Spectroscopic examination and release of microencapsulated oregano essential oil


doi: 10.5599/admet.5.4.426 224 

ADMET & DMPK 5(4) (2017) 224-233; doi: http://dx.doi.org/10.5599/admet.5.4.426 

 
Open Access : ISSN : 1848-7718  

http://www.pub.iapchem.org/ojs/index.php/admet/index   

Original scientific paper  

Spectroscopic examination and release of microencapsulated 
oregano essential oil 

Ioannis Partheniadis
1
, Panagiota Karakasidou

1
, Souzan Vergkizi

2
, Ioannis 

Nikolakakis
1
* 

1 
Department of Pharmaceutical Technology, School of Pharmacy, Faculty of Health Sciences, Aristotle University of 
Thessaloniki, Thessaloniki, 54124, Greece 

2
 Department of Microbiology, School of Medicine, Faculty of Health Sciences, Aristotle University of Thessaloniki, 
Thessaloniki, 54124, Greece  

*Corresponding Author:  E-mail: yannikos@pharm.auth.gr; Tel.: +302310997635; Fax: +302310997652 

Received: August 29, 2017; Revised: September 28, 2017; Published: December 24, 2017  

 

Abstract 

Oregano essential oil (EO) of Greek origin with high carvacrol content (86.84 %) was encapsulated by spray 
drying using Arabic gum, modified starch and maltodextrin (75:12.5:12.5) as wall materials. The spray-dried 
product (EOSD) consisted of roundish particles with narrow size distribution. FT-IR and Raman spectroscopy 
identified the EO in EOSD, with Raman spectra showing more distinct peaks and a small shift of the peak at 
1260 cm

-1
 (assigned to the stretching vibration of the bond of C-O of the phenol), implying only minor chemical 

interaction with the wall materials. Release of the EO from EOSD was described by the Hixson-Crowell equation 
(R

2
=0.986) with apparent diffusion coefficient 8.3x10

-10 
m

2
/s. These findings indicate that microencapsulation by 

spray drying did not affect the quality of the oregano EO and provided relatively fast and complete release.  

Keywords 

oregano essential oil; microencapsulation; spray drying; FT-IR; Raman spectroscopy; in vitro release 

 

Introduction 

Essential oils are complex mixtures of natural, aromatic and volatile compounds synthesized by 

aromatic plants. Selected oils have been shown to act on microbial cell surface causing disruption of the 

cell wall and the cytoplasmic membrane leading to lysis and leakage of intracellular compounds [1]. 

Because of the increasing problem of bacterial resistance to several antibiotics and their accepted safety 

profile, essential oils may be interesting candidates against microbial infections [2].  

Oregano essential oil (EO) has been receiving attention because of its antimicrobial activity against both 

Gram negative and Gram positive bacteria and to its colicidal and colistatic properties due to the presence 

of carvacrol and thymol in its composition
 
[3-5]. Since oregano EO contains volatile and easily oxidized 

active ingredients protection from environmental factors is important for retaining its activity in the 

marketed product. This problem may be tackled by spray drying, which is an industrially established 

continuous process that in combination with emulsification offers a method for EO microencapsulation [6-

9]. For this purpose, an EO in water emulsion is initially prepared and the EO droplets are stabilized by a 

http://www.pub.iapchem.org/ojs/index.php/admet/index
mailto:yannikos@pharm.auth.gr


ADMET & DMPK 5(4) (2017) 224-233 The release of microencapsulated oregano essential oil 

doi: 10.5599/admet.5.4.426 225 

mixture of gums and carbohydrates [10-11]. The emulsion is then spray-dried under appropriate conditions 

of temperature and feed rate, and a powder product consisting of single or agglomerated particles is 

obtained where the EO is encapsulated and thus protected from humidity and light that normally lead to 

oxidation of alcohols, reduced antimicrobial activity and even inactivation [6, 12-14]. Moreover, 

microencapsulation is expected to increase the solubility of the EO by facilitating wetting of the wall 

materials and re-emulsification of sprayed dried product (EOSD), a process that possibly occurs when in 

contact with gastric fluids [15]. 

The aim of this work was to prepare a spray-dried encapsulated product of oregano EO of Greek origin 

that had high carvacrol content, using a composition of Arabic gum/starch/maltodextrin [7] as wall 

materials. In particular, the purpose was to identify the presence of EO in the product and possible 

interactions of the EO with the wall materials using Fourier transform infrared (FTIR) and Raman 

spectroscopy and to elucidate the mechanism of in vitro release of the EO in aqueous medium by dialysis 

dissolution method. The essential oil of oregano was used instead of a methanol extract since it has been 

reported that the former has stronger and broader spectrum of antimicrobial activity [16]. Arabic gum was 

used as the major of the three encapsulating materials because it forms a low viscosity colloidal dispersion 

suitable for spray drying, stabilizes EO emulsions in water across a wide pH range as encountered in the 

gastrointestinal tract, has good retention of volatile compounds and is compatible with other encapsulants 

[12, 17]. Modified starch was used since besides protection from oxidation and loss of volatiles, it also has 

emulsification ability. Maltodextrin with high dextrose equivalent (DE 20-23) was added to protect from 

oxidation and also to facilitate spray drying and improve product wettability [7, 12, 18]. 

Experimental  

Materials 

Oregano essential oil (EO), obtained from Oreganum vulgare (Heracleoticum) was a gift from Ecopharm 

Hellas, Kilkis, Greece Batch 0614 and had in its composition: 86.84 % carvacrol, 2.82 % thymol, 0.96 % γ-

Terpinene, 3.46 % p-Cymene, 1.82 % β-Caryophyllene and 4.11 % other terpenes and phenols 

(Manufacturer’s data). The encapsulating materials: Arabic gum (AG, Spraygum AB) was purchased from 

Nexira, France. Maltodextrin (MD, Glucidex 21) and modified starch (MS, Clearam CH20 20, food grade 

acetylate di-starch adipate (E1422), waxy maize basis) were from Roquette Italia, both gifts from Interallis 

Chemicals, Sindos, Greece. 

Preparation of encapsulated oregano EO 

A 30 % w/w concentration of dispersed phase of sprayed emulsion used for encapsulation was selected 

after preliminary trials since its viscosity allowed feeding and passing through the nozzle of the spray drier 

with minimal losses to the walls of the drying chamber at the applied conditions. The emulsion consisted of 

3 % w/w oregano EO as the internal dispersed phase, 27 % w/w encapsulating materials (AG 75 %, MS 12.5 

%, MD 12.5 %) and 70 % deionised water as the external phase [7]. For the preparation of the emulsion, AG 

and MD were hydrated overnight in deionised water at 4-5 °C and then heated to 82 °C. MS was added to 

this and the mixture homogenized at 15000 rpm for 20 min using an Ultra Turrax (IKA, Germany). The 

mixture was cooled to about 5 °C and oregano EO was added, followed by further homogenization for 5 

min. The prepared emulsion was spray-dried using a mini spray dryer (B-191, Büchi, Switzerland) operated 

under the following conditions: feed rate 5 mL min
-1

, inlet air temperature 180 °C, outlet temperature 117 

°C, aspiration rate 100 % and airflow 600 mL/min. The nominal content of oregano EO in the final spray-



I. Nikolakakis et al.  ADMET & DMPK 5(4) (2017) 224-233 

226  

dried product was 10 %. Three replicate batches were prepared and used for the determination of 

physicochemical properties and drug release. A spray-dried product without EO was also prepared for 

comparison purposes. 

Particle size and moisture content 

The spray-dried product consisted of reasonably well formed particles with a narrow normal size 

distribution and particle diameters in the range D10=3.9 μm to D90=16.9 with mean value 8.1 μm as 

previously reported [19]. The moisture content was measured by heating at 105 °C to constant weight and 

was found to be 3.4±0.2 expressed as % of weight loss on a dry basis (Table 1). 

Table 1. Technological properties of spray-dried oregano EO product (mean ± 
standard error, n=3) 

Property Value 

Refractive Index of unprocessed EO 1.51387±5.2x10
-5

 

Refractive indexof EO after spray drying 1.51566±8.5x10
-5

 

Particle size (μm)  

D10 4.7 

D50 11.0 

D90 26.0 

Moisture content (%) 3.4 ± 0.2 

Refractive index 

The refractive index of the unprocessed EO and after its extraction from EOSD was measured using a 

refractometer (Bellingham and Stanley, Kent, England), illuminated with a sodium D1 (yellow) lamp at 

589.6 nm and 20 °C. The units read on the scale of the instrument were converted to refractive index from 

the manufacturer’s conversion table. 

FT-IR and Raman spectroscopy 

FT-IR Spectra were obtained using a Shimadzu FT-IR-Prestige-21 spectrometer (Shimadzu Corporation) 

attached to a horizontal Golden Gate MKII single-reflection ATR system (Specac, Kent, UK) equipped with a 

Diamond/ZnSe crystal (45° angle to infrared beam, 1.66 μm at 1000 cm
-1

 depth of penetration, 2.4 

refractive index and 525 cm
-1

 long wavelength cut-off). A few drops of oregano EO or a small amount of the 

EOSD powder product were placed on the diamond disk and 64 scans were collected over the range of 

4000–400 cm
-1

 at resolution 4 cm
-1

 using appropriate software (Shimadzu IRsolution 1.3). For the spray-

dried powder product a sapphire anvil was used to restrain the powder in the path of the beam.  

Raman spectra of samples placed in standard vials were recorded using a bench top Raman 

spectrophotomer (Agility, dual band 785/1064 nm model, BaySpec, CA, USA) and supporting software 

(Agile 20/20). The laser excitation line was 1064 nm selected due to strong fluorescence of the sample at 

lower wavelengths, the resolution 12 cm
−1

, the exposure time 2 s, the power of incident laser beam 

350 mW and the recorded spectra were the average of 100 runs. 

In vitro release of oregano EO  

A dialysis method was used to test the release of encapsulated EO from EOSD. 100-mg sample 

corresponding to 10 mg nominal EO but in fact to about 7-8 mg due to losses during spray drying [7], was 



ADMET & DMPK 5(4) (2017) 224-233 The release of microencapsulated oregano essential oil 

doi: 10.5599/admet.5.4.426 227 

Wavelength  / nm 

placed in a dialysis cellulose tubing (molecular weight cut-off 12500, Sigma-Aldrich), closed at the two ends 

and immersed in 200 mL phosphate buffer (PBS, pH 6.8, 37 °C), under magnetic stirring. Since the cut-off 

MW was greater than that previously used for similar systems [20, 21], no interference of the membrane 

pores was expected in the measured values of EO. For the construction of the standard reference curve, 

the absorption peaks of the oregano EO were first determined from spectra of oregano EO obtained using 

a UV-VIS spectrophotometer (Pharma Spec UV-1700 Shimandzu, Japan). A major peak appeared at 

wavelength 273 nm (Figure 1) and was used for the determination of released EO. In fact, this was very 

close to the peak obtained from the pure carvacrol (Sigma-Aldrich) (Figure 1) indicating its predominance in 

the composition of EO (86.84 % according to the manufacturer’s data). The reference curve of EO in PBS 

was then constructed using standard solutions of unprocessed oregano EO prepared by diluting stock EO 

solutions in methanol with phosphate buffer (PBS) pH 6.8, to give final concentrations in the range 0.01125 

– 0.1125 mg/mL. The standard reference curve was C = (Abs - 0.0192) / 11.525), where C is in mg mL
-1

 and 

was used for the determination of EO in the aliquots taken at timely intervals from the dissolution 

medium. 

 

 

Figure 1. UV-VIS spectra of unprocessed oregano EO (black line) and carvacrol (red line) 

Results  

The values of the refractive indices of the unprocessed and extracted EO are shown on Table 1. It can be 

seen that they were only slightly different indicating that the oregano EO essentially retained its 

composition after spray drying. 

Particle size, shape and moisture content 

Particle size distribution data of the spray-dried product (EOSD) are presented in Table 1 as diameters 

D10, D50 and D90 corresponding to 10 %, 50 % and 90 % of the distribution. It can be seen that the 

particles formed a narrow and normal size distribution of low span [(D90-D10)/D50]=2.0, with mean 

diameter 11.0 μm. The narrow particle size distribution of EOSD as well as the 3.4 % moisture content 

(Table 1) is within the expected ranges for spray-dried products prepared using equipment of similar 

A
b

so
rb

a
n

ce
 



I. Nikolakakis et al.  ADMET & DMPK 5(4) (2017) 224-233 

228  

capacity and operating conditions [11]. 

FT-IR and Raman spectroscopy 

FT-IR spectra of carvacrol, oregano EO and of the spray-dried product without EO or with EO (EOSD) are 

presented in Figure 2. Carvacrol and oregano EO spectra looked the same even in the fingerprint region 

1600-600 cm
-1

, confirming that the consistency did not change after spray drying, and the carvacrol 

content remained very high. Several of the characteristic EO peaks present in the carvacrol and the 

oregano EO spectra (Figure 2a-b) also appeared in the EOSD spectrum (Figure 2c) at the same wavelengths: 

2960 cm
-1

, 1420 cm
-1

 and at 1249 cm
-1

 (indicated by vertical dotted lines), although at much lower 

intensities because of the relatively low EO content (10 %) in the product. These peaks, however, were 

absent from the spectrum of the spray-dried product without EO (Figure 2d), confirming that these were 

specific to oregano EO. 

Similarly, from the Raman spectra shown in Figure 3 it can be seen that the peaks were almost identical 

for carvacrol and oregano EO reflecting the high carvacrol content in the EO. Several characteristic peaks 

present in the carvacrol and the oregano EO spectra (Figure 3a-b) also appeared distinctly in EOSD (Figure 

3c) at the same wavelengths (marked by vertical dotted lines): 1621 cm
-1

, 760 cm
-1

 and 570 cm
-1

 [22]. An 

additional peak at 1260 cm
-1

 in the carvacrol and EO spectra, appears to be shifted to the left at 1285 cm
-1

 

(higher wavelength) in the spectrum of the EOSD, implying possible interaction of the EO with the wall 

materials. The above peaks were absent from the spectrum of the spray-dried product with wall materials 

alone (without EO). 

In vitro release of oregano EO  

The dialysis membrane method was used for testing the release of encapsulated EO from EOSD in order 

to avoid passage of colloidal particles of the high molecular weight (MW) polysaccharides into the 

dissolution medium and subsequent interference with UV absorption of EO. The release vs time profile of 

EO from the EO encapsulated spray-dried product (EOSD) is shown in Figure 4. As it can be seen, plateau is 

reached after about 60 min corresponding to release of about 7-8 mg, as expected due to loss during 

spray-drying [7]. The data were analyzed using different kinetic models. EO release should involve diffusion 

from the interior of the particles to the surface and additionally, relaxation and swelling of the hydrophilic 

wall materials due to hydration. Therefore, the simple power equation of Peppas and Ritger [23] for 

swelling-controlled release systems was initially tried but poor fitting of the data was found implying that a 

more complex release mechanism operates which, besides diffusion and swelling also involves progressive 

dissolution of the wall material.  

For this reason the cube-root law [24-25], equation (1) was applied: 

1/3 1/3
Mo Mt kt   (1) 

Mt is the weight of unreleased EO at time t and Mo the initial weight of EO in the sample.  

This is based on the assumptions that a) the dissolving particles are spherical and of narrow size 

distribution b) sink conditions prevail and c) there is no influence of stagnant layers forming in the 

neighborhood of the particles. These assumptions were obeyed in this study as demonstrated by the low 

content of EO in the dissolution fluid (about 7-8 mg in 200 mL) compared to the solubility of carvacrol 

(1.250 mg mL
-1

) and, by providing sufficient agitation. 

 



ADMET & DMPK 5(4) (2017) 224-233 The release of microencapsulated oregano essential oil 

doi: 10.5599/admet.5.4.426 229 

 
Figure 2. FT-IR spectra of (a) carvacrol, (b) oregano EO, (c) encapsulated EO spray-dried product and (d) spray-

dried product without EO. Vertical dotted lines show presence of EO peaks in the EOSD product. 

 

 

Figure 3. Raman spectra of (a) carvacrol, (b) oregano EO, (c) encapsulated EO spray-dried product and (d) spray-
dried product without EO. Vertical dotted lines show presence of oregano EO peaks in the EOSD product. 

The results were plotted according to equation (1) in Figure 5 where it can be seen that the points fall 

on a straight (R
2
=0.986) with slope line k=0.0213 (mg

1/3
 / min) representing the rate constant of the Hixson-

Crowell equation known as ‘cube-root law’ [24], expressed by equation:  

1/3
  (4 / 3 )  ( / )    

app
k N D Cs h  (2) 

ρ=0.95 g/cm
3
 is the density of oregano EO, Cs its solubility in water (taken as that of carvacrol 1.250 

(d) 

(a) 

(c) 

(b) 

2960 1420 1249 

Wavenumber, cm
-1

 

T
ra

n
sm

it
ta

n
ce

 

Raman shift, cm
-1

 

R
a

m
a

n
 i

n
te

n
si

ty
 



I. Nikolakakis et al.  ADMET & DMPK 5(4) (2017) 224-233 

230  

mg/ml), h the thickness of diffusion layer (taken as the mean particle radius 5.5 μm, Table 1, assuming 

uniform EO distribution in the particles) and N=1.387x10
4
 the number of EO releasing particles in the 

100 mg sample, calculated from the mean particle diameter and its density (1.34 g/cm
3
, equal to the 

weighted average of the components). Dapp is an ‘apparent’ diffusion coefficient representing the 

composite release mechanism involving diffusion, swelling and particle dissolution. By substituting the 

values of the above parameters into equation (2), Dapp=8.3x10
-10

 m
2 

/s. Although the estimation of diffusion 

may be affected due to the passage of EO through the pores of the dialysis membrane, this effect is not 

expected to be significant due to the low MW of the ingredients of EO (i.e. Carvacrol 155.22, p-Cymene 

139.21, γ-Terpinene 136.23 and Thymol 150.22). Besides, previous estimations of the diffusion coefficients 

[20, 21] were also obtained using the dialysis method and therefore comparisons of the present with the 

previous data can be made. 

 

Figure 4. Release-time profile of oregano EO from the spray–dried powder product (error bars show standard 
deviation, n=3) 

 

Figure 5. Release data of oregano EO from the spray-dried powder product plotted according to the Hixson-
Crowell ‘cube-root law’ equation. 

Discussion 

Antimicrobial resistance is an emerging health problem which is enlarged by the shortage of new 

antibiotic agents. At the same time, interest in antimicrobials obtained from natural sources has increased 



ADMET & DMPK 5(4) (2017) 224-233 The release of microencapsulated oregano essential oil 

doi: 10.5599/admet.5.4.426 231 

due to their accepted safe status [1-2, 3-4]. Essential oils derived from aromatic plants and, oregano EO in 

particular fall into a group of antimicrobials that has attracted major attention as shown by the numerous 

reports in the literature [26-27]. However, since pure oregano EO is highly irritating to taste and cannot be 

easily consumed as such, its microencapsulation into a spray-dried product offers a convenient way for oral 

administration besides providing protection from environmental factors as well.    

The peaks that are common in the FT-IR spectra of carvacrol, oregano EO and EOSD (Figure 2) are 

ascribed at: 2960 cm
-1

 to antisymmetrical -CH3 stretching vibration, 1420 cm
-1

 to antisymmetric -CH3 

bending and 1249 cm
-1

 to C-O-C stretching. Since these peaks are absent from the spectrum of the spray-

dried product without EO they could be potentially used (especially the more distinct at 1420 cm
-1 

and 

1249 cm
-1

), for identification purposes. Raman spectroscopy is complementary to FT-IR and was used to 

add more information about the state of the EO in the product. The peak at 760 cm
-1

 in the EOSD 

corresponds exactly to the position in the carvacrol spectrum, with no shifting towards lower 

wavenumbers that might be caused by the presence of thymol confirming carvacrol as the main 

constituent and that substances present at low percentages do not influence the EO spectrum [25]. 

The distinct peaks that are common in the Raman spectra of carvacrol, unprocessed oregano EO and EO 

in the EOSD (Figure 3) are ascribed at: 1621 cm
-1

 to conjugated C=C stretching vibration, 760 cm
-1

 to 

breathing vibration mode and 570 cm
-1 

to aromatic ring vibration. Since they are absent from the spectrum 

of the spray-dried product without EO, they can be used for identification of EO [22]. The shifting of the 

peak at 1260 cm
-1

, which is assigned to the stretching vibration of the C-O bond of the phenol, to the left at 

1285 cm
-1

 implies interaction of the EO and the wall material, probably between the aromatic –OH of 

carvacrol and the hydroxyl groups of maltodextrin, resulting in lower vibration frequency and shifting of 

the peak to higher wavelength. From the above discussion it appears that Raman spectroscopy provides 

more information on the state of EO in the product by revealing more distinct peaks of EO in the product 

and possible interactions, thus offering a better alternative for identification and the state of EO in the 

EOSD than FTIR. 

Contrary to previous works [20, 21]
 
the results in the present study could not be described by Fick’s 

diffusion models due to progressive dissolution of the wall material resulting in change of available particle 

surface. For this reason the release model cube-root law of Hixson-Crowell [24] was applied which is 

derived on the basis of surface change, expressed in equation (1) as mass change with time. The good 

fitting of the data to this model (R
2
=0.986) indicates distribution of EO in the wet jelly matrix of spray-dried 

particles during release, so that mass change at different times corresponds to release of proportional 

amounts of EO. The rather high value of the apparent diffusion coefficient Dapp = 8.3x10
-10

 m
2
/s in equation 

(2) compared to the values of about 10
-13

 to 10
-16

 in previous works [20-21], is attributed to the different 

wall materials used and different types of diffusion mechanisms. Also, in their studies [20], interactions 

between EO and the wall material were reported whereas only minor interactions were seen in the 

present work.  

Conclusions 

Microencapsulated oregano EO by spray drying using Arabic gum, starch and maltodextrin as wall 

materials has been previously reported by da Costa et. al [7] to offer good retention and encapsulation 

efficiency. It was therefore considered worthwhile investigating the state of microencapsulated EO and its 

release profile from the spray-dried product (EOSD). FT-IR and Raman spectroscopy clearly identified the 

presence of EO in the EOSD, with a small shift of the peak at 1260 cm
-1

 in the Raman spectrum to 1285 cm
-1

, 



I. Nikolakakis et al.  ADMET & DMPK 5(4) (2017) 224-233 

232  

implying only minor chemical interaction with the wall materials. Release of the EO from EOSD was 

completed within 1 – 1.5 h and was well described by the Hixson-Crowell equation (R
2
=0.986) with 

apparent diffusion coefficient 8.3x10
-10 

m
2
/sec. The above findings encourage formulation of oregano EO 

into spray-dried product for oral administration for therapeutic purposes. 

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