2 3 A B C D E F G H I J K L M N O P Q R S T V W

Claims on microcirculation

Claims on microcirculation

Introduction

In cosmetics, the efficacy of products plays a crucial role. An innovative approach to evaluating this efficacy is to measure the microcirculation in the skin. Claims on microcirculation can help manufacturers to validate the benefits of their products and market them more effectively. In this blog post, we explain the methods and the principle of microcirculation measurement, possible claims that can be supported by this method and its significance for the cosmetics industry.

 

Method of microcirculation measurement

Microcirculation measurement is performed by various non-invasive techniques that monitor blood flow in the smallest blood vessels of the skin. Commonly used methods are:

Laser Doppler Flowmetry (LDF): This technique measures the speed and volume of blood flow by scattering laser light.
Laser Doppler Imaging (LDI): Similar to LDF, but with visualisation of blood flow in a larger area of skin.
Optical coherence tomography (OCT): Uses light waves to create high-resolution images of skin structures and microcirculation.
Capillaroscopy: A method for examining the smallest blood vessels (capillaries) in the skin using a microscope.

The application of these techniques allows detailed and precise data on microcirculation to be obtained, which can serve as the basis for scientifically substantiated claims on microcirculation.

 

How microcirculation works

Microcirculation is essential for supplying the skin with oxygen and nutrients and for removing metabolic waste products. Improved microcirculation can significantly improve the health and function of the skin. Cosmetic products that promote microcirculation can offer the following benefits:

Increased nutrient supply: Improved blood circulation enables more efficient supply of important nutrients to skin cells.
Better oxygen supply: This leads to healthier and more radiant skin.
Accelerated regeneration: Good microcirculation supports the skin’s repair processes and accelerates wound healing.
Swelling and inflammation are reduced: By improving the removal of waste products and excess fluid.

 

Possible claims on microcirculation

The use of microcirculation measurements enables cosmetics manufacturers to formulate specific claims for their products. Here are some examples of claims on microcirculation:

Increased firmness of the skin: Products that promote microcirculation can help to firm and tighten the skin.
Improved complexion: Increased blood flow can even out the complexion and give a more radiant appearance.
Less swelling: Products can reduce swelling and dark circles under the eyes by improving the drainage of fluid.
Promotes skin regeneration: By supporting the natural repair processes, the skin can regenerate more quickly.
Reduced signs of fatigue: Improved microcirculation can reduce signs of fatigue and give the skin a fresher appearance.
Increased absorption of active ingredients: Improved blood flow can improve the absorption and effectiveness of other active ingredients in skin care products.
Studies on microcirculation in cosmetics

A special study to measure microcirculation was conducted with 31 test subjects who used a cream formulation. The results showed a significant improvement in microcirculation and associated benefits for the skin. This study highlights the importance of microcirculation for skin health and provides a solid basis for claims on microcirculation.

 

Cosmetics and microcirculation

There are several cosmetic products that have been specifically developed to promote microcirculation:

Serums with blood flow-enhancing ingredients: These products contain active ingredients such as ginseng, caffeine or niacinamide that stimulate blood flow.
Creams and lotions: Formulations with ingredients that promote microcirculation can help to improve skin health and reduce signs of aging.
Masks and scrubs: These products can improve microcirculation through mechanical stimulation or active ingredients such as AHA and BHA.

 

Supplement: Information on the Chemicos measurement method

The Chemicos measurement method is an advanced technique for assessing microcirculation in the skin. This method uses special sensors and optical technologies to monitor blood flow in real time. By applying this technique, detailed data on microcirculation can be obtained, which enables precise and reliable claims on microcirculation. Chemicos provides a solid basis for scientifically substantiated advertising claims and helps to strengthen consumer confidence in the efficacy of cosmetic products.

 

Conclusion

Claims on microcirculation provide a valuable opportunity to scientifically substantiate and market the efficacy of cosmetic products. By measuring microcirculation, manufacturers can highlight specific benefits of their products and strengthen their position in the market. Improved microcirculation can lead to healthier, more radiant skin and offer numerous cosmetic benefits.
Cosmacon is happy to help you market your products by providing support for claims on microcirculation based on testing at our partner test institutes.

 

Literature:

Effects of Fluids on the Macro- and Microcirculations.

Bennett VA, Vidouris A, Cecconi M.Crit Care. 2018 Mar 20;22(1):74

Changes in Skin Microcirculation Resulting from Vibration Therapy in Women with Cellulite.

Piotrowska A, Czerwińska-Ledwig O, Stefańska M, Pałka T, Maciejczyk M, Bujas P, Bawelski M, Ridan T, Żychowska M, Sadowska-Krępa E, Dębiec-Bąk A.Int J Environ Res Public Health. 2022 Mar 13;19(6):3385

Protective Role of Nutritional Plants Containing Flavonoids in Hair Follicle Disruption: A Review.

Bassino E, Gasparri F, Munaron L.Int J Mol Sci. 2020 Jan 14;21(2):523

Current methods for the assessment of skin microcirculation: Part 1.

Neubauer-Geryk J, Hoffmann M, Wielicka M, Piec K, Kozera G, Brzeziński M, Bieniaszewski L.Postepy Dermatol Alergol. 2019 Jun;36(3):247-254

Current methods for the assessment of skin microcirculation: Part 2.

Neubauer-Geryk J, Hoffmann M, Wielicka M, Piec K, Kozera G, Bieniaszewski L.Postepy Dermatol Alergol. 2019 Aug;36(4):377-381.