim esnasında besleme ünitesi ile toplayıcı 
arasındaki mesafe ve besleme oranı değiştirilerek; elde edilen yüzeylerin morfolojileri taramalı elektron 
mikroskopu (SEM) ile analiz edilmiştir. Nanolifli yüzeylerin, nanolif çapı, gözenek boyutu ve 
gözeneklilikleri tayin edilmiştir. Nanolifli yapı içerisindeki çörek otu yağının varlığı FTIR analizi ile ve 
yüzeylerin ıslanabilirlik seviyesi temas açısı ölçümleri ile incelenmiştir. Sonuç olarak; sürekli, üniform ve 
boncuk içermeyen nanolifler elde etmek için çörekotu yağı katkısı için en uygun konsantrasyon ve 
optimum elektro çekim proses parametreleri belirlenmiştir. 
Anahtar Kelimeler: Poliüretan, çörekotu yağı, elektro çekim, kompozit nanolif 
                                                          
*
   Bursa Uludag University, Faculty of Engineering, Textile Engineering Department, 16059, Gorukle, Bursa  
**
  Bursa Uludag University, Faculty of Arts and Sciences, Chemistry Department, 16059, Gorukle, Bursa 
     Corresponding Author: Esra Karaca (ekaraca@uludag.edu.tr) 
 This study is a part of the master thesis of the first author 
 
671 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
1. INTRODUCTION 
Nigella Sativa (NS), commonly known as ―black seed‖, is an herbaceous plant that grows 
around of Mediterranean countries (Zaoui et al., 2002). The black seed and its extracts have the 
wide variety of applications in the traditional medicine and it can be use on treatment of various 
diseases including diabetes, asthma, flatulence, polio, kidney stones, and abdominal pains. 
Many pharmacological studies have been conducted to investigate its biological activities and 
therapeutic properties such as analgesic and anti-inflammatory effect (Hajhashemi et al., 2004), 
anti-cancer (Gali-Muhtasib et al., 2006), antibacterial activity (Randhawa et al., 2016), anti-
fungal effect (Aljabre et al., 2005), anti-oxidant effect (Burits and Bucar, 2000). Main 
components of black seed oil (BSO) are saturated/unsatured fixed oil, essential oil (0.4-0.45%), 
carbohydrate (33-34%), protein (16-19.9%), amino acid, alkaloid, tannins, saponins, minerals 
(calcium, zinc, phosphate), vitamins (ascorbic acid, thiamine, niacin, pyridoxine and folic acid) 
(Güzelsoy et al., 2018). The thymoquinone, which is known to cause for many therapeutic 
properties, is a major active chemical component (30%-48%) of essential oil of the black seed 
(Ahmad et al., 2013). Many studies have been also issued to prove therapeutic effects of 
thymoquinone (Kalhori et al., 2018; Majdalawieh, 2017).  
Polymeric nanofibers possess unique properties, such as ultra-fine fiber diameter, high 
surface area per unit mass, high porosity, small pore size, high mechanical properties, and extreme 
flexibility depending on the polymer structure. Therefore, they are favorable for many 
applications (Akduman and Kumabasar, 2017 and Mi et al., 2015). Electrospinning is an 
effective method for the production of polymer nanofibers with the usage of electrostatical 
forces. In this method, a droplet of a polymer solution is subjected to an electrical field. With 
the increasing voltage, the solvent evaporates, leaving behind a mat of dry polymeric nanofibers 
on the collector (Tijing et al., 2012; Almetwally et al., 2017). 
 Due to their outstanding properties, nanofibrous mats present a wide range of application 
possibilities from agriculture to protective clothing. Among many application areas, nanofibrous 
mats are promising for medical applications such as tissue engineering, drug delivery, wound 
healing, tumor therapy, and barrier textiles due to their small fiber diameter, high surface area to 
volume ratio, small pore size, high porosity and high mechanical properties (Huang, et al., 2003; 
Chronakis, 2005). 
 Although electrospinning is relatively a simple method compared to other nanofiber production 
methods, there are many parameters affecting the morphology of the nanofibers. These parameters are 
mainly solution parameters (viscosity, surface tension, pH, molecular weight of the polymer, etc.), 
process parameters (flow rate, spinning distance, voltage, needle diameter, etc.) and ambient 
parameters (temperature and humidity). In order to produce an appropriate nanofibrous mat with 
desired properties, these parameters should be carefully selected (Teo and Ramakrishna, 2006; 
Theron et al., 2004). 
 Polyurethane (PU) is a highly used polymer in medical applications because of their 
biocompatible nature, non-toxicity, controlled degradation, good barrier properties and 
capability of gas and water permeability (Detta et al.,2010). They are a type of polyurethane 
(PU) composed of chemical reaction between isocyanates (hard segments) and polyols (soft 
segments) and contain repeating urethane groups (Sharmin and Zafar, 2012). They also have 
high elongation, good mechanical properties, water insolubility, abrasion and tear resistance 
properties (Akduman et al., 2016). There are many studies reported in the literature on the 
medical applications of PU nanofibers as vascular grafts (Theron et al., 2010), coating materials 
for implantable biosensors and stents (Wang et al., 2018; Pant et al., 2015), tissue engineering 
applications (Mi et al., 2014), heart valve (Chen et al., 2009), drug delivery systems (Saha et al., 
2014), wound healing applications (Hacker et al., 2013; Tan et al., 2015; Guo et al., 2012), etc. 
Recently, various researches have been focused on developing wound dressings blended with 
essential oils such as murivenna, rosemary, oregano, cinnamon (Manikandan, et al., 2017, 
Rieger and Schiffman, 2014; Liakos et al., 2017; Wen et al., 2016). However, to the best of our 
672 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
knowledge, there is no research explaining production and characteristics of PU nanofibrous 
mats containing black seed oil. 
 The aim of this study is to produce PU/BSO nanofibrous mats by electrospinning, to 
determine the optimum solution and process parameters (flow rate and spinning distance) for 
the electrospinning of PU/black seed oil nanofibers, and to investigate the effect of solution 
properties and process parameters on the morphology of PU/BSO nanofibrous mats. Therefore, 
PU/BSO solutions with different concentrations were prepared. The solutions were 
characterized in terms of viscosity, pH and surface tension. PU/BSO nanofibers were produced 
by using single needle electrospinning process with different flow rates and spinning distances. 
The surface properties were investigated by Scanning Electron Microscopy (SEM) studies and 
contact angle measurements. Fourier Transform Infrared spectrometry (FTIR) analyses were 
performed in order to understand the chemical structure of the fibers. SEM studies showed that 
PU and PU/BSO nanofibers were successfully with diameters mostly below 500 nm. The 
diameters and contact angle values were slightly decreased depending on the BSO content in the 
nanofibrous mat. It was also seen that; process parameters have significant effect on the mat 
morphologies. 
 
2. MATERIALS AND METHODS 
    2.1 Materials 
    To prepare PU and PU/BSO electrospinning solutions, polyester-based thermoplastic PU 
3
(BASF Elastollan®) with a molecular weight of 107.010 g/mol and a bulk density of 1.19 g/cm  
was used. Cold pressed black seed oil was supplied from a local farmer in Bursa- 
Mustafakemalpaşa (Turkey). Dimethylformamide (DMF) (Sigma-Aldrich, USA) was used as 
solvent to prepare the spinning solutions. All the chemicals were used as received without any 
further purification. 
 2.2 Methods 
2.2.1 Production of PU and PU/BSO nanofibrous mats 
Prior to the solvent preparation, the fatty acid composition of black seed oil was determined. 
Analysis of fatty acid composition of black seed oil was carried out using an Agilent 6890 N 
GC gas chromatography-flame ionization dedector (GC–FID) (Agilent Technologies, Palo Alto, 
CA). An HP-88 fused-silica capillary column 100m×0.25 i.d., with 0.20 um film thickness was 
employed. The injector temperature was set at 250 C. The GC oven temperature was held at 
−1
120 C for 1 min, then increased to 175 C at a heating rate of 10 C min , 210 C at a heating 
−1 −1
rate of 3 C min , 240 C at a heating rate of 5 C min  and the temperature was held for 5min. 
Standard test method of TS EN ISO 12966-2 and TS EN ISO 12966-4 was used in analysis. The 
test was repeated three times. 
 In this study, three different solutions were prepared with 5%, 10%, and 15% (v/v) BSO 
addition into the spinning solution. PU solutions without addition of BSO were also prepared as 
reference. In order to prepare PU/BSO electrospinning solutions, 10% (w/v) PU and BSO with 
different concentrations were dissolved in DMF and stirred at room temperature for 24 h. For 
the sake of brevity, the reference sample was denoted as PU, while the solutions with different 
BSO concentrations were denoted as PU/BSO5, PU/BSO10, and PU/BSO15. 
The prepared solutions and pure black seed oil were characterized in terms of viscosity, 
surface tension, and pH. The viscosities of all solutions were determined by Brookefield 
viscometer at 100 rpm. Surface tension values of the solutions were measured by KSV-The 
Modular CAM 200 tensiometer and the pH values were determined by a Hanna pH tester. 
Electrospinning was performed with an Inovenso Electrospinning Equipment. All 
experiments were carried out 15 kV at room temperature. The nanofibrous mats were collected 
673 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
on a rotating drum with a speed of 200 rpm. All electrospun mats were produced from 
electrospinning solutions of 20 mL. The details of the process are given in Table 1. 
 
Table 1. The electrospinning parameters 
BSO Flow rate Distance 
PU concentration (%) Sample ID 
concentration (%) (mL/h) (cm) 
18 PU-1 
0.5 
20 PU-2 
- 
0.7 18 PU-3 
 20 PU-4 
0.5 18 PU/BSO5-1 
5  20 PU/BSO5-2 
 0.7 18 PU/BSO5-3 
 20 PU/BSO5-4 
10 
0.5 18 PU/BSO10-1 
10  20 PU/BSO10-2 
 0.7 18 PU/BSO10-3 
 20 PU/BSO10-4 
0.5 18 PU/BSO15-1 
15  20 PU/BSO15-2 
 18 PU/BSO15-3 
0.7 
20 PU/BSO15-4 
2.2.2 Characterization of the PU and PU/BSO nanofibrous mats 
SEM studies 
 
The surface morphologies of the nanofibrous mats were examined by a Scanning Electron 
Microscope (SEM) (Carl Zeiss Evo 40). Fiber uniformity, fiber diameter distribution, fiber 
evenness in the mats was observed. The surfaces were coated with a thin conducted gold layer 
prior to SEM observations. Fiber diameters were calculated from the SEM images by measuring 
100 random diameters using image analysis software (Image J). 
 
Pore Size and Porosity Calculations 
 
2
In order to calculate pore size and porosity, the samples were cut as 2x2 cm . Afterwards the 
samples were weighted by a digital scale and the thicknesses of the samples were measured by a 
digital micrometer. The measurements were repeated three times. 
The mean effective pore diameter (pore size) and porosity of the electrospun nanofibrous mats 
were calculated using the following equations (Zhu et al., 2015; Ma et al., 2005; Düzyer, 2017): 
 
                                               ε= (1- ρe/ρf) x100…………………………………………….. (1) 
 
Where ε is the porosity of the electrospun nanofibrous mat, ρe and ρf are the electrospun 
nanofibrous mat density and bulk PU density, respectively.  
 
                                                D= πd/4(1-ε) ……………….…………………………………(2)            
Where D is the mean effective pore diameter, d is the mean nanofiber diameter and ε is the 
mean porosity of the sample. 
 
 
 
674 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
Contact Angle Measurements 
The contact angle values of the electrospun nanofibrous mats were determined using KSV-
The Modular CAM 200 Contact Angle Measurement System. A water droplet was dispersed on 
each sample by a micropipette, and the images were captured as quickly as possible after water 
droplet was placed onto the sample surface. Three measurements were performed on each 
sample and mean values were recorded.  
ATR-FTIR analysis 
A Perkin–Elmer Spectrum 100 FTIR Spectrometer (Perkin Elmer, Waltham, MA, USA) 
equipped with an attenuated total reflectance (ATR) apparatus was used to obtain FTIR spectra 
-1
of oil, PU and PU/BSO nanofibrous mats within the range of 600-4000 cm  with the resolution 
-1
of 2 cm . 
3. RESULTS AND DISCUSSION 
3.1. Characterization of PU, BSO and PU/BSO solutions 
Solution parameters play a key role on the morphology of the nanofibers. Table 2 shows the 
properties of the BSO, PU and PU/BSO solutions.  
Viscosity of a solution is dependent on the chain entanglements in the solution. In 
electrospinning, a critical chain entanglement is required to obtain nanofibers (Mi et al., 2013, 
Ramakrishna et al., 2005). It can be seen that, BSO addition into the spinning solution resulted 
in higher viscosities due to the increase in polymer concentration per unit area at a constant 
volume.  
 Surface tension of the polymer solution directly affects polymer jet formation, as the 
electrostatic forces in the electric field must overcome the surface tension of the solution to 
form a polymer jet (Teo and Ramakrishna, 2006). With the BSO addition into the spinning 
solution, the surface tension values of the solutions were slightly increased indicating that 
higher electrical forces are needed to overcome the surface tension of the polymer droplet at the 
spinneret (Demir et al., 2001). This result is also compatible with the viscosity increase of the 
solutions.  
 Since pure BSO has an acidic nature, the pH of the PU/BSO solutions have slightly 
decreased, compared to pure PU solution. Adding an acidic component into the spinning 
solution leads to increase in the conductivity of the solution because of the increase in the 
number of ions. This may affect the diameter of the nanofibers. Thinner nanofibers can be 
produced from the more conductive solutions (Ramakrishna et al., 2005). 
 
Table 2. The solution properties 
Viscosity Surface tension 
Solution pH 
(cP) (mN/m) 
BSO 38.4 33.29 5.73 
PU 1213 35.24 10.36 
PU/BSO5 1295 35.97 9.41 
PU/BSO10 1451 35.44 9.27 
PU/BSO15 1533 38.40 9.10 
 
3.2. Characterization of PU and PU/BSO nanofibrous mats 
The nanofibrous mats (Figure 1) were successfully produced from solutions of PU and 
PU/BSO by electrospinning. The properties of the electrospun nanofibrous mats were given in 
Table 3. Generally, PU nanofibers without BSO had diameters between 400-700 nm. The 
increase in viscosity of the solution leads an increase in diameter (Ramakrishna et al., 
2005).With the addition of BSO, the viscosities of the solutions were increased. When the 
675 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
concentration of BSO in the solution was increased, the fiber diameters increased. However,  
PU/BSO nanofibers showed smaller diameters than PU nanofibers. This is maybe due to the pH 
change in the spinning solution. Since the number of ions increased with the addition of BSO, 
the diameters were decreased.  
 
Figure 1: 
SEM images of the nanofibrous mats 
Table 3. The properties of the nanofibrous mats  
Sample Diameter (nm) Pore size (µm) Porosity (%) Contact angle (°) 
PU-1 474 ± 98 0.89 58 106.3 ± 4.3 
PU-2 408 ± 98 1.90 83 103.5 ± 7.9 
PU-3 719 ± 94 3.24 83 114.1 ± 2.8 
PU-4 599 ± 93 2.54 81 118.4 ± 7.1 
676 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
PU/BSO5-1 321 ± 82 0.61 59 98.8 ± 5.6  
PU/BSO5-2 
283 ± 78 0.64 65 101.3 ± 2.6 
PU/BSO5-3 377 ± 42 1.48 80 97.9 ± 1.3 
PU/BSO5-4 357 ± 61 1.17 76 105.0 ± 6.6 
PU/BSO10-1 
346 ± 62 0.49 45 84.2 ± 8.4 
PU/BSO10-2 
338 ± 68 0.72 63 102.4 ± 2.8 
PU/BSO10-3 443 ± 72 1.03 66 98.2 ± 4.7 
PU/BSO10-4 433 ± 88 1.22 72 113.7 ± 2.4 
PU/BSO15-1 
460 ± 83 0.92 61 96.3 ± 6.1 
PU/BSO15-2 
620 ± 81 1.50 67 95.6 ± 7.2 
PU/BSO15-3 675 ± 90 0.87 39 86.4 ± 3.3 
PU/BSO15-4 794 ± 80 1.65 62 97.1 ± 1.4 
  
In the study, the effect of flow rate and the distance between the needle and the collector on 
surface morphology were also investigated. When the flow rate was increased from 0.5 mL/h to 
0.7 mL/h, nanofibers with larger diameters were produced (Figure 2), as expected. Also, with 
the increase in flow rate, the pore sizes of the nanofibrous mats were increased, nanofibers were 
flattened, and nanofiber web formation was observed. In electrospinning, if the flow rate is 
high, due to the greater volume of solution drawn from the needle tip, the jet needs longer time 
to dry. As a result, the solvents in the deposited fibers may not have enough time to evaporate. 
Evaporation of some amount of residual solvent from the fibers on the collector may cause the 
fibers to fuse together at contact points where they become flattened and form webs 
(Ramakrishna et al., 2005; Li and Wang, 2013, Baji et al., 2010). Although the increase of the 
fiber diameter is caused by flattening, the increase in the pore size might be associated with the 
dissolution of some fiber during solvent evaporation and the formation of new pores. 
The distance between the needle and the collector also affect the nanofiber morphology and 
diameter. If the distance is short, the fiber cannot find enough time to solidify before reaching 
the collector. When the distance is increased, the polymer jet exposed to higher electrical forces, 
the flight time of the jet increases as a result, thinner nanofibers are obtained (Li and Wang, 
2013). In this study, PU and PU/BSO nanofibrous mats were produced with different distances 
at 18 cm and 20 cm. It was seen that with the increasing distance, the nanofibrous mats with 
higher porosity, higher pore size, and thinner fibers were produced (Figure 3).  
 
677 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
 
Figure 2: 
The effect of flow rate on the diameters of nanofibers produced with different distances:a) 18 
cm, b) 20 cm 
 
 
Figure 3: 
The effect of distance on the diameters of nanofibers produced with different flow rates: a) 0.5 
mL/h, b) 0.7 mL/h 
 
Contact angle measurements give information about the surface characteristics of the 
materials such as, surface wettability, adhesion, hydrophobicity, absorption, etc. (Hsieh, 2001). 
In this study, all PU and PU/BSO nanofibrous mats showed contact angle values higher than 
90° indicating that all the surfaces were hydrophobic due to the chemical structure of PU 
polymer. Pure PU nanofibrous mats produced with different flow rates and distances had 
contact angle values changing from 103.5° to 118.4°. The lowest contact angle was observed as 
86.4° for the samples produced from the solutions containing 15% wt. BSO. Although, BSO has 
a hydrophobic nature, adding BSO into the nanofiber structure decreased the contact angle 
values. Contact angle values are dependent on the compounds present at the surface, the surface 
roughness, and the surface morphology. Surface morphology and roughness of the nanofibrous 
mats are affected by the diameter of the nanofibers, pore sizes and porosity of the nanofibrous 
mats. Highly porous surfaces show high contact angle due to the air pockets trapped under the 
liquid drop (Darmanin and Guittard, 2014). In the present study, pure PU nanofibrous mats had 
higher porosity compared to the PU/BSO nanofibrous mats (Table 3). Therefore, more porous 
surfaces produced from pure PU solutions, showed higher contact angle values. This proved that 
surface structure has a significant effect on the wettability of the nanofibrous mats.‖. FTIR 
analysis were performed in order to show the presence of BSO in the nanofibrous mats (Figure 
4). FTIR analysis are not affected by the concentration of the spinning solution. Although, the 
concentration may affect the intensity of the peak, it doesn’t affect the location of the peak. 
Therefore, FTIR spectrums of BSO, pure PU nanofibrous mat and PU/BSO nanofibrous mat 
-1 -1
were given in this study. The spectrum of pure PU exhibited peaks at 3327 cm , 2954 cm , 
678 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
-1 -1 -1 -1 -1 -1 -1 -1
2865 cm , 1727 cm , 1701 cm , 1597 cm , 1527 cm , 1220 cm , 1142 cm  and 770cm . The 
-1
peak at 3327 cm  is a characteristic broad of PU that corresponds with stretching vibration of 
-1 -1
the N-H in urethane groups and the peak at 1597 cm and 1527 cm shows the vibration of the 
NH stretch (Tang and Gao, 2017). The other absorption peaks of pure PU were observed at 
-1 -1 
2954 cm  and 2865 cm that denote CH2 asymmetric vibration and CH3 symmetric vibration, 
-1 -1 
respectively (Tijing et al., 2012). The peaks at 1701 cm and 1727 cm exhibit stretching 
vibration of carbonyl group (C=O) in hard segments and C-O vibration corresponding to alcohol 
-1 -1 -1 
groups were observed at 1220 cm , 1142 cm , 770cm (Ayyar et al., 2017). 
    Triacylglycerol composition (TAG) is the main compound of oils and fats, comprising 96–
98% of them. The dominant TAGs in black seed oil are mainly tri-linoleoyl, oleoyl-di-linoleoyl, 
palmitoyldi-linoleoyl, palmitoyl-oleoyllinoleoyl and dioleoyl-linoleoyl (Mazaheri et al., 2019). 
It was supported by the fatty acid composition of BSO results (Table 4). It is well known that 
-1 -1 
TAGs response to characteristic peaks were at 3009 cm (trans =C-H stretch), 2923 cm (-CH2 
-1 -1 
symmetrical stretching), 2854cm (- CH2 asymmetrical stretching), 1743 cm (-C=O stretching 
of esters) and 1659 (-C=C asymmetrical stretching) due to the dominance of carbon chains in 
the unsaturated fatty acids (Nurrulhidayah et al. 2011; Kalhori et al., 2018; Yang et al., 2005).  
-1 
The PU/BSO nanofiber spectrum was similar to PU nanofiber spectrum. The peak at 3325 cm
-1 
and 2951 cm related to stretching vibration of the N-H and C=N which are characteristic bond 
-1 -1
of PU. But, the peak at 2926 cm  and 2855 cm  were due to the presence of oil in the 
nanofiber.  
 
Table 4. The main fatty acid composition of BSO 
 
Components Amount (%) 
Linoleic acid (C18:2) 55.10 ± 4.00 
Oleic acid (C18:1) 23.60 ±1.80 
Palmitic acid (C16:1) 11.70 ± 1.00 
Stearic acid (C18:0) 3.15 ± 0.24 
Eicosenoic ccid (C20:3) 2.57 ± 0.01 
 
 
Figure 4: 
 FTIR spectra of the BSO, PU nanofibrous mat, and PU/BSO nanofibrous mat 
 
 
679 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
4. CONCLUSION 
BSO is widely used for medical applications due to its anti-inflammatory, and antimicrobial 
properties. PU is a biocompatible, non-toxic, and non-inflammatory polymer that has been 
intensively used in wound dressings. Polymeric nanofibers provide excellent surfaces for wound 
healing because of their unique properties.  
 In the study, PU and PU/BSO nanofibrous mats were produced by electrospinning. The 
effect of BSO content, and electrospinning parameters such as flow rate and spinning distance 
on the morphological properties of nanofibrous mats were investigated. 
SEM results showed that pure PU nanofibers had diameters between 400-700 nm. With the 
increasing flow rate, diameters of the PU nanofibers were increased, whereas the diameters 
were decreased with the increasing spinning distance.  
Depending on the BSO content in the polymer solution, the nanofiber diameters also 
increased due to the increase in viscosity. The lowest diameter was obtained with the samples 
produced from 5% wt. BSO containing solutions.  
 BSO addition also had an effect on the wettability of the nanofibrous mats. Although BSO 
has a hydrophobic nature, contact angle values were decreased with the increase in BSO content 
due to the surface morphology. This indicates that not only the chemical structure of the BSO, 
but also the porosity play an important role on wettability of the nanofibrous mats. FTIR results 
showed that, BSO was successfully loaded into the nanofibrous structure and it was compatible 
with PU.  
It can be concluded that, PU/BSO nanofibrous mats can be promising for wound healing 
applications due to their high porosity, reasonable wetting property, and small fiber diameters.  
REFERENCESS 
1. Ahmad, A., Husain, A., Mujeeb, M., Khan, S. A., Najmi, A. K., Siddique, N. A., & Anwar, 
F. (2013) A review on therapeutic potential of Nigella sativa: A miracle herb, Asian Pacific 
Journal of Tropical Biomedicine, 3(5), 337–352. doi:10.1016/s2221-1691(13)60075-1 
2. Akduman, C., Özgüney, I., & Kumbasar, E. P. A. (2016)  Preparation and characterization 
of naproxen-loaded electrospun thermoplastic polyurethane nanofibers as a drug delivery 
system. Materials Science and Engineering, 64, 383–390. doi:10.1016/j.msec.2016.04.005 
3. Akduman, C., & Kumbasar, E. P. A. (2017)  Electrospun Polyurethane Nanofibers, Aspects 
of Polyurethanes. doi:10.5772/intechopen.69937  
4. Aljabre, S. H. M., Randhawa, M. A., Akhtar, N., Alakloby, O. M., Alqurashi, A. M., & 
Aldossary, A. (2005) Antidermatophyte activity of ether extract of Nigella sativa and its 
active principle, thymoquinone, Journal of Ethnopharmacology, 101(1-3), 116–119. 
doi:10.1016/j.jep.2005.04.002  
5. Almetwally, A. A., El-Sakhawy, El-shakankery, Elshakankery, M. H, & M., Kasem, M. 
(2017). Technology of nano-fibers: Production techniques and properties - critical review, 
Journal of the Textile Association, 78(1), 5-14.  
6. Ayyar, M., Mani, M. P., Jaganathan, S. K., & Rathanasamy, R. (2017) Preparation, 
characterization and blood compatibility assessment of a novel electrospun nanocomposite 
comprising polyurethane and ayurvedic-indhulekha oil for tissue engineering applications. 
Biomedical Engineering/ Biomedizinische Technik. doi:10.1515/bmt-2017-0022 
7. Baji, A., Mai, Y. W., Wong, S. C., Abtahi, M., & Chen, P. (2010) Electrospinning of 
Polymer Nanofibers: Effects on Oriented Morphology, Structures and Tensile Properties, 
Composites Science and Technology, 70, 703-718. doi: 
https://doi.org/10.1016/j.compscitech.2010.01.010 
680 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
8. Burits, M. & Bucar, F. (2000) Antioxidant activity of Nigella sativa essential oil. Phytother. 
Res., 14: 323-328. doi:10.1002/1099-1573(200008)14:5<323::AID-PTR621>3.0.CO;2-Q 
9. Chen, R., Morsi, Y., Patel, S., Ke, Q., & Mo, X. (2009) A novel approach via combination 
of electrospinning and FDM for tri-leaflet heart valve scaffold fabrication. Frontiers of 
Materials Science in China, 3(4), 359–366.doi:10.1007/s11706-009-0067-3  
10. Chronakis, I. S. (2005) Novel nanocomposites and nanoceramics based on polymer 
nanofibers using electrospinning process—A review, Journal of Materials Processing 
Technology, 167(2-3), 283–293. doi:10.1016/j.jmatprotec.2005.06.053 
11. Darmanin, T. & Guittard, F. (2014) Wettability of conducting polymers: from 
superhydrophilicity to superoleophobicity, Progress in Polymer Science, 39, 656-682. doi: 
http://dx.doi.org/10.1016/j.progpolymsci.2013.10.003 
12. Demir, M. ., Yilgor, I., Yilgor, E., & Erman, B. (2002) Electrospinning of polyurethane 
fibers, Polymer, 43(11), 3303–3309. doi:10.1016/s0032-3861(02)00136-2  
13. Detta, N., Errico, C., Dinucci, D., Puppi, D., Clarke, D. A., Reilly, G. C., & Chiellini, F. 
(2010) Novel electrospun polyurethane/gelatin composite meshes for vascular grafts, 
Journal of Materials Science:Materials in Medicine, 21(5), 1761–
1769.  doi:10.1007/s10856-010-4006-8 
14. Düzyer, Ş. (2017) Fabrication Of Electrospun Poly (Ethylene Terephthalate) Scaffolds: 
Characterization And Their Potential On Cell Proliferation In Vitro, Tekstil Ve 
Konfeksiyon, 27(4), 334-341 WOS:000419066800002 
15. Gali-Muhtasib, H., Diab-Assaf, M., Boltze, C., Al-Hmaira, J., Harting, R., Roessner, A., & 
Schneider-Stock, R. (2004) Thymoquinone extracted from black seed triggers apoptotic cell 
death in human colorectal cancer cells via a p53-dependent mechanism, Internatıonal 
Journal of Oncology, 25, 857-866 doi: 10.3892/ijo.25.4.857 
16. Guo, H.-F., Li, Z.-S., Dong, S.-W., Chen, W.-J., Deng, L., Wang, Y.-F., & Ying, D.-J. 
(2012) Piezoelectric PU/PVDF electrospun scaffolds for wound healing applications. 
Colloids and Surfaces B: Biointerfaces, 96, 29–36.doi:10.1016/j.colsurfb.2012.03.014 
17. Güzelsoy, P., Aydın, S., & Başaran, N. (2018) Çörek Otunun (Nigella Sativa L.) Aktif 
Bileşeni Timokinonun İnsan Sağlığı Üzerine Olası Etkileri, Journal of Literature Pharmacy 
Sciences, 7(2), 118-135. doi: 10.5336/pharmsci.2018-59816 
18. Hacker, C., Karahaliloglu, Z., Seide, G., Denkbas, E. B., & Gries, T. (2013) Functionally 
modified, melt-electrospun thermoplastic polyurethane mats for wound-dressing 
applications. Journal of Applied Polymer Science, 131(8), n/a–n/a. doi:10.1002/app.40132 
19. Hajhashemi, V., Ghannadi, A., & Jafarabadi, H. (2004) Black cumin seed essential oil, as a 
potent analgesic and antiinflammatory drug, Phytotherapy Research, 18(3), 195–199. 
doi:10.1002/ptr.1390 
20. Hsieh, Y. (2001) Surface Characteristics of Polyester Fibers: Surface Characteristics of 
Fibers and Textiles, Editors: Pastore, C. M., Kiekens, P., Markel Dekker Inc., p.33-57,USA  
21. Huang, Z.-M., Zhang, Y.-Z., Kotaki, M., & Ramakrishna, S. (2003) A review on polymer 
nanofibers by electrospinning and their applications in nanocomposites, Composites Science 
and Technology, 63(15), 2223–2253. doi:10.1016/s0266-3538(03)00178-7  
22. Kalhori, F., Arkan, E., Dabirian, F., Abdi, G., & Moradipour, P. (2018) Controlled 
Preparation and Characterization of Nigella Sativa Electrospun Pad for Controlled Release. 
Silicon. doi:10.1007/s12633-018-9931-z  
681 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
23. Li, Z., & Wang, C. (2013) One-Dimensional nanostructures: Electrospinning Technique and 
Unique Nanofibers, SpringerBriefs in Materials, 15-25. doi:10.1007/978-3-642-36427-3 
24. Liakos, I., Holban, A., Carzino, R., Lauciello, S., & Grumezescu, A. (2017)  Electrospun 
Fiber Pads of Cellulose Acetate and Essential Oils with Antimicrobial Activity. 
Nanomaterials, 7(4), 84. doi:10.3390/nano7040084 
25. Ma, Z., Kotaki, M., Yong, T., He, W., Ramakrishna, S. (2005) Surface Engineering of 
Electrospun Polyethylene Terephthalate (PET) Nanofibers Towards Development of a New 
Material for Blood Vessel Engineering, Biomaterials, 26, 2527-2536.  
doi:10.1016/j.biomaterials.2004.07.026  
26. Majdalawieh, A. F., Fayyad, M. W., & Nasrallah, G. K. (2017) Anti-cancer properties and 
mechanisms of action of thymoquinone, the major active ingredient of Nigella sativa, 
Critical Reviews in Food Science and Nutrition, 57(18), 3911–3928. 
doi:10.1080/10408398.2016.1277971 
27. Manikandan, A., Mani, M. P., Jaganathan, S. K., Rajasekar, R., & Jagannath, M. 
(2017) Formation of functional nanofibrous electrospun polyurethane and murivenna oil 
with improved haemocompatibility for wound healing. Polymer Testing, 61, 106–113. 
doi:10.1016/j.polymertesting.2017.05.008 
28. Mi, H.-Y., Jing, X., Jacques, B. R., Turng, L.-S., & Peng, X.-F. (2013)  Characterization 
and properties of electrospun thermoplastic polyurethane blend fibers: Effect of solution 
rheological properties on fiber formation, Journal of Materials Research, 28(17), 2339–235. 
doi:10.1557/jmr.2013.115  
29. Mi, H.-Y., Salick, M. R., Jing, X., Crone, W. C., Peng, X.-F., & Turng, L.-S. 
(2014) Electrospinning of unidirectionally and orthogonally aligned thermoplastic 
polyurethane nanofibers: Fiber orientation and cell migration. Journal of Biomedical 
Materials Research Part A, 103(2), 593–603. doi:10.1002/jbm.a.35208 
30. Nurrulhidayah, A.F., Che-Man, Y.B.,  Al-Kahtani, H.A., & Rohman, A. (2011) Application 
of FTIR spectroscopy coupled with chemometrics for authentication of Nigella sativa seed 
oil, Spectroscopy, 25, 243–250. doi: 10.3233/SPE-2011-0509 
31. Pant, H. R., Pokharel, P., Joshi, M. K., Adhikari, S., Kim, H. J., Park, C. H., & Kim, C. S. 
(2015) Processing and characterization of electrospun graphene oxide/polyurethane 
composite nanofibers for stent coating. Chemical Engineering Journal, 270, 336–342. 
doi:10.1016/j.cej.2015.01.105 
32. Rajendran, S. (2009) Advance textiles for wound care, CRC Press, Woodhead Publishing in 
Textiles, p:55, UK, ISBN: 1420094890,9781420094893             
33. Ramakrishna, S., Fujihara, K., Teo, W. E., Lim, T. C., Ma, Z. (2005) An Introduction to 
Electrospinning and Nanofibers, World Scientific Publishing Company, 90-101,USA, ISBN: 
981-256-415-2 
34. Randhawa, M., Alenazy, A., Alrowaili, M., & Basha, J. (2017) An active principle of 
Nigella sativa L, thymoquinone, showed significant antimicrobial activity against anaerobic 
bacteria, Journal of Intercultural Ethnopharmacology, 6(1), 97. 
doi:10.5455/jice.20161018021238  
35. Rieger, K. A., & Schiffman, J. D. (2014) Electrospinning an essential oil: Cinnamaldehyde 
enhances the antimicrobial efficacy of chitosan/poly(ethylene oxide) nanofibers. 
Carbohydrate Polymers, 113, 561–568.doi:10.1016/j.carbpol.2014.06.075 
682 
Uludağ University Journal of The Faculty of Engineering, Vol. 24, No. 2, 2019 
 
36. Saha, K., Butola, B. S., & Joshi, M. (2014) Drug release behavior of polyurethane/clay 
nanocomposite: Film vs. nanofibrous web. Journal of Applied Polymer Science, 
131(19). doi:10.1002/app.40824 
37. Sharmin, E., & Zafar, F. (2012)  Polyurethane: An Introduction. Polyurethane. 
Intechopen,  doi:10.5772/51663  
38. Tan, L., Hu, J., Huang, H., Han, J., & Hu, H. (2015) Study of multi-functional electrospun 
composite nanofibrous mats for smart wound healing. International Journal of Biological 
Macromolecules, 79, 469–476.doi:10.1016/j.ijbiomac.2015.05.014 
39. Tang, Q., & Gao, K. (2017) Structure analysis of polyether-based thermoplastic 
1 13
polyurethane elastomers by FTIR, H NMR and C NMR,  International Journal of 
Polymer Analysis and Characterization, 22(7), 569–574. 
doi:10.1080/1023666x.2017.1312754  
40. Teo, W. E., & Ramakrishna, S. (2006) A review on electrospinning design and nanofibre 
assemblies. Nanotechnology, 17(14), 89–106. doi:10.1088/0957-4484/17/14/r01 
41. Theron, S. A., Zussman, E., & Yarin, A. L. (2004) Experimental investigation of the 
governing parameters in the electrospinning of polymer solutions, Polymer, 45(6), 2017–
2030. doi:10.1016/j.polymer.2004.01.024 
42. Theron, J. P., Knoetze, J. H., Sanderson, R. D., Hunter, R., Mequanint, K., Franz, T., & 
Bezuidenhout, D. (2010)  Modification, crosslinking and reactive electrospinning of a 
thermoplastic medical polyurethane for vascular graft applications. Acta Biomaterialia, 
6(7), 2434–2447. doi:10.1016/j.actbio.2010.01.013 
43. Tijing, L., Ruelo, M., Amarjargal, A., Pant, H., Park, C., Kim, D., Kim C. (2012) 
Antibacterial and superhydrophilic electrospun polyurethane nanocomposite fibers 
containing tourmaline nanoparticles, Chemical Engineering Journal, 197, 41–48. doi: 
10.1016/j.cej.2012.05.005 
44. Yang, H., Irudayaraj, J., & Paradkar, M. M. (2005) Discriminant analysis of edible oils and 
fats by FTIR, FT-NIR and FT-Raman spectroscopy, Food Chem,93(1), 25-32. 
doi:10.1016/j.foodchem.2004.08.039  
45. Yeganeh Mazaheri, Mohammadali Torbati, Sodeif Azadmard-Damirchi & Geoffrey P. 
Savage (2019) A comprehensive review of the physicochemical, quality and nutritional 
properties of Nigella sativa oil, Food Reviews International, 35(4) 342–362. 
doi:10.1080/87559129.2018.1563793 
46. Yuan, Y., & Lee, T. R. (2013) Contact Angle and Wetting Properties, Springer Series in 
Surface Sciences, 3–34. doi:10.1007/978-3-642-34243-1_1  
47. Wang, Y., Hao, J., Huang, Z., Zheng, G., Dai, K., Liu, C., & Shen, C. (2018) Flexible 
electrically resistive-type strain sensors based on reduced graphene oxide-decorated 
electrospun polymer fibrous mats for human motion monitoring. Carbon, 126, 360–371. 
doi:10.1016/j.carbon.2017.10.034 
48. Wen, P., Zhu, D.-H., Wu, H., Zong, M.-H., Jing, Y.-R., & Han, S.-Y. (2016). Encapsulation 
of cinnamon essential oil in electrospun nanofibrous film for active food packaging. Food 
Control, 59, 366–376. doi:10.1016/j.foodcont.2015.06.005 
49. Zaoui, A., Cherrah, Y., Mahassini, N., Alaoui, K., Amarouch, H., & Hassar, M. 
(2002) Acute and chronic toxicity of Nigella sativa fixed oil, Phytomedicine, 9(1), 69–
74.  doi:10.1078/0944-7113-00084  
683 
Aras C., Düzyer Gebizli Ş., Tümay Özer E., Karaca E.: Invest. The Effect of Some Process Paramt. 
50. Zhu, G., Kremenakova, D., Wang, Y., Militky, J. (2015) Air Permeability of Polyester 
Nonwoven Fabrics, AUTEX Research Journal, 15(1), 8-12. 11. doi: 10.2478/aut-2014-0019  
 
 
 
 
 
 
 
684