Extraction, Characterization, Interpretation of Natural Dyes with its Application and Degradation Studies

Soumallya Chakraborty; Somenath Bhattacharya; Amit Maity; Sonia Samanta; Koushik Jana; Anirban Ghosh

doi:10.5281/zenodo.20329596

Research Paper | Open Access
Volume 04 | Issue 05 | Article Id IJPS/260404904

Extraction, Characterization, Interpretation of Natural Dyes with its Application and Degradation Studies
Soumallya Chakraborty* Somenath Bhattacharya Amit Maity Sonia Samanta Koushik Jana Anirban Ghosh
Global College of Pharmaceutical Technology, Nadia, West Bengal, India

Abstract

Natural dyes have emerged as promising sustainable alternatives to synthetic colourants, necessitating a deeper investigation into their physicochemical properties and environmental behaviour. This study explores the systematic extraction, characterization, application, and degradation kinetics of bio-derived dyes from selected plant matrices. Extraction efficiency was optimized using solvent polarity variation, pH control, and temperature modulation to enhance pigment yield and stability, Structural and functional characterization was carried out using UV–Visible spectroscopy, and chromatographic techniques to identify chromophores, auxochromes, and molecular interactions governing colour properties. Dyeing performance was evaluated on cellulose and protein-based fibres under varying mordanting conditions, with emphasis on adsorption behaviour, binding mechanisms, and fastness properties.Degradation studies were conducted under controlled photolytic, thermal, and biodegradative conditions. Kinetic modelling suggested that dye degradation predominantly follows pseudo-first-order reaction pathways, influenced by environmental parameters such as light intensity, oxygen availability, and pH. The results indicate a trade-off between ecological degradability and functional durability. This work provides critical insights into the structure–property–degradation relationship of natural dyes, offering a scientific basis for improving their applicability in sustainable textile and material engineering.

Keywords

Natural dyes, Coton fabric, Phytochemical, Mordant, IR

Introduction

Natural dye refers to a colouring substance obtained from natural sources, especially plants, which is used in the study and evaluation of crude drugs.These dyes occur in various plant parts such as roots, leaves, bark, and flowers, and contain phytochemicals like flavonoids, tannins, curcumin, and anthocyanins. They are useful for identification purposes and may also be used in herbal formulations ^1-5.

Natural dyes are preferred because they are non-toxic, biodegradable, and compatible with herbal drugs, making them safer than synthetic colouring agents.

Natural dyes are generally known as colorants and mostly founds from different plants parts like root (turmeric, beet), leaves (indigo, tea), bark (alder), fruits/seed (pomegranate, berries, coriander), flowers (marigold). Different types of insects like cochineal or lac produce natural dye vibrant red while minerals like ochre also provide earth tones ^6-11.

Importance of Natural Dyes:

Natural dyes are important in the pharmaceutical field due to their safety, low toxicity, and biodegradable nature. They are used as indicators to monitor pH changes during drug formulation and quality testing.

These dyes are also applied as colouring agents in medicines, improving appearance and patient acceptance. Being naturally derived, they reduce the risk of harmful side effects compared to synthetic dyes.

In addition, natural dyes are cost-effective and easily available, making them useful in basic testing and in areas with limited resources. However, their use is limited in advanced applications due to lower stability and precision ¹¹.

ADVANTAGES& DISADVANTAGES:

Table-1: Advantages and Disadvantages of Natural dyes ^{12, 13}

ADVANTAGES	DISADVANTAGES
Eco-Friendly and Sustainable: These dyes are biodegradable and renewable, causing significantly less environmental pollution compared to petroleum-based synthetic dyes.	Consistency and Standardisation: It is difficult to reproduces identical because the pigment concentration in plants varies based on soil, climate, and harvest time.
Health and Safety: They aregenerally non-toxic and non-allergenic, making them safe for skin contact. Many herbal dyes, like those containing anthocyanins, even possess antioxidant, antimicrobial, and anti-inflammatory properties.	Higher Production Costs: The extraction process is often expensive and time consuming, requiring large amounts of raw plant material to yield a relatively small amount of pigment.
UV Protection: Some plant-based dyes provide natural ultraviolet (UV) protection for the fabrics they colour.	Limited Colour Spectrum: While natural dyes offer rare shades, they have a limited overall colour band compared to the virtually infinite variety available from synthetic sources.

Natural dyes are collected from different plants parts. Natural dyes are biodegradable, harmless and friendly with environment in contrast with synthetic dyes. In this research we collect dyes from different plant sources like Thea sinensis (Tea), Curcuma longa (Turmeric), Beta vulgaris (Beet Root), Coriandrum sativum (Coriander) ¹¹.

Table-2: Introduction about selected plant

Name of Plant	Biological Source	Geographical source	Plant parts used	Picture
Tea ¹⁴	Thea sinensis Family-Theaceae	China, India, Kenya, and Sri Lanka	Leaves
Turmeric ¹⁵	Curcuma longa Family-Zingiberaceae	India, Vietnam, China, Myanmar	Rhizomes
Beetroot ¹⁶	Beta vulgaris Family-Amaranthaceae	Russia, France, United state, Germany	Roots
Coriander ¹⁷	Coriandrum sativum Family-Apiaceae	India, Morocco, Canada, Russia, Romania	Leaf

Four plant sources were selected for extraction of natural dyes based on their colour properties. Tea and coriander were selected for brown and green shades respectively, while turmeric and beetroot were chosen for yellow and red colours. Fresh plant materials were collected from local sources and cleaned thoroughly with tap water before use.

Table-3: Chemical constituents and extract colour of selected plant

Sr. No	Plant name	Chemical Constituents	Colour	Pictures
1.	Tea ¹⁴	Catechins, flavanols, Caffeine, theobromine, theophylline.	Brown
2.	Turmeric ¹⁵	α-phellandrene, zingiberene, sabinene, cineol, and sesquiterpenoids, Curcumin	Yellow
3.	Beetroot ¹⁶	Betacyanin and Betaxanthins, Phenolic acids and flavonoids.	Red
4.	Coriander ¹⁷	Linalool, pinene, -terpinene, camphor, and geraniol, Polyphenols, Flavonoids	Green

MATERIAL AND METHODS:

Chemicals, Instruments and Equipment

Chemicals:

Distilled water, sodium hydroxide, copper sulphate, Sulphuric acid, Ferrous Sulphate, Chloroform, Boric Acid, Molisch reagent

Instruments:

Analytical balance was used for accurate weighing of plant materials. A centrifuge and filtration setup were used for separation of extracts. IR spectrophotometer was used for characterization studies.

Equipment:

Laboratory equipment such as beakers, conical flasks, test tubes, measuring cylinders, mortar and pestle, blender, pipettes, petri dishes, and glass rods were used. Water bath was used for extraction, and filter paper was used for filtration.

Collection of Plant Materials

Plant materials such as tea, turmeric, beetroot and coriander were selected based on their natural colouring properties. The samples were collected from local markets and nearby areas. All materials were properly identified and cleaned to remove dust and impurities.

Drying of Plant Materials

They were then cut into small pieces and dried under shade at room temperature to preserve their chemical constituents. Direct sunlight was avoided to prevent degradation of active compounds. The drying process was continued until the materials became completely moisture-free, after which they were stored in clean, dry containers for further use.

Extraction of Natural Dyes:

Collect 50 gm plant materials by using a digital balance. The chopped plant materials were dipped in 200 ml of distilled water in a beaker and heated at a temperature range of 35-40°C until the dye was released. The dye from aqueous extraction was filtered through sieve, then container of hot extractive was kept in cold water.

Figure no-1: Extraction of different Plants

RESULT AND DISCUSSION

The extracted dyes showed a good colour-imparting ability and were of the desirable consistency.

Screening of those extracted components:

Sr. No	Plant name	Procedure for Chemical test	Results	Pictures
1.	Tea ¹⁴	Black tea extract mixed with chloroform and evaporated, then treated withconcentrated H₂SO₄ and warmed	Produces a greyish colour, confirming the presence of terpenoids. A= Seed extract B= reagent C= Observed result
2.	Turmeric ¹⁵	Boric Acid Test: Small amount of turmeric extract treated with boric acid	A reddish-brown colour indicates the presence of Curcumin. A= Seed extract B= reagent C= Observed result
3.	Beet Root¹⁶	A few drops of Molisch reagent (????-naphthol in ethanol) are added to a beetroot extract, followed by slow addition of concentrated sulfuric acid	A purple or red-violet ring at the interface indicatespresence of all carbohydrates. A= Seed extract B= reagent C= Observed result
4.	Coriander ¹⁷	1 mL of the extract is treated with 1 ml of 10% Sodium Hydroxide (NaOH).	The development of a yellow color or fluorescence indicates the presence of coumarins. A= Seed extract B= reagent C= Observed result

Different Chemical Test of Extract:

Table-4: Different Chemical Test of Extract

Name	Tea	Turmeric	Beetroot	Coriander
Protein	-	+	+	+
Carbohydrates	+	+	+	+
Flavonoids	+	+	+	+
Glycosides	+	+	+	+
Terpenoids	+	+	-	+
Saponins	+	+	+	+
Phenols	+	+	+	+
Tannins	+	+	-	+
Quinones	-	+	+	-
Coumarin	-	-	-	+
‘+’ = Indicates presence ‘ - ’ = Indicates absence

Characterization of Dyes: Using FT-IR Spectrum

Fourier Transform Infrared Spectroscopy (FT-IR) is an important analytical technique used for the characterization of dyes. It helps in identifying the different functional groups present in the dye molecules by measuring the absorption of infrared radiation at various wavelengths. This method is widely used for both natural and synthetic dyes to understand their chemical structure and confirm the presence of specific bonding groups. FT-IR is commonly used in dye research to detect groups such as hydroxyl, carbonyl, amino, and aromatic compounds.

In FT-IR analysis, a small amount of the extracted dye sample is placed in the instrument, and infrared light is passed through it. Different chemical bonds absorb IR radiation at characteristic frequencies, producing a spectrum in the range of 4000–400 cm?¹. The obtained spectrum acts like a fingerprint of the dye compound, which helps in determining its molecular composition.

Figure no-2: IR Spectrum (Tea)

Figure no-3: IR Spectrum (Turmeric)

Figure no-4: IR Spectrum (Beetroot)

Figure no 5: IR Spectrum (Coriander)

Application of Dyes to Fabrics:

The dye is applied to fabric by two methods

Without Mordant
With mordant

Mordant:

Copper Sulphate (CuSO₄): 0.05 g of Copper Sulphate was dissolved in 50 mL of distilled water.
Ferrous Sulphate (FeSO₄): 0.05 g of Ferrous Sulphate was dissolved in 50 mL of distilled water.

Figure-6: Extract plant with CuSO₄ Figure-7: Extract plant with FeSO₄

Comparison of colour in paper with and without mordant:

Table-5: Comparison of colour in paper with and without mordant

Aspect	Without Mordant	With copper sulphate	With ferrous sulphate
Colour intensity	Light	Brighter, often greenish or bluish	Darker, reddish or earthy
Colour fastness	Poor	Moderate	High
Durability	Low	Improve wash and light resistant	Strong resistance to fading

Application of dyes in cotton:

The stability, colour, and functionalitycontaining natural dyes were greatly impacted by the storage temperature. It was discovered that the manufactured remained stable for up to four weeks when stored at room temperature and 4 ° C. They added an intense colour and had a decent consistency. Additionally, because the dyes were made with only natural chemicals, they left the skin feeling calm and refreshed. The stability and shelf life of natural dyes depends on several factors, including the type of dye, exposure to environmental elements.

Figure - 8: Using different plant dyes in filter paper without, CuSO4, FeSO4 mordants

Table-6: Application of selected natural plants

Sr. no	Plant name	Application
1	Tea	Textile dyeing of cotton, silk, and wool fabrics Paper staining and antique effect in craft work Used in handmade eco-friendly fabrics
2	turmeric	Food colouring agent in snacks, rice, curry, and sweets Cosmetic products such as herbal face packs and soaps Medicinal textiles and Ayurvedic cloth
3	Beetroot	Dyeing cotton and wool fabrics Natural food colouring in juices, ice cream, cakes, and candies Used for herbal colours during festivals
4	Coriander	Food decoration and natural colouring Herbal cosmetic products Used in experimental natural dye projects

Degradation rates factor of selected natural dyes:

Natural dyes obtained from plants gradually lose their colour strength due to different environmental and chemical factors. This process is called degradation. The stability of the dye depends on the nature of the pigment present in each plant source.

Table-7: Degradation rates factor of selected natural dyes

Factor	Tea	Turmeric	Beetroot	Coriander
Light sensitivity	Medium	High	High	High
Heat sensitivity	Medium	Medium	High	High
pH sensitivity	Low	High	High	Medium
Oxidation	Medium	Medium	High	High

CONCLUSION:

It is concluded that natural dyes obtained from plant sources such as tea, turmeric, beetroot, and coriander are valuable eco-friendly alternatives to synthetic dyes. The extraction process helps in isolating useful colouring pigments from plant materials, while characterization techniques such as FT-IR assist in identifying their chemical nature and functional groups. These dyes have wide applications in textile colouring, handicrafts, cosmetics, and food-related products because of their non-toxic and biodegradable properties. However, their degradation rate depends on factors like light, temperature, pH, and oxidation, which may affect colour stability over time. Overall, natural dyes are safe, sustainable, and environmentally beneficial for various practical uses.

ACKNOWLEDGEMENT:

We would like to thank our college Global College of Pharmaceutical Technology for giving us the opportunities to perform this research work.

CONFLICT OF INTEREST: None

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