Abstract
Plants have always been the main source for active cosmetic ingredients, having proven health beneficial effects on human, such as anti‐aging, antioxidant, anti‐inflammatory, UV‐protective, anti‐cancer, anti‐wrinkle, skin soothing, whitening, moisturizing, etc. Extracts from herbal, aromatic and/or medicinal plants have been widely used as effective active ingredients in cosmeceuticals or nutricosmetics, especially in products for topical application and skin‐care formulations. However, over the past decade, there has been an increasing interest to plant cell culture – derived active cosmetic ingredients. These are “new generation” of high quality natural products, produced by the modern plan biotechnology methods, which usually showed stronger activities than the plant extracts obtained by the classical methods. In this review, the advantages and the current progress in plant cell culture technology for the production of active cosmetic ingredients have been summarized, and discussed in details within a presented case study for calendula stem cell product development.
Keywords: Calendula officinalis L., Cosmeceuticals, Nutricosmetics, Plant cells, Plant stem cells, Polysaccharides, Tissues and organ cultures
Abbreviations
- CMC
cambial meristematic cells
- EGF
Epidermal Growth Factors
1. Introduction
Plants are the oldest source of natural compounds with medicinal and cosmetic properties explored by the mankind. Even nowadays, between 70 and 80% of the people worldwide relay on traditional herbal medicine to cover their basic healthcare needs 1. In fact, 11% of the existed essential drugs used in modern human medicine are still with plants origin 2. The percentage of plant‐derived natural products, applied as active ingredients in cosmetics, is much higher. In accordance with the continuous increase of world population, the global demand for natural plant ingredients is expected to continue its exponential growth 1. As result, we are already witnesses of mass overexploitation of natural habitats of some herbal and aromatic plants, placing them under threat or even leading to their extinction 3. This negative tendency is especially dangerous for medicinal plants, which in most cases are rare and endemic species. These species often grew under extreme climate, unique soil composition or specific latitude. Their populations usually have been characterized with low levels of genetic diversity, which makes these species extremely vulnerable to genetic erosion and decrease their chance to survive in case of environmental pollution 4. Moreover, plant derived active ingredients are usually very complex mix of bioactive molecules, which cannot be easily replaced by chemically synthesized analogs. To solve the above problems, plant biotechnology has provided the tool, which can secure more eco‐friendly and sustainable supply of valuable phytochemicals with health‐beneficial properties, to cover the growing demands of cosmetic industry. Over the last decade, the advantages of plant cells and tissues culture technologies have been widely explored in development of highly‐efficient platforms for more rapid production of pharmaceutically important molecules of plant origin or for heterologous expression of therapeutic proteins 5. Nowadays, there are many cosmetic products, including both cosmeceuticals and nutricosmetics, which have active ingredients, derived by plant cell culture technology. The aim of this paper is to review the recent progress in plant cell technology for cosmetic application and to provide short overview on commercialized plant cell culture – derived active cosmetic ingredients available on the market. The information in this review was retrieved by an exploratory electronic survey of plant tissue culture ‐ derived cosmetic ingredients and their technical specification datasheets, conducted by search in the technical websites of the major suppliers such as Prospector® search engine, SpecialChem, Cosmetic Design Europe, the academic search engines Scopus, ScienceDirect, Google Scholar, and PubMed, and the popular search engine Google. In addition, the main steps in development and characterization of plant cell culture – derived active ingredients are closely discussed in the presented case study for development of InnovaStemCell Calendula product.
2. Plant extracts as active ingredients in cosmetics
Plants are rich source of countless metabolites with potential application in cosmetic products. Since time immemorial, the mankind has used different plants and their extracts to create cosmetics with the aim to establishing a state of eternal youth 6. Nowadays, the plant extracts are becoming the most popular active ingredients of cosmetics due to the ever‐increasing demand for natural compounds which in addition to esthetic looks can provide additional health benefits. Development of such products, known as “cosmeceuticals”, reflects a most recent trend in the modern cosmetics and personal care industries. Indeed, plants are rich in endogenous bioactive metabolites with potential cosmetic and pharmaceutical applications 7, 8, 9. Most of these phytochemicals, such as polyphenols, phenolic acids, triterpenes, flavonoids, stilbenes, steroids, carotenoids, steroidal saponins, sterols, fatty acids, polysaccharides, sugars, peptides, etc., could be extracted with appropriate solvents and used as active ingredients present in cosmetic formulations 10. Because of this, huge numbers of plant sources have been explored by the cosmetics industry in search of innovative active ingredients which combine some specific pharmacological properties, such as antioxidant, antimicrobial, antiviral, anticancer, antifungal, anti‐inflammatory, anti‐allergy, etc., and also showing strong moisturizing, anti‐ageing, anti‐wrinkle and UV protective effects 11. However, the quality and phytochemical profiles of plant extracts varied in wide range, depending on climate, soil, latitude, seasonal factors, time of harvest, and the field management practice, which could be a challenge to standardize their activities 12. The search for novel natural phytochemicals has led to the gathering bioactive extracts not only by plants, but also from mushrooms, algae, and also, by utilization of by‐products of plant origins 13, 14, 15, 16, 17. Nowadays, with the growth in consumers’ interest to effective and safe natural products, a “new generation” of high quality bioactive phytochemicals, produced by the plant cell culture technology, have been introduced in the past decade, and now, their presence in the cosmeceuticals market have been steadily on the rise.
3. Plant cell culture technology: principles for production of active cosmetic ingredients
Plant cell culture technology is a technique for growing of plant cells under strictly controlled environmental conditions. Because plant cells are considered totipotent, they have the potential to express the full genetic machinery coded in the nucleus, and thus, they are able to produce the full spectrum of characteristic secondary metabolites, found in mother plants. Plant cells are amenable to good manufacturing practice procedures and can be easily propagated by using large volume bioreactors independently on climate or soil or field management practices 5, 18. Moreover, in vitro cultured plant cells are characterized with fast growth, and the ability to accumulate large amount of uniform biomass for a short period of time 19, 20. This is very important advantage especially for the production of rare bioactive compounds, as resveratrol, paclitaxel or terpenoids, which are usually found in low concentrations in plants and their isolation and purification requires the processing of large amounts plant biomass 21, 22, 23, 24, 25. Additionally, plant cell culture technology offers a reliable and powerful production platform for continuous supply of contamination‐free, phytochemically uniform biomass from herbal, aromatic, medicinal, and even from rare and threatened plant species 26. The perspective to obtain natural phytochemicals by using an environmentally sustainable biosynthetic platform made plant cell culture technique exceptionally attractive for the production of active ingredients for high added values “green” cosmetic formulations 27, 28, 29, 30. It should be noted, that active cosmetic ingredients, obtained by the plant cell culture technology are popularized among the customers under the name “plant stem cells”. Here it is important to understand that the term “stem cells” used in this phrase is not always referred to real plant stem cells. The most of the existed plant cell culture production platforms are in fact developed on the basis of the use of dedifferentiated plant cells rather than on the culturing of the true plant stem cells. Dedifferentiated plant cells are obtained by dedifferentiation of already differentiated mature plant cells from different specialized tissues, whereas the true plant stem cells should be never differentiated in their life cycle. Because raised from the dedifferentiation of differentiated cells, the dedifferentiated plant cell cultures could inherit some epigenetic modifications, characteristic for the type of the tissues they have obtained from, and thus, they could be very heterogeneous in their biosynthetic and growth properties. This fact made it possible to generate almost unlimited numbers of plant cell lines with unique phytochemical profiles and growth characteristics even from the same plant, used for their initiation. For this reason, the terms as “leaf stem cells”, “meristems stem cells”, “root stem cells” “rhizome stem cells”, “flower stem cells”, “fruit stem cells”, etc. could be often seen in INCI names of active cosmetic ingredients, but in fact all of these refers to dedifferentiated plant cell cultures. On the other hand, there are plant cell technologies existed, which are developed on the basis of the cultivation of true plant stem cells – the cambial meristematic cells (CMC). These cells are isolated by cambial layer and consist only of true meristem stem cells 31, 32. Cambial meristematic cells are characterized with fast and uniform growth, lack of epigenetic modifications and ability to produce predictable yields of secondary metabolites when treated with stimulating factors such as elicitors 33. This technology have been used by the Korean company “Unhwa Corp.” to produce several active cosmetic ingredients, by using the patent protected expression platform Ddobyul®, developed on the basis of propagation of cambial meristematic cells (Table 1). Another important fact, concerning the plant cells used for cosmetics, is that the term “plant stem cells” is often equally used for active ingredients, produced by either callus cultures, cell suspensions or hairy roots. It is important to understand, that the callus cultures are plant cells, cultured on solid medium, whereas the cell suspension cultures are single plant cells or small cell aggregates cultivated under submerged conditions in liquid medium. Both callus cultures and cell suspensions could consist of dedifferentiated or true stem cells. On the opposite, the hairy roots are organ cultures, obtained by genetic transformation of plant cells 23, 34. Some of the plant cell culture technology – derived active cosmetic ingredients, currently available on the market are reviewed in Table 1.
Table 1.
Some of the most popular plant cell culture technology – derived active cosmetic ingredients, currently available on the market
Market names of active ingredient | Plant species | Type of cell culture and extracts | Benefits | Company; country |
---|---|---|---|---|
Phyto‐Biotics Perilla® | Perilla frutescens | cell suspension extract | anti‐aging, antimicrobial, soothing effect | Active Concepts LLC; USA |
Phyto‐Biotics Quercus® | Quercus alba | meristematic stem cells extract | antioxidant, soothing effect, antimicrobial, anti‐aging | Active Concepts LLC; USA |
Phyto‐Biotics Acai® | Euterpe oleracea | cell suspension extract | antioxidant, anti‐aging, anti‐wrinkle, soothing effect, moisturizer | Active Concepts LLC; USA |
AKOSKY® APIUM | Apium graveolens | callus culture extract | skin regeneration | Akott Evolution S.R.L.; Italy |
VITADENIA® | Gardenia taitensis | callus culture extract | anti‐aging, anti‐wrinkle, regenerative, repairing | Biocosmethic; France |
UrbanEthic® | Gossypium herbaceum | stem cell extract | anti‐photo‐aging, protection against atmospheric pollutants and heavy metals. protection from oxidative stress | Biocosmethic; France |
NatureCells Hydragenesis | Vitis vinifera cv. Verdejo | liposomal complex of cell suspension extract | antioxidant, moisturizer, hydrating effect | Infinitec; Spain |
NatureCells Antiaging | Vitis vinifera cv. Mencia | liposomal complex of cell suspension extract | anti‐aging, antioxidant, anti‐wrinkle | Infinitec; Spain |
NatureCells Anti Stretch Marks | Centella asiatica | liposomal complex of cell suspension extract | skin‐firming, anti‐stretch mark effect, anti‐inflammatory, anti‐cellulite | Infinitec; Spain |
InnovaStemCell Calendula W | Calendula officinalis | cell suspension extract | anti‐wrinkle, skin regeneration, moisturizer | Innova BM; Bulgaria |
InnovaStemCell Calendula EM | Calendula officinalis | emulsified cell suspension | anti‐wrinkle, skin regeneration, deep hydration | Innova BM; Bulgaria |
InnovaStemCell Rosa damascena W | Rosa damascena | cell suspension extract | skin regeneration, anti‐aging, antioxidant, anti‐inflammatory | Innova BM; Bulgaria |
InnovaStemCell Rosa rugosa W | Rosa rugosa | cell suspension extract | antioxidant, antimicrobial, UV protective | Innova BM; Bulgaria |
Plant C‐Stem™ Vigna Radiata | Phaseolus radiatus | meristem cell culture vacuole extract | anti‐aging, anti‐wrinkle, protection/repair of environmental damage | Innovacos Corp.; USA |
Roseroot (Rhodiola rosea L .) Plant Stem Cell Extract | Rhodiola rosea | callus culture extract | antioxidant | In vitro Plant‐tech AB; Sweden |
Milk thistle (Silybum marianum L.) plant stem cell extractat | Silybum marianum | callus culture extract | antioxidant | In vitro Plant‐tech AB; Sweden |
Greater plantain (Plantago major L.) plant stem cell extract | Plantago major | callus culture extract | antioxidant | In vitro Plant‐tech AB; Sweden |
PhytoCellTec™ Malus Domestica | Malus domestica | liposomal complex of cell suspension extract | anti‐wrinkle | Mibelle AG Biochemistry; Switzerland |
PhytoCellTec™ Solar Vitis | Vitis vinifera cv. Gamay Teinturier Fréaux | cell suspension extract | anti‐photo‐aging, extending skin vitality | Mibelle AG Biochemistry; Switzerland |
PhytoCellTec™ Alp Rose | Rhododendron ferrugineum | cell suspension extract | protecting longevity, increasing skin vitality, protection/repair of environmental damage | Mibelle AG Biochemistry; Switzerland |
PhytoCellTec™ Argan | Argania spinosa | cell suspension extract | improve activity of human dermal stem cells, anti‐wrinkle | Mibelle AG Biochemistry; Switzerland |
PhytoCellTec™ Symphytum | Symphytum officinale | cell suspension extract | increase skin renewal, rejuvenates skin epidermis | Mibelle AG Biochemistry; Switzerland |
PhytoCellTec™ nunatak® | Saponaria pumila | cell suspension extract | increase skin elasticity, firmness and density, protection/repair of environmental damage, anti‐aging | Mibelle AG Biochemistry; Switzerland |
RootBioTec HO | Ocimum basilicum | hairy root culture extract | reduce hair loss, inhibit 5α reductase activity, stimulate dermal papilla cells | Mibelle AG Biochemistry; Switzerland |
EGF (Epidermal Growth Factor); | Oryza sativa | recombinant proteins expressed by rice cell culture | restore reduced activity with age, stimulate epidermal skin cells, anti‐aging, anti‐wrinkel, wound healing, stimulation on collagen synthesis in aged skin | Natural Bio‐Materials (NBM) Inc.; Korea |
FGFb (basic Fibroblast Growth Factor) | Oryza sativa | recombinant proteins expressed by rice cell culture | anti‐aging, anti‐wrinkle, anti‐hair loss, hair growth | Natural Bio‐Materials (NBM) Inc.; Korea |
IGF‐1 (Insulin‐like Growth Factor‐1) | Oryza sativa | recombinant proteins expressed by rice cell culture | growth support for skin cells with EGF, support young and healthy skin | Natural Bio‐Materials (NBM) Inc.; Korea |
KGF (Keratinocyte Growth Factor, Fibroblast Growth Factor‐7) | Oryza sativa | recombinant proteins expressed by rice cell culture | specific growth factor for keratinocyte | Natural Bio‐Materials (NBM) Inc.; Korea |
VEGF165 (Vascular Endothelial Growth Factor) | Oryza sativa | recombinant proteins expressed by rice cell culture | skin cell growth and support, wrinkel and skin aging improvement, wound healing after laser resurfacing or injury, hair cell growth and support, hair cycle regulation and anti‐hair loss | Natural Bio‐Materials (NBM) Inc.; Korea |
Foreseen Shield Nopal | Opuntia ficus indica | powdered leaf cells | antioxidant, anti‐wrinkle, anti‐aging, UV protective, decrease melanine spots | Naolys, France |
Initial E [PT+TMG] | Polianthes tuberosa | callus culture extract | anti‐aging, anti‐wrinkle, anti‐circle, | |
anti‐puffines, brightening, firming, soothing, moisturizing | Naolys, France | |||
Power Extension [HSB+R] | Hibiscus syriacus | leaf cell extract with rutin | anti‐aging, anti‐wrinkle, antioxidant | Naolys, France |
All Even Sweet iris | Iris pallida | glycerin based leaf cell extract | anti‐aging, anti‐wrinkle, firming | Naolys, France |
All Fiber Booster Olive tree | Olea europea | glycerin based leaf cell extract | anti‐aging, restructurating | Naolys, France |
All Fiber Booster Chinese hibiscus | Hibiscus rosa sinensis | glycerin based leaf cell extract | anti‐aging, restructurating | Naolys, France |
All Fiber Booster Green tea | Camellia sinensis | glycerin based leaf cell extract | anti‐aging, firming, regenerating, softening, restructurating | Naolys, France |
Fiber Booster Plus Sequoia and Vitis flower | Sequoia sempervirens and Vitis vinifera | glycerin based leaf and flower cells extract | anti‐aging, antioxidant | Naolys, France |
Inside Heart Egyptian blue lily | Nymphaea caerulea l | glycerin based leaf and flower cells extract | anti‐aging, antioxidant | Naolys, France |
Revive Commiphora and | ||||
Rose from Damas | Commiphora myrrha and Rosa damascena | glycerin based leaf cells extract | anti‐aging, energizing | Naolys, France |
StandStill Rose from Damas | Rosa damascena | glycerin based leaf cells extract | anti‐aging, firming | Naolys, France |
New ReGeneration Cocoa | Theobroma cacao | glycerin based leaf cells extract | anti‐aging, firming, regenerating, protective, restructurating | Naolys, France |
Total Generation Sequoia and Egyptian blue lily | Sequoia sempervirens and Nymphaea caerulea | glycerin based leaf cells extract | anti‐aging, regenerating | Naolys, France |
Total Generation Curry plant | Helicrysum italicum | glycerin based leaf cells extract | anti‐aging, regenerating | Naolys, France |
Inside Light Poet's narcissus | Narcissus poeticus | callus culture extract | brightening, lightening and anti‐blemish, anti‐aging | Naolys, France |
Bright Light Madonna lily | Lilium candidum | powdered leaf cells | brightening, regenerating | Naolys, France |
LightWaves Defense [JS+M] | Jasminum sambac | sunflower oil based leaf cells extract | protective, anti‐aging, radiance, firming, anti‐redness | Naolys, France |
Global Protect Common juniper | Juniper communis | glycerin based leaf cells extract | protective, anti‐pollution | Naolys, France |
OxyRelax California poppy | Eschscholzia californica | glycerin based leaf cells extract | protective, antioxidant, anti‐aging | Naolys, France |
OxyRelax Cherry tree | Prunus cerasus | glycerin based leaf cells extract | protective, antioxidant, cell relaxing | Naolys, France |
Smooth Lightening White rose | Rosa alba | glycerin based leaf cells extract | protective, antioxidant, radiant, regenerating, detoxifying | Naolys, France |
Sun Protect Date palm | Bombax costatum | glycerin based leaf cells extract | protective, soothing, sunscreen, anti‐aging | Naolys, France |
Whole Protection Edelweiss | Leontopodium alpinum | sunflower oil based leaf cells extract | protective, soothing, repairing, anti‐aging | Naolys, France |
Whole Protection Red‐flowered silk cotton tree | Bombax costatum | glycerin based leaf cells extract | protective, soothing | Naolys, France |
Refine Ginger | Zingiber officinale | glycerin based leaf cells extract | astringent, firming, mattifying, moisturizing, antioxidant | Naolys, France |
Pure Light Chinese peony | Paeonia lactiflora | powdered leaf cells | mattifying, radiance, moisturizing, soothing, relaxing | Naolys, France |
Unwind Sacred lotus | Nelumbo nucifera | sunflower oil based leaf cells extract | soothing, relaxing, radiance | Naolys, France |
Essential Being Indian jasmine | Jasminum sambac | glycerin based leaf cells extract | regenerating, detoxifying | Naolys, France |
Full Detox Ylang Ylang | Cananga odorata | sunflower oil based leaf cells extract | radiance, mattifying, regenerating, antioxidant, anti‐pollution | Naolys, France |
Purify Apothecary's rose | Rosa gallica | sunflower oil based callus extract | soothing, regenerating, radiance | Naolys, France |
Purify Aloe vera | Aloe barbadensis | sunflower oil based callus extract | soothing, regenerating, radiance | Naolys, France |
First Light Snow lotus | Saussurea involucrata | sunflower oil based callus extract | radiance, brightening, regenerating, antioxidant | Naolys, France |
HydraSourcing [AM+PS] | Argemone mexicana | glycerin based callus extract | moisturizing, protective, regenerative, anti‐aging | Naolys, France |
HydraGeneration Papyrus | Cyperus papyrus | powdered leaf cells | hydrating, protective, barrier function | Naolys, France |
HydraGeneration Pale rose | Rosa centifolia | glycerin based leaf cells extract | moisturizing, regenerative | Naolys, France |
HydraSoothing Indian olibanum | Boswellia serrata | sunflower oil based leaf cells extract | moisturizing, regenerative, antioxidant, soothing | Naolys, France |
Soothing Light Apple tree | Malus domestica | powdered leaf cells | soothing, lightening, radiance | Naolys, France |
Fragile Vitis flower | Vitis vinifera | glycerin based flower cells extract | soothing, antioxidant | Naolys, France |
Fragile Cotton | Gossypium arboreum | glycerin based leaf cells extract | soothing, protective | Naolys, France |
Fragile Japanese Cherry tree | Prunus serrulata | sunflower oil based leaf cells extract | soothing, antioxidant | Naolys, France |
Soothing Light Apricot | Prunus armeniaca | glycerin based leaf cells extract | soothing, lightening | Naolys, France |
OvernightEnhance [MJ+C] | Mirabilis jalapa | glycerin based callus extract | radiance, energizing, repairing, detoxifying, antioxidant | Naolys, France |
Balancing Energy Asian ginseng | Panax ginseng | sunflower oil based leaf cells extract | energizing, antioxidant | Naolys, France |
Light&Energy Coffee and Saffron | Crocus sativus and Coffea arabica | sunflower oil based callus and leaf cells extract | energizing, antioxidant, radiance | Naolys, France |
Full Energy Vanilla | Vanilla planifolia | sunflower oil based leaf cells extract | energizing, antioxidant, regenerating | Naolys, France |
Splint&Slim Great bougainvillea | Bougainvillea spectabilis | powdered leaf cells | firming, slimming, lipolitical, anti‐aging | Naolys, France |
EtHAIReal Peppermint | Mentha piperita | sunflower oil based leaf cells extract | regulating, soothing, antioxidant, lightening | Naolys, France |
Healthy Shine Lilac | Syringa vulgaris | glycerin based leaf cells extract | restoring shine and damaged hair, soothing, energizing, protective | Naolys, France |
3HC Hair Stimulation Complex | Vitis vinifera | mix of meristem plant cell culture derived active ingredients and hydrolyzed plant extracts | increase the lifespan of hair and reduce hair loss | Phenbiox SRL; Italy |
Soy Cell | Glycine max | callus culture extract | anti‐photo‐aging, antiradical, anti‐wrinkles | Phenbiox SRL; Italy |
G‐Cell | Vitis vinifera | meristem cell culture from green unripe grapes extract | antioxidant, skin protective | Phenbiox SRL; Italy |
P‐Cell | Capsicum annuum | fruit meristem cell culture extract | promote cell protein synthesis, increase skin elasticity | Phenbiox SRL; Italy |
Citrustem™ | Citrus aurantium dulcis | callus culture extract | anti‐aging, skin conditioner | Provital Group; Spain |
Lingostem™ | Vaccinium vitis‐idaea | callus culture extract | anti‐aging, anti‐wrinkle, make up treatments | Provital Group; Spain |
RASTEM | Lpomoea purpurea | callus culture extract | skin‐renewal, anti‐inflammatory, anti‐wrinkle, antioxidant | Radiant Inc.; Korea |
Carrot Stem Cell | Daucus carota | callus culture extract | antioxidant, skin‐nourishing effect | Radiant Inc.; Korea |
Cucumber Stem Cell | Cucumis sativus | callus culture extract | skin cooling effect, moisturizer | Radiant Inc.; Korea |
Ginseng Stem Cell | Panax ginseng | cell culture extract | skin regeneration | Radiant Inc.; Korea |
Lotus Stem Cell Extract | Nelumbo nucifera | callus culture extract | controls excessive sebum secretion, absorbs sebum, maintains clean skin condition | Sandream Impact LLC; USA |
Tomato Callus Stem Cell Extract | Solanum lycopersicum | callus culture extract | moisturizer | Sandream Impact LLC; USA |
Rice Callus Stem Cell Extract | Oryza sativa | callus culture extract | antioxidant, anti‐inflammatory, whitening | Sandream Impact LLC; USA |
Carrot Callus Stem Cell Extract | Daucus carota | callus culture extract | moisturizer | Sandream Impact LLC; USA |
Rose Callus Stem Cell Extract | Rosa damascena | callus culture extract | protecting longevity, delaying senescence, increasing skin vitality, boosting epidermal skin cell regeneration | Sandream Impact LLC; USA |
Grape Callus Stem Cell Extract | Vitis vinifera | callus culture extract | antioxidant, anti‐inflammatory | Sandream Impact LLC; USA |
Orchid Callus Stem Cell Extract | Orchis spp. | callus culture extract | promote skin growth and proliferation, moisturizer, skin rejuvenation, soothing effect | Sandream Impact LLC; USA |
Ginseng Callus Stem Cell Extract | Panax pseudoginseng | callus culture extract | restorative effect, tonic | Sandream Impact LLC; USA |
Green Tea Callus Stem Cell Extract | Camellia sinensis | callus culture extract | antioxidant, anti‐inflammatory | Sandream Impact LLC; USA |
Marrubium Stems GX™ | Marrubium vulgare | cell suspension extract | protective effect, pollution defense, skin conditioner | Sederma (Croda Personal Care); United Kingdom |
Buddleja Stems GX™ | Buddleja davidii | cell suspension extract | anti‐photo‐aging, anti‐aging, protects from UV‐induced oxidative stress, anti‐inflammatory, matrix metalloproteinase activation | Sederma (Croda Personal Care); United Kingdom |
Centella Stems GX™ | Centella asiatica | cell suspension extract | reduces skin redness, straightening capillary structure, fights against rosacea | Sederma (Croda Personal Care); United Kingdom |
Dermasyr 10™ | Syringa vulgaris | verbascoside concentrate extracted from leaf cell culture | reduce skin blemishes and inflammatory hyper‐pigmentation, control skin redness and balances of seborrhea, soothing, purifying, skin conditioning | Sederma (Croda Personal Care); United Kingdom |
Echinacea Stems GX™ | Echinacea angustifolia | cell suspension extract | stimulates collagen synthesis, prevents collagen loss, reduces capillary permeability | Sederma (Croda Personal Care); United Kingdom |
Gardenia Stems GX™ | Gardenia jasminoides | cell suspension extract | reduces MMP‐1 synthesis, inhibits collagenase activity, stimulates collagen synthesis | Sederma (Croda Personal Care); United Kingdom |
Leontopod Stems GX™ | Leontopodium alpinum | cell suspension extract | prevents collagen loss, antioxidant, anti‐wrinkle | Sederma (Croda Personal Care); United Kingdom |
Celtosome™ Eryngium Maritimum ST | Eryngium maritimum | dried stem cell | anti‐aging, improving skin firmness, skin renewal | SEPPIC (Air Liquide Healthcare); France |
Celtosome Crithmum Maritimum ST | Crithmum maritimum | dried stem cell | skin lightening, wound healing, lightening effect, pigmentation regulation, anti‐wrinkle | SEPPIC (Air Liquide Healthcare); France |
Ddobyul® | Panax ginseng | cambial meristematic cells suspension extract | anti‐aging | Unhwa Corp.; Korea |
Ddobyul® | Taxus cuspidata | cambial meristematic cells suspension extract | anti‐allergic | Unhwa Corp.; Korea |
Ddobyul® | Ginkgo biloba | cambial meristematic cells suspension extract | whitening | Unhwa Corp.; Korea |
Ddobyul® | Solanum lycopersicum | cambial meristematic cells suspension extract | antioxidant | Unhwa Corp.; Korea |
Vita SeneBlock | Citrus limon | mix of cell wall peptides and sugars from somatic embryos | inducing youth and longevity markers, protect DNA | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Vita iLux | Capsicum annuum | mix of peptides and sugars from cell cultures | firming effect, promoting bilirubin degradation, improves skin's regenerative process | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Hibiskin Vita | Hibiscus syriacus | cell culture extract | restore colagen, improve skin barrier function, moisturizer, improves skin's regenerative process | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Mythos Vita | Actinidia arguta | mix of stem cell culture derived extract and hydrosoluble plant fruit extract | anti‐photo‐aging, protect DNA | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Vita Nova | Lotus japonicus | mix of cell wall peptides and sugars from somatic embryos | extends cellular vitality and longevity, anti‐aging, reactivate skin's natural repair process | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Vita Genesis White | Brassica rapa | mix of cell wall fraction and hydro‐ethanolic extract derived from hairy root cultures | inhibits pigmentation process, reduce melanin synthesis | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Vita Freeze | Solanum lycopersicum | mix of peptides and sugars from cell cultures | prevent premature skin ageing, improve skin elasticity, extend cellular vitality and longevity | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Daphne VitaSense | Daphne odoracell | cell suspension extract | strengthens skin protecting barrier, accelerate healing of cutaneous micro‐lesions, reduce skin inflammation | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
VitaLight | Cirsium eriophorum | cell suspension extract | reduce sebum production, reduce skin inflammation, increase skin desquamation | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
VitaShape | Coleus forskohlii | cell suspension extract | anti‐fat properties, anti‐oedema effect, antioxidant, detoxifying capacity | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
BerryFlux Vita | Rubus idaeus | cell culture extract | moisturizer, hydrating effect, improve production of ceramides | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
FicuCell Vita | Opuntia spp. | cell culture extract | protect extracellular matrix, extend cellular longevity, delay premature skin ageing, improve skin firmness and elasticity | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
DoliCos PhotoProtect | Dolichos spp. | cell culture extract | UV protective,detoxifie cells, soothing effect | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Cell Pulse | Coffea spp. | cell culture extract | antioxidant, cell energiser, anti‐wrinkle | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Lycoskin Defence | Solanum lycopersicum | water‐soluble fraction from cell cultures | extend cellular vitality, protect DNA, radiance effect | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
BioNymph Peptide | Nicotiana sylvestris | mix of peptides and sugars from cell cultures | antioxidant, extend cellular vitality and longevity, anti‐wrinkle, improve skin smoothness | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
Cellintegrity | Rubus idaeus | concentrated water‐soluble fraction from cell cultures | antioxidant, anti‐inflammatory, protect DNA, enhance cellular longevity, soothing effect, strengthening action | Vitalab s.r.l. (Arterra Bioscience s.r.l); Italy |
SENSIA CAROTA PRCF | Daucus carota sativa | lysate of root stem cells culture | anti‐aging, anti‐inflammatory, antioxidant | Vytrus Biotech; Spain |
LUMINIA GRANATUM PRCF | Punica granatum | powdered plant stem cells | antioxidant, reduces hyper‐pigmentation, enhances skin radiance and glow | Vytrus Biotech; Spain |
ARABIAN COTTON PRCF | Gossypium herbaceum | lysate of plant stem cells culture | soothing, anti‐inflammatory, antioxidant, photoprotection, regeneration | Vytrus Biotech; Spain |
TURMERIA ZEN PRCF | Curcuma longa | glycerin based lysate of rhizome cells culture | anti‐stress wrinkles, emotional hydration manager, modulator of Brain‐skin connection | Vytrus Biotech; Spain |
SARCOSLIM RE‐SHAPE PRCF | Sarcocapnos crassifolia, | lysate of callus culture | skin regeneration and repair | Vytrus Biotech; Spain |
CAPILIA LONGA PPF | Curcuma longa | plant growth factor peptides ‐ concentrated secretome of totipotent rhizome cells | hair follicle regeneration, hair growth re‐activation | Vytrus Biotech; Spain |
CENTELLA REVERSA PPF | Centella asiatica | plant signaling peptides ‐ concentrated secretome of totipotent petioles cells | rebuilding the core skin structure | Vytrus Biotech; Spain |
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3.1. Plant stem cells
Plant cells can be propagated and used for continuous supply of fresh plant biomass for cosmetic formulations. However, it is of great importance to understand that we cannot introduce the entire plant cells in cosmetic products and keep them alive as active ingredient there 30, 35. Plant cells are extremely sensitive to environmental factors, nutrient medium composition, osmotic and mechanical (shear) stress, gas exchange and oxygen supply, temperature, light, ionic strength and water content, and thus, they can survive neither during cosmetic products preparation, nor during storage or application of cosmetics on skin. Even a delivery system, able to maintain and supply live stem cells could be developed, the size and the specific structure of plant cells will not allow them to attach or penetrate the skin surface. Because of all discussed concerns, the plant stem cells are rather used as a raw material for preparing different types of extracts, which then could be included in cosmetic formulations as active ingredients. However, there are various products, available on the market, which are based on a whole dried plant cells and standardized on the cells count per gram of active ingredient (Table 1). Such examples are the anti‐aging active ingredient Celtosome™ Eryngium Maritimum ST (based on sea holly cell culture with 100 million cells/g of active ingredient), and the tyrosinase inhibitory skin lightening active ingredient Celtosome™ Crithmum Maritimum ST (based on rock samphire cell culture with more than 1 billion cells/g of active ingredient) (Table 1).
3.2. Plant stem cells extracts
Most of the available active cosmetic ingredients, obtained by plant cell culture technology are marketed in the form of different extracts (Table 1). In contrast to the plant – derived extracts, the extracts obtained from plant cell cultures can be easily standardized, and perfectly complying with the strict safety requirements that the high end cosmetic market constantly demands 35. Plant cell extracts are free of pathogens, agrochemical, toxic substances, allergens and pollutants, because they are produced under controlled conditions, complying with the procedures of good manufacturing practice. Depending of the type of used solvent, the plant cell extracts used in cosmetics could be contingently divided to liposoluble (extracted with oils) and hydrosoluble (extracted with glycerin) extracts, dried extracts (conditioned with maltodextrin), plant cell wall extracts (rich in peptides and sugars), nanoemulsions or suspension extracts 35. However, most of the existed extracts have been developed on the basis on extraction of target compound or group of closely related bioactive compounds, and thus, not the entire health beneficial potential of the extracted plant cells could be utilized. Some exceptions could be found, where the entire plant cells were freeze dried and powdered for direct application in cosmetic formulations (see some products offered by “Vytrus Biotech” and “Naolys”, Table1), or the entire cell suspensions have been, emulsified or encapsulated in liposomal complex (see some products offered by “Innova BM” and “Mibelle AG Biochemistry”, Table1) by using high‐pressure homogenizers.
3.3. Molecular farming for production of recombinant proteins
Plants are excellent production matrixes for expression of recombinant proteins with important pharmaceutical properties 36. This powerful recombinant protein expression technique, known as “molecular farming” have been widely used for the production of vaccines 37, 38, 39, cytokines 40, and even for production of therapeutic protein for human use 5, 41, 42. The classical molecular farming technology is based on genetic modification of plants for recombinant protein expression. This could be realized by permanent integration of foreign genes into the host DNA to generate stable transgenic lines, or by transient transformation of intact plant leaves 43. However, both methods requires growing of whole plants under strictly controlled environmental conditions into contained greenhouses, complying with the strict regulatory standards 36. By using such technology, The Iceland Company “BIOEFFECT” has applied for the first time a plant‐based transgenic platform for large‐scale production of Epidermal Growth Factors (EGF) for cosmetic use, expressed in genetically engineered barley seeds. The company offers a wide range of skin‐care products containing this cellular activator, which contribute for healthier and younger‐looking skin. However, the recent interests in molecular farming have been focused on adaptation of plant cell culture technology for the production of recombinant proteins. This technique offers sustainable and continuous heterologous proteins production by plant cells growing under precisely controlled micro‐environmental in vitro conditions in bioreactors. Cultivation of genetically engineered plant cell cultures have been recognized as much powerful expression platform, when compared to the classical molecular farming techniques, relying on agricultural‐scale production by growing of genetically transformed plants 18, 41. Recently, the Korean company “Natural Bio‐Materials (NBM)”, has launched series of active cosmetic ingredients containing growth factors (Epidermal Growth Factor, Basic Fibroblast Growth Factor, Insulin‐like Growth Factor‐1, Keratinocyte Growth Factor, Fibroblast Growth Factor‐7, and Vascular Endothelial Growth Factor), expressed by recombinant rice (Oryza sativa L.) cell cultures (Table 1). However, even that the human recombinant proteins, produced by this technology have undeniable advantages and are characterized with high level of purity, animal‐free, virus‐free, bacterial‐free and exotoxin‐free production, there are still some consumers which have concerns to use such products because they are expressed by genetically modified organisms.
4. Case Study: Initiation, growth, phytochemical profile and physicochemical characteristics of exopolysaccharides in INNOVA StemCell Calendula
Calendula (Calendula officinalis L.), known as “marigold”, has been widely used in traditional herbal medicine and skin care cosmeceuticals for topical application 11. The pant was shown to be rich in phenolic acids, flavonoid, triterpenes, carotenoids, aroma compounds and unique mix of polyunsaturated fatty acids 44, 45, 46. Because of its high therapeutic value and the proved cosmetic effects, the Bulgarian company “Innova BM” has developed and released on the market two high quality active cosmetic ingredients, based on Calendula dedifferentiated cell culture (Table 1). The development of these products is schematically presented on Fig. 1. The technological steps include screening of calendula plants with superior phytochemical profiles, selection, sterilization and cultivation of plant explants on callus induction medium, selection of friable cell lines with appropriate phytochemical profiles, initiation of liquid cell suspension culture and optimization of cultivation conditions and nutrient medium composition. The optimization step is critical in our technology, since a significant increase in biosynthetic potential and accumulated biomass of selected cell line can be achieved (Table 2, Fig. 2). After optimization, the selected line was scaled‐up to large scale cultivation in stirred tank bioreactor. The produced cell suspension (cells and culture liquid) was then processed by high‐pressure homogenizer to produce glycerin extract (50 % wt.) or calendula emulsion (75 % wt. cell suspension) 47. The produced active ingredients have been found to have superior moisturizing, anti‐wrinkle, hydrating and regenerative effects, when applied on skin. These effects are due to the high content of secreted exopolysaccharides, during cultivation of calendula cells (Fig. 2D). The exopolysaccharides have been identified to belong to pectin type. The crude exopolysaccharides fraction contains 879 μg/mg neutral sugars and 50 μg/mg proteins. The unique combination of polysaccharides and peptides made this exopolysaccharide fraction almost perfect for application as emulsifier in cosmetic products for topical application. The potential synergistic interactions, when applied with other popular emulsifiers, as well as their emulsion stabilization properties are presented in Table 3. The polysaccharides have molecular weight of 6.7 × 104 Da and contain 413μg/mg uronic acids. The full monosaccharide composition of exopolysaccharide fraction was determined as: glucuronic acid (13.6μg/mg), galacturonic acid (399.7 μg/mg), glucose (185.5μg/mg), galactose (179.9μg/mg), rhamnose (178.9μg/mg), arabinose (166.7μg/mg), fucose (0.6μg/mg) and mannose (4.7 μg/mg). The presence of this exopolysaccharides fraction incorporated into Innova StemCell Calendula products, in combination with bioactive compounds from the released cell content (Table 2) made these products unique and one of the kind in the market of active cosmetic ingredients.
Table 2.
GC‐MS profiles of Calendula officinalis stem cell suspension before and after optimization of nutrient medium composition 47
Metabolites | Calendula cell suspension before optimization | Calendula cell suspension after optimization |
---|---|---|
μg/g dry biomass | μg/g dry biomass | |
Amino acids | ||
Glycine | 62.77 | 106.74 |
Serine | 21.09 | 175.87 |
L‐Proline | 73.08 | 162.56 |
L‐Aspartic acid | 10.83 | 138.41 |
L‐Glutamic acid | 161.68 | 274.91 |
L‐Asparagine | 19.19 | 146.38 |
L‐Glutamine | 88.03 | 224.10 |
Organic acids | ||
Succinic acid | 6.40 | 130.88 |
Fumaric acid | 7.23 | 172.30 |
Malic acid | 5.41 | 149.20 |
GABA | 50.02 | 184.38 |
Pyroglutamic acid | 20.41 | 115.51 |
Saturated and Non‐saturated Fatty Acids | ||
n‐Tetracanoic acid (Myristic acid) (C14:0) | 26.68 | 83.07 |
n‐Hexadecanoic acid (Palmitic acid) (C16:0) | 183.91 | 178.69 |
9‐(Z)‐Hexadecenoic acid (Oleic acid) (C 18:1) | 39.33 | 95.36 |
Octadecanoic acid (Stearic acid) (C 18:0) | 197.61 | 192.01 |
Sterols | ||
Campesterol | 59.27 | 59.07 |
Stigmasterol | 65.34 | 89.14 |
β‐Sitosterol | 94.82 | 112.77 |
β‐Amyrin | 12.13 | 77.46 |
Phenolic acids | ||
Quinic acid | 13.49 | 81.92 |
Caffeic acid | ‐ | 62.05 |
trans‐Cinnamic acid | ‐ | 170.39 |
p‐Coumaric acid | ‐ | 67.63 |
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Table 3.
Synergistic effect of exopolysaccharides, released by Calendula officinalis stem cell suspension in relation to emulsion stabilizing properties in mixtures with cellulose gum, xanthan gum, guar gum, and sodium‐alginate
Model emulsion systems Oil/Water (1:1 v/v) with: | Light microscopy | Turbidimetric method | |
---|---|---|---|
Emulsifying activity index (EAI), m2/g | Emulsion stability index (ESI), min | ||
0.6 % Calendula Cell Suspension Exopolysaccharides | 175.0 | 16.8 | |
0.6 % Calendula Cell Suspension Exopolysaccharides And 0.3 % Cellulose Gum | 38.4 | 13.9 | |
0.6 % Calendula Cell Suspension Exopolysaccharides and 0.3 % Xanthan Gum | 47.6 | 22.1 | |
0.6 % Calendula Cell Suspension Exopolysaccharides and 0.3 % Guar Gum | 322.4 | 15.0 | |
0.6 % Calendula Cell Suspension Exopolysaccharides and 0.3 % Sodium Alginate | 1307.5 | 60.7 |
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The emulsifying activity index (EAI) and emulsion stability index (ESI) were determined according to 48. Model emulsion systems were prepared by mixing polysaccharides, water and sunflower oil for 5 min at 10 000 rpm by homogenizer (Ultra Turrax IKA T18 Basic, Germany).
5. Concluding remarks
Following the ever‐growing demand for high quality natural products of plant origin for application as active ingredients in cosmeceutical formulations, the plant cell culture technology has developed powerful production platforms which can effectively supply the customers’ needs. We are witnesses of exponentially growing number of commercialized plant cell – derived ingredients, offered on the cosmetic industry market and the diversity of utilized plant species, used for their production has continue to increase every year. In fact, the observed interest to production of plant cell ‐ derived ingredients for cosmetic needs could be correlated with the recent advance in development and commercialization of plant cell culture technology in technologically advanced countries. Moreover, the new developed techniques of gene editing, metabolite engineering and synthetic biology could have a significant impact on improvement the yields and development of tailor made cosmetic products with desired activities. The advance in molecular farming has already leaded to commercial production of rare human activator peptides, cytokines and growth factors, which are the first step in development of cosmetic products with potential to extend skin life by using the body self‐repair mechanisms. However, till now there are many open questions, concerning regulatory standards and documentation, unification of health beneficial claims and the methodology for evaluation of pharmaceutical effects, which should be answered in order to help the consumers to make the right choice of their cosmeceutical product.
Practical application
The aim of this paper is to review the recent progress in plant cell technology for cosmetic application and to provide short overview on commercialized plant cell culture – derived active cosmetic ingredients available on the market.
The authors have declared no conflict of interest.
Acknowledgments
We would like to thanks the Innova BM, Bulgaria, for the financial support, close collaboration and the shared data.
6 References
- 1.Siahsar, B., Rahimi, M., Tavassoli, A., Raissi, A., Application of biotechnology in production of medicinal plants. Am. Eurasian J. Agric. Environ. Sci.2011, 11, 439–444. [Google Scholar]
- 2.Rischer, H. T., Hakkinen, S., Ritala, A., Seppanen‐Laakso, T., etal., Plant cells as pharmaceutical factories. Curr. Pharm. Des.2013, 19, 5640–5660. [DOI] [PubMed] [Google Scholar]
- 3.Bodeker G, Bhat K, Burley J, Vantomme P., (Eds.) Medicinal plants for forest conservation and health care, Food & Agriculture Org; 1997. [Google Scholar]
- 4.Brown, A. H. D., Hodgkin, T., Indicators of genetic diversity, genetic erosion, and genetic vulnerability for plant genetic resources, in: Ahuja M. R., Jain S. M. (Eds.) Genetic Diversity and Erosion in Plants: Indicators and Prevention, Springer International Publishing, Cham, 2015, pp. 25–53. [Google Scholar]
- 5.Georgiev, V., Mass propagation of plant cells–an emerging technology platform for sustainable production of biopharmaceuticals. Biochem. Pharmacol. (Los Angel).2015, 4, e180. [Google Scholar]
- 6.Charles Dorni, A. I., Amalraj, A., Gopi, S., Varma, K., etal., Novel cosmeceuticals from plants—An industry guided review. J. Appl. Res. Med. Aromat. Plants.2017, 7, 1–26. [Google Scholar]
- 7.Armendáriz‐Barragán, B., Zafar, N., Badri, W., Galindo‐Rodríguez, S. A., etal., Plant extracts: from encapsulation to application. Expert Opinion on Drug Delivery. 2016, 13, 1165–1175. [DOI] [PubMed] [Google Scholar]
- 8.Działo, M., Mierziak, J., Korzun, U., Preisner, M., etal., The potential of plant phenolics in prevention and therapy of skin disorders. Internat. J. Mol. Sci.2016, 17, 160. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Ferrazzano, G., Amato, I., Ingenito, A., Zarrelli, A., etal., Plant polyphenols and their anti‐cariogenic properties: a review. Molecules2011, 16, 1486. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.Ribeiro, A., Estanqueiro, M., Oliveira, M., Sousa Lobo, J., Main benefits and applicability of plant extracts in skin care products. Cosmetics2015, 2, 48. [Google Scholar]
- 11.Gediya, S. K., Mistry, R. B., Patel, U. K., Blessy, M., etal., Herbal plants: used as a cosmetics. J. Nat. Prod. Plant Resour.2011, 1, 24–32. [Google Scholar]
- 12.Papaioanou, M., Chronopoulou, E., Ciobotari, G., Efrose, R., etal., Cosmeceutical properties of two cultivars of red raspberry grown under different conditions. Cosmetics2018, 5, 20. [Google Scholar]
- 13.Taofiq, O., González‐Paramás, A. M., Martins, A., Barreiro, M. F., etal., Mushrooms extracts and compounds in cosmetics, cosmeceuticals and nutricosmetics—a review. Industrial Crops Products2016, 90, 38–48. [Google Scholar]
- 14.Barbulova, A., Colucci, G., Apone, F., New trends in cosmetics: by‐products of plant origin and their potential use as cosmetic active ingredients. Cosmetics2015, 2, 82. [Google Scholar]
- 15.Guillerme, J.‐B., Couteau, C., Coiffard, L., Applications for marine resources in cosmetics. Cosmetics2017, 4, 35. [Google Scholar]
- 16.Juliano, C., Magrini, G., Cosmetic functional ingredients from botanical sources for anti‐pollution skincare products. Cosmetics2018, 5, 19. [Google Scholar]
- 17.Wang, H.‐M. D., Chen, C.‐C., Huynh, P., Chang, J.‐S., Exploring the potential of using algae in cosmetics. Bioresou. Technol.2015, 184, 355–362. [DOI] [PubMed] [Google Scholar]
- 18.Hellwig, S., Drossard, J., Twyman, R. M., Fischer, R., Plant cell cultures for the production of recombinant proteins. Nat. Biotech.2004, 22, 1415–1422. [DOI] [PubMed] [Google Scholar]
- 19.Yue, W., Ming, Q.‐l., Lin, B., Rahman, K., etal., Medicinal plant cell suspension cultures: pharmaceutical applications and high‐yielding strategies for the desired secondary metabolites. Crit. Rev. Biotechnol.2016, 36, 215–232. [DOI] [PubMed] [Google Scholar]
- 20.Wilson, S. A., Roberts, S. C., Recent advances towards development and commercialization of plant cell culture processes for the synthesis of biomolecules. Plant Biotechnol. J.2012, 10, 249–268. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 21.Jeandet, P., Clément, C., Courot, E., Resveratrol production at large scale using plant cell suspensions. Engineer. Life Sci.2014, 14, 622–632. [Google Scholar]
- 22.Rahpeyma, S.‐A., Moieni, A., Jalali Javaran, M., Paclitaxel production is enhanced in suspension‐cultured hazel (Corylus avellana L.) cells by using a combination of sugar, precursor, and elicitor. Engineer. Life Sci.2015, 15, 234 [Google Scholar]
- 23.Kümmritz, S., Haas, C., Winkler, K., Georgiev, V., etal., Hairy Roots of Salvia Species for Bioactive Substances Production, in: Georgiev V., Pavlov A. (Eds.) Salvia Biotechnology, Springer International Publishing, Cham, 2017, pp. 271–289 ‐242. [Google Scholar]
- 24.D'Amelia, V., Ruggiero, A., Tranchida‐Lombardo, V., Leone, A., etal., Biosynthesis of salvia specialized metabolites and biotechnological approaches to increase their production, in: Georgiev V., Pavlov A. (Eds.) Salvia Biotechnology, Springer International Publishing, Cham, 2017, pp. 241–270. [Google Scholar]
- 25.Savona, M., Barberini, S., Bassolino, L., Mozzanini, E., etal., Strategies for Optimization of the Production of Rosmarinic Acid in Salvia officinalis L. and Salvia dolomitica Codd Biomass with Several Biotechnological Approaches, in: Georgiev V., Pavlov A. (Eds.) Salvia Biotechnology, Springer International Publishing, Cham, 2017, pp. 209–239. [Google Scholar]
- 26.Imseng, N., Schillberg, S., Schürch, C., Schmid, D., etal., Suspension culture of plant cells under heterotrophic conditions, industrial scale suspension culture of living cells, Wiley‐VCH Verlag GmbH & Co. KGaA2014, pp. 224–258. [Google Scholar]
- 27.Ananga, A., Phills, B., Ochieng, J., Georgiev, V., etal., Production of anthocyanins in grape cell cultures: A potential source of raw material for pharmaceutical, food, and cosmetic industries, in: Poljuha D., Sladonja B. (Eds.) The Mediterranean Genetic Code ‐ Grapevine and Olive, INTECH Open Access Publisher; 2013, pp. 247–287. [Google Scholar]
- 28.Trehan, S., Michniak‐Kohn, B., Beri, K., Plant stem cells in cosmetics: current trends and future directions. Future Sci. OA2017, 3, FSO226. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29.Skotnicka‐Graca, U., Plant stem cells as innovation in cosmetics. Acta Poloniae Pharmaceutica2014, 71, 701. [PubMed] [Google Scholar]
- 30.Draelos, Z., Plant stem cells and skin care. Cosmet. Dermatol.2012, 25, 395–396. [Google Scholar]
- 31.Lee, E.‐K., Jin, Y.‐W., Park, J. H., Yoo, Y. M., etal., Cultured cambial meristematic cells as a source of plant natural products. Nat. Biotech.2010, 28, 1213–1217. [DOI] [PubMed] [Google Scholar]
- 32.Ochoa‐Villarreal, M., Howat, S., Jang, M. O., Kim, I. S., etal., Cambial meristematic cells: a platform for the production of plant natural products. New Biotechnol.2015, 32, 581–587. [DOI] [PubMed] [Google Scholar]
- 33.Zhou, P., Yang, J., Zhu, J., He, S., etal., Effects of β‐cyclodextrin and methyl jasmonate on the production of vindoline, catharanthine, and ajmalicine in Catharanthus roseus cambial meristematic cell cultures. Applied Microbiol. Biotechnol.2015, 99, 7035–7045. [DOI] [PubMed] [Google Scholar]
- 34.Steingroewer, J., Bley, T., Georgiev, V., Ivanov, I., etal., Bioprocessing of differentiated plant in vitro systems. Engineering Life Sci.2013, 13, 26–38. [Google Scholar]
- 35.Barbulova, A., Apone, F., Colucci, G., Plant cell cultures as source of cosmetic active ingredients. Cosmetics2014, 1, 94. [Google Scholar]
- 36.Fischer, R., Vasilev, N., Twyman, R. M., Schillberg, S., High‐value products from plants: the challenges of process optimization. Curr. Opin. Biotechnol.2015, 32, 156–162. [DOI] [PubMed] [Google Scholar]
- 37.Meeusen, E. N. T., Walker, J., Peters, A., Pastoret, P.‐P., etal., Current status of veterinary vaccines. Clin. Microbiol. Rev.2007, 20, 489–510. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 38.Ruiz, V., Mozgovoj, M. V., Dus Santos, M. J., Wigdorovitz, A., Plant‐produced viral bovine vaccines: what happened during the last 10 years?Plant Biotechnol.J.2015, 13, 1071–1077. [DOI] [PubMed] [Google Scholar]
- 39.News In Brief. Nat. Biotechnol.2006, 24, 233. [Google Scholar]
- 40.Tremblay, R., Wang, D., Jevnikar, A. M., Ma, S., Tobacco, a highly efficient green bioreactor for production of therapeutic proteins. Biotechnol. Advan.2010, 28, 214–221. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 41.Xu, J., Zhang, N., On the way to commercializing plant cell culture platform for biopharmaceuticals: present status and prospect. Pharmaceut. Bioprocess.2014, 2, 499–518. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 42.Fischer, R., Schillberg, S., Hellwig, S., Twyman, R. M., etal., GMP issues for recombinant plant‐derived pharmaceutical proteins. Biotechnol. Advan.2012, 30, 434–439. [DOI] [PubMed] [Google Scholar]
- 43.Sainsbury, F. and Lomonossoff, G. P., Transient expressions of synthetic biology in plants. Curr. Opin. Plant Biol.2014, 19, 1–7. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 44.Ercetin, T., Senol, F. S., Erdogan Orhan, I., Toker, G., Comparative assessment of antioxidant and cholinesterase inhibitory properties of the marigold extracts from Calendula arvensis L. and Calendula officinalis L., Industrial Crops Products2012, 36, 203–208. [Google Scholar]
- 45.Król, B., Paszko, T., Harvest date as a factor affecting crop yield, oil content and fatty acid composition of the seeds of calendula (Calendula officinalis L.) cultivars. Industrial Crops Products2017, 97, 242–251. [Google Scholar]
- 46.Dulf, F. V., Pamfil, D., Baciu, A. D., Pintea, A., Fatty acid composition of lipids in pot marigold (Calendula officinalis L.) seed genotypes. Chem. Central J.2013, 7, 8‐8. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 47.Pavlov, A., Georgiev, V., Phytochemical composition of Calendula (Calendula officinalis L.) dedifferentiated cell suspension, BG Patent, Utility Model # 2773/26.09.2017, 2017.
- 48.Diniz, R. S., Coimbra, J. S. d. R., Teixeira, Á. V. N. d. C., da Costa, A. R., etal., Production, characterization and foamability of α‐lactalbumin/glycomacropeptide supramolecular structures. Food Res. International2014, 64, 157–165. [DOI] [PubMed] [Google Scholar]