Modern Extraction and Isolation Methods
Faculty of Pharmacy MU
Department of Natural Drugs
prof. PharmDr. Karel Šmejkal, Ph.D.
Introduction to Extraction and
Isolation
Ústav přírodních léčiv2
Why to extract?
̶ Content of active compounds in drug low
̶ Content of active compounds variable
̶ Presence of unwanted compounds
̶ Drug not acceptable because of bed organoleptic properties
̶ The amount for direct preparation of application
form/administration too big
̶ Better possibility of dosage
̶ Better compliance of patient
Ústav přírodních léčiv3
Content compounds
̶ Main active compounds
̶ Supporting content compounds
̶ Ballast compounds
̶ The aim of extraction:
̶ Remove ballast substances, to maintain main and supporting content
compounds, the obtain extract rich in target substance
Ústav přírodních léčiv4
Drug
Fresh plant or
its part
Medicinal
wines
Pressed
juices
Oil
concentrates
Cold
macerations
Water
extracts
Infusions
Decoctions
Instant
products
External
preparations
(ointments,
balms,
compresses)
Herbal
(medicinal)
teas
Essential
oils
Cosmetic preparations
Aromatic
alcohols
Pulverized
drug
Tinctures
Extracts
Liquid
Thick
Dry
Lipophilic extracts
EtOHWater
Traditional processing of medicinal plants, their parts and drugs
Ústav přírodních léčiv5
Methods of standardization
Analytical techniques for determination of markers
and standardization
Determination of class of compounds
Total phenolics, total flavonoids, total alkaloids…
Amount of volatile substances (essential oil quantification)
Common utilization of color reactions
Fast, simple, cheap
Possible false-positive results, possible falsification
Single compounds as markers
• HPLC-DAD, HPLC-MS, GC-MS
• Quantification of one or more
compounds
• Precise, more expensive, low
chance of falsifying
Requirements for marker:
1) Bioactivity
2) Sufficient content
3) Physico-chemical stability
Combination of analytical technique
and biological activity
Ústav přírodních léčiv6
Extraction - Fick diffusion law
Δn/ Δ t = - (DA/h) × (c0 - c)
̶ Δn/Δt – velocity of diffusion
̶ D – diffusion coefficient based on temperature and diameter
of diffunding particles
̶ A – diffusion space (surface)
̶ h – diffusion layer
̶ (c0-c) – concentration gradient
Ústav přírodních léčiv7
Improved effectiveness of extraction
̶ Maceration (one batch method – periodic)
̶ Decantation, centrifugation, filtration
Improved methods
(semicontinual)
– Percolation
– Digestion
– Variations on
Soxhlet extractor
Matrix effects
Desintegration of material
Meating
Stirring
Repetition of process
Solvent selection
Sonication
Ústav přírodních léčiv8
MUNI Biopharma Hub9
Solid-liquid extraction techniques
̶ Conventional extraction techniques
̶ maceration, percolation, squeezing, counter-current extraction, extraction through Soxhlet,
distillation, etc.
̶ high quantities of expensive and pure solvents, a low selectivity of extraction; a high
solvent evaporation rate during the process; long extraction times, thermal decomposition
of thermolabile compounds
̶ Unconventional (innovative) extraction techniques
̶ ultrasound-assisted extraction (UAE), supercritical fluid extraction (SFE), microwaveassisted
extraction (MAE), extraction with accelerated solvent, solid phase microextraction,
enzyme-assisted extraction, and rapid solid-liquid extraction dynamic (RSLDE) via the
Naviglio extractor
Ústav přírodních léčiv10
Water steam destillation
Ústav přírodních léčiv11
Ústav přírodních léčiv12
Dalton´s law
Steam distillation
Suitable for water-insoluble substances, only volatile compounds
Selective
Simple
Cheap
Ústav přírodních léčiv13
Ústav přírodních léčiv14
Products of steam distillation
̶ Essential oils
̶ Eucalyptus, tea-tree oil, camphora
̶ Hydrolates
̶ Rose water
̶ Orange blossom water
̶ Aromatic spirits
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Equipment
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Equipment
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Supercritical fluid extraction
̶ Extraction with utilization of supercritical fluids
̶ Supercritical fluid
Pressure and temperature over critical values
Physical properties form a transition between the properties of
gases and liquids
Density close to liquids good dissolving ability
Diffusion constant close to gases rapid mass transfer
Viscosity lower than liquid advantage of better flow
properties
Low surface tension easy material penetration
Ústav přírodních léčiv18
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Supercritical fluid extraction
Ústav přírodních léčiv20
Advantages of SFE:
Gentle technique.
Ideally, no organic solvents are needed.
Ecologically harmless.
Cheap.
Fast.
Possibility of automation.
Changes of solvation strength by changes
of pressure.
Disadvantages of SFE:
Less suitable for polar compounds.
More demanding instrumentation.
Requires the use of high pressures.
Less suitable for leaf extraction.
Extraction tuning issues.
Difficult extraction of fresh material
(water content).
CO2 – non-flammable, non-explosive, easily available, cheap,
environmentally friendly, advantageous supercritical region (T=31.1
°C; P=7.28 MPa), suitable for the extraction of low polar substances
(essential oils, oils, waxes, carotenoids)
̶ Utilization:
Hop extraction. Decaffeination of coffee. Extraction of taxol from
Taxus brevifolia. Extraction of essential oils and spices. Nonpharmaceutical
purposesÚstav přírodních léčiv21
SFE
Ústav přírodních léčiv22
Ústav přírodních léčiv23
Accelerated solvent extraction (ASE)
̶ Increased extraction yields and reduced time
̶ An increased diffusion
̶ Liquids operating above their boiling temperature while being
maintained in a liquid state by the increase in pressure
̶ A cylindrical steel container, the extracting solvent is introduced
̶ The temperature of the system is raised above the boiling point of
the solvent, which is maintained in the liquid state thanks to a
simultaneous increase in pressure (the vial is sealed to resist high
pressure values: 100–200 bar)
̶ Not suitable for thermally labile substances
Ústav přírodních léčiv24
Accelerated solvent extraction (ASE)
https://www.thermofisher.com/cz/en/home/industrial/chromatography/chromatography
-sample-preparation/automated-sample-preparation/accelerated-solvent-extraction-
ase.html
https://www.thermofisher.com/order/catalog/product/083114
Ústav přírodních léčiv25
Ultrasound assisted extraction
doi: 10.3390/ijerph18179153
̶ An innovative technique, used in different
settings
̶ “Clean technology”
̶ Use of low solvent volumes
̶ Short Ets
̶ Few instrumental requirements
̶ Low economic and environmental impact
̶ Technique employs ultrasonic waves
frequencies between 20 kHz and 10 MHz
̶ power ultrasound (20–100 kHz),
characterized by a high intensity, used for
extraction and processing applications
̶ signal or diagnostic ultrasound (100 kHz–
10 MHz), employed as a clinical
diagnostic technique, and for control and
quality assessment
̶ Acoustic cavitation (AC)
Ústav přírodních léčiv26
̶ UAE-Associated Mechanisms
• Fragmentation → the reduction of matrix particle size guided by the ultrasonic action → increases
the solid surface area to develop mass transfer, driving to better extraction yields
• Erosion → the release of solid structures from the matrix into the extractive solvent, caused by the
collapse of cavitation bubbles
• Sonocapillary → an enhanced penetration of solvent into the canals and pores of the matrix
• Detexturation → the solid matrix destruction
• Sonoporation → an increase in cell membranes permeability, forming of membrane pores
• Local shear stress → generation of shear forces onto the matrix surface, causing the later rupture of
its structures and the extraction of inner compounds in the solvent
̶ Relevant Parameters Associated with UAE
• Physical parameters - power, frequency, and ultrasound intensity, related with the ultrasound
equipment – ET, shape and size of ultrasonic reactors
• Medium parameters - the solvent nature and its properties (polarity,, viscosity, surface tension,
solvent vapor pressure), extraction time, the presence of gases, new green solvents for lipophilic
extraction → ionic liquids and deep eutectic solvents
• Matrix parameters
• type of matrix, structure, pre-treatment, particle size, or solid-liquid ratio
Ultrasound assisted extraction (UAE)
Ústav přírodních léčiv27
Ultrasound assisted extraction
Advantages
̶ Similar results as extraction by
pressing (squeezing)
̶ High speed
̶ Economic advantage
̶ Relatively low-cost technology
involved
Disadvantages
̶ The system heats up due to the
prolonged treatment
̶ The solid matrix is completely crushed
→ difficult to separate the mass from
extract
̶ The use of ultrasound energy of more
than 20 kHz may influence the active
phytochemicals through the formation
of free radicals.
Ústav přírodních léčiv28
Microwave assisted extraction
Ústav přírodních léčiv29
Microwave assisted extraction
̶ Microwaves at 2.45 GHz
̶ Electric field causes heating
̶ Dipolar rotation
Molecules with dipol moment (permanent or induced), both in solvent and solid
Oscillation caused collisions and interactions with surrounding molecules → deliberation of thermal energy
Larger dielectric constant of solvent – greater heating
̶ Ionic conduction
Ion currents formation – resistence induces heat
̶ Extraction
̶ Disruption of weak hydrogen bonding
̶ Viscosity decreases effect
̶ Migration of ions increases solvent penetration into matrix
̶ In some cases, the matrix itself interacts with microwaves while the surrounding solvent
possesses a low dielectric constant and thus remains cold
Advantageous in the case of thermosensitive compounds - the extraction of essential oils, microwaves interact selectively with the
polar molecules present in glands, trichomes or vascular tissues. Localised heating leads to the expansion and rupture of cell walls
and is followed by the liberation of essential oils into the solvent
Ústav přírodních léčiv30
Microwave assisted extraction
̶ Closed and open wessels
Ústav přírodních léčiv31
Microwave assisted extraction
̶ Combination of MAE with
different methods
̶ Maceration
̶ Percolation
̶ Distillation
Ústav přírodních léčiv32
Rapid Solid-Liquid Dynamic Extraction (RSLDE)
̶ a negative gradient of pressure between the inner material and the
outside of the solid matrix (high pressure inside and low pressure
outside; Naviglio’s principle).
̶ When the gradient of pressure is removed, the liquid flows out of
the solid in a very fast manner and carries out all substances not
chemically bonded to the main structure of the solid.
an “active” process → the gradient of
pressure forces out the molecules
techniques based on diffusion and osmosis
→ “passive” processes, molecules are not
forced out of the matrix
Ústav přírodních léčiv33
Figure 1. Schematic representation of the Naviglio extractor consisting of two extraction
chambers connected via a conduit: the first two images show the dynamic phase, while the
third image the static phase.
An extractive cycle consists of both static and dynamic phases. During the static phase, the liquid is maintained under pressure at about
10 bar on the solid to be extracted and is left long enough to let the liquid penetrate inside the solid and to balance the pressure
between the inside and the outside of the solid (about 1–3 min). After this, at the beginning of the dynamic phase, the pressure
immediately drops to atmospheric pressure, causing a rapid flowing of liquid from the inside to the outlet of the solid matrix. At this
moment, there is a suction effect of the liquid from the inside towards the outside of the solid. This rapid displacement of the extracting
solvent transports the extractable material (compounds not chemically linked) outwards. The cycles can be repeated until the solid runs
out. Experimental tests carried out to date on more than 200 vegetables have shown that, working at a pressure of about 10 bar, most
solid matrices, regardless of the degree of crumbling, can be extracted using about 30 extractive cycles (two-minute static phase; twominute
dynamic phase) that are completed in two hours. Furthermore, the reproducibility of the extraction on the same matrix in terms
of yield was proven, and experiments were carried out to compare this method with other extraction techniques, which showed that
RSLDE had a higher recovery and a higher quality of extract, and in no case was the alteration of thermolabile substances induced
Ústav přírodních léčiv34
Comparison of different extraction techniques
LUPULI FLOS – Hop flowers (ČL 2017)
Humulus lupulus
L. – Hop, Chmel
otáčivý
(Cannabaceae)
• a dioecious, right-handed
winding climbing plant
• cultivated in US, Europe
and northern Asia
• only female plants are
grown, they reproduce
vegetatively
https://doi.org/10.1016/j.tifs.2019.08.018.
Ústav přírodních léčiv35
Hop processing
Hop material
(raw, granulate, pelets)Phenolics Essential oils
Total resins
Soft resins (hexan
soluble)
α-bitter acids
β-bitter acids
unspecified soft resins
(resupones)
Hard resins (hexan
unsoluble)
γ-hard resins
δ-hard resins
Hot water extraction Steam distillation
Methanol, ethanol, diethylether
extraction
Hexane extraction
Ústav přírodních léčiv36
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Hop products and extracts
Products
̶ Mechanical products – compressed hop, granulates
Extracts
̶ Ethanol (MW assisted, Rapid Solid-Liquid Dynamic Extraction (RSLDE) –
Naviglio´s principles)
̶ Extract containg besides α-acids, β-acids and hop essential oils also phenolics and tannins
̶ 90% ethanol, possible fractionation to get hop tannins (water soluble)
̶ CO2
̶ Supercritical or subcritical – effectivity/yield/conditions
̶ pure hop resin extract containing α-acids, β-acids and hop essential oils.
̶ Steam distillation (MW assisted)
̶ pure extract hop essential oils
̶ Vaccum distillation and chromatographic purification of CO2 extracts
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Extraction of hop components conventionally or assisted by intensified technologies, a) solvent extraction optionally assisted
by microwave (Jeliazkova et al., 2018; Tyśkiewicz et al., 2018), b) extraction assisted by pulsed electric field (Held &
Stanis, 2018), and c) pressurized extraction https://doi.org/10.1016/j.tifs.2019.08.018.
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