BIOACTIVE BOTANICAL COMPOSITIONS AN

BIOACTIVE BOTANICAL COMPOSITIONS AND USES THEREOF


Field of the การประดิษฐ์
The การประดิษฐ์นี้ relates to compositions and methods for mitigating 5 inflammation and irritation induced by surface active สารประกอบ.


Background of the การประดิษฐ์
Surface Active สารประกอบ are substances that can decrease the surface tension or
interfacial tension of a liquid when dissolved in it. Most commonly this refers to water and its 10 interfaces with air, solid surfaces, and other substances. While any solute can change the
properties of a solution, certain สารประกอบ especially effective at this are called surfactants.
This effectiveness is the result of an amphiphilic structure that includes a hydrophobic part,
commonly ประกอบรวมด้วยd of one or two hydrocarbon "tails"; and hydrophilic "head" part, which
may be negatively charged (anionic surfactants), positively charged (cationic surfactants),
15 lack a charge (nonionic surfactants), or have both positively and negatively charged groups
within head structure (amphoteric or zwitterionic surfactants).


Some examples of surfactants belonging to these groups would be:

• Anionic
20 o Sodium Dodecyl Sulfate (SDS)
o Sodium Olefin Sulphonate
• Cationic
o Cetrimonium Bromide (or hexadecyltrimethylammonium bromide)
o Mono Alkyl Quat
25 o C12-C18 Ethoxylated Amine
• Nonionic
o Octyl Phenol Ethoxylate
o Ethoxylated Alcohol
• Zwitterionic/Amphoteric
30 o Cocamidopropyl betaine
o Coco Ampho Poly Carboxyglycinate
Amphiphilic structure allows surfactant molecules to aggregate and orient themselves
at the interfacial boundaries, form complex arrangements, increase the wetting ability of
solutions, allow suspension of hydrophobic substances, and interact with arrangements
35 formed by other amphiphilic substances.


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A biologically important example of such an arrangement is the plasma membrane of
a living cell and organelles, which is a bi-layer structure formed by two layers of oriented
phospholipids, with inner side of the membrane being the hydrophobic "tails" facing each 5 other and outer sides facing the intracellular and extracellular medium being the hydrophilic
"heads". Other components important for cell function are embedded in or attached to the
plasma membrane.


Health and viability of living tissues strongly depends on properties of the
10 surrounding medium and on integrity of the plasma membranes of the cells of the tissue.
Introduction of a surfactant can alter the properties of the medium such as surface tension
and impact the plasma membrane stability by increasing its permeability, or otherwise
damaging it. Introduced surfactants can also interact with other plasma membrane
components. Undesirable effects of surfactants on living tissues can cause complex
15 biological responses such as inflammation and irritation.


In the past, many attempts have been made to reduce surfactant-induced skin
irritation and inflammation by selecting less-irritating surfactants, blocking skin contact by
occlusive films, reducing the critical micelle concentration of detergent to limit the exposure 20 of skin to free surfactant monomers, or adding enzymes and conventional plant extracts to
promote skin exfoliation and skin cell renewal. However, surfactant-induced skin irritation
and inflammation are still one of the major concerns of the consumers. As surfactants have a
great variety of industrial, scientific and household uses to allow or improve processes of
wetting, emulsifying and solubilizing, cleaning, foaming, and dispersing.
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Therefore, human contact with surfactants is a frequent occurrence, and mitigating harmful effects of such contact is desirable.
Inflammation is a complex cascade of biological reactions mediated by signaling 30 substances ที่รวมถึง, but not limited to vasoactive amines such as histamine, products of
arachidonic acid metabolism such as prostaglandins, and signaling proteins such as
chemokines and interleukins in particular. Certain signaling molecules are particularly
important in regulating the inflammation and quantification of inflammatory activity due to
factors ที่รวมถึง but not limited to their position in inflammatory signaling cascades,
35 broadness of their range of pro-inflammatory effects, and comparative efficacy at triggering
the inflammatory responses. An example of such a cascade is provided in Figure 1.


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One of the methods of studying and quantifying such inflammation is by culturing
cells of the tissue most likely to come in contact with surfactants, such as viable
keratinocytes from the epidermis. These cultured cells could be subjected to stresses and
treatments, and levels of released substances associated with inflammatory signaling or
5 cellular damage could be determined by means of various bioassays. The skin keratinocytes
have become the focus of attention in irritant-induced skin inflammation by virtue of their
epidermal location, their importance in maintaining the integrity of the stratum corneum
barrier, and their ability to produce a range of inflammatory mediators. Keratinocytes contain
large quantities of biologically active Interleukin (IL)-1a, which can be released in response 10 to a range of irritants, such as surfactants. IL-1 a is one of the primary cytokines, which can
be induced by irritants, and is often released from keratinocytes at the early stage of
inflammation cascade. Subsequently, IL-1a leads to the induction of numerous down-stream
inflammatory mediators, e.g. signaling molecules, cytokines, and chemokine IL-8, which is
known as neutrophil chemotactic factor. IL-8 is important for the recruitment of leukocytes to 15 damaged skin and for the development of the signs of skin inflammation. Therefore, by
reducing secretion of IL-1a and IL-8 from keratinocytes, an initial inflammatory response
mediator and a key chemotactic factor, the signs of the skin inflammation may be reduced,
prevented, and/or eliminated.