As indicated in Table 3, the fatty

As indicated in Table 3, the fatty acid profiles of RHSO
obtained by Soxhlet extraction withn–hexane and scCO2 extraction
with entrainer or without contained palmitic (2.3–2.5%), stearic
(1.9–2.5%), oleic (20.5–20.7%), linoleic (47.0–48.5%), linolenic
(19.9–21.9%) and arachidonic acid (1.0–1.1%) for waste oilseeds,
and also palmitic (3.7–3.8%), stearic (2.1–2.4%), oleic (19.9–20.5%),
linoleic (48.5–49.2%), linolenic (20.5–22.0%) and arachidonic acid
(0.8%) for original oilseeds. Also according to Table 3, by analyzing
the composition of unsaturated fatty acids from the samples,
it was possible to verify that the fatty acid profile is consistent for
RHSO and in accordance with some researchers [24,26,27,30,31]
with the major components oleic, linoleic and linolenic acids being
approximately 80% of the extracted RHSO. The percentage distribution
of the fatty acid components determined for the waste and
original oilseeds in this work had some similarities and differences
from those of other studies. The reason was explained by Yılmaz
et al. [40] as these similarities and differences could be attributed
to difference climate, soil, ecological conditions and also genetic
factor by different researchers. For example, del Vella et al. [24]
reported that linoleic acid (43.9%) was the most abound followed
by linolenic acid (35.1%) and oleic acid (14.2%) of fatty acid composition
which was obtained with the scCO2 extraction (40 ◦C, 30 MPa,
21 g CO2/min) of RHSO in the seeds of Rosa aff. rubiginosa. However,
Eggers et al. [27] reported for the similar plant origin that linolenic
acid (40.8%) was the most abound followed by linoleic acid (37.5%)
and oleic acid (9.2%) of fatty acid composition which was obtained
with the scCO2 extraction at 30 MPa, 60 ◦C, 6 kg CO2/h. The findings
of these two researchers are very different from each other. The
experimental findings of Machmudah et al. [31] are in agreement
with Illes et al. [26]. Both researchers are reported that linoleic acid
was the most abound (52–55%) followed by linolenic acid which
accounted for 23–24% of total fatty acid profiles. A comprehensive
study concerning the effects of temperature (40–80 ◦C), pressure
(15–45 MPa) and CO2 flow rate (2–4 mL/min) on fatty acids percentage
of total fatty acid species in the extracted was investigated
by Machumudah et al. [31]. The rosehip seeds separated from the
dried fruit was used as an oilseed material. They reported that the
fatty acids composition was influenced by the extraction conditions.
The aforesaid studies emphasized thatthere areno significant
changes in fatty acid profiles of the obtained oils from rosehip
seeds by Soxhlet, cold press and scCO2 extraction methods. However,
Illes et al. [26] reported that scCO2 extraction is more than
efficient in extracting such precious micronutrients when compared
to Soxhlet extraction with n–hexane. Szentmihalyi et al. [30]
showed that the biologically active substances of rosehip seeds can
be extracted in favorable yields by supercritical CO2 and propane,
and also scCO2 extraction results in an oil less rich carotene as
compared to Soxhlet, microwave and ultrasound extractions with
n–hexane. The effect of entrainer contribution in the scCO2 extraction of RHSO has not been carried out so far. Ethanol may enhance
the extraction of polar compounds in original or waste oilseeds
of the rosehip because of their lower solubility in scCO2. Temelli
[41] emphasized that an important aspect in oil extraction is the
use of entrainers to increase solvent loading and to recover polar
components as CO2 is selective for non–polar compounds. Because
specialty oils as RHSO are receiving growing interest due to their
high concentrations of bioactive components which have various
health benefits. Therefore, ethanol addition would be advantageous
in an extraction process if the selectivity can be improved due to
specific intermolecular interactions between the co–solvent and
specific components of a mixture [42,43]. In this study, the percentage
of linoleic acid in the extracted oils from the original and
waste oilseeds did not change significantly with the contribution
of 5%vol. ethanol into scCO2 at the conditions of 40 ◦C, 30 MPa and
0.045 L/h. The percentage of oleic acid increased when using 5%vol.
ethanol, but the percentage of linolenic acid decreased. These tendencies
for both original and waste oilseeds are similar. As shown
in Table 3, the extraction with supercritical fluids of RHSO in both
original and waste oilseeds resulted infavorable fatty acid compositions.
Linoleic acid content in RHSO obtained by Soxhlet extraction
is higher than the supercritical fluids. In contrast, oleic and linolenic
is lower than