1Research Scholar, Department of Pharmaceutics, Delight College of Pharmacy, Koregaon Bhima, Pune, Maharashtra, India 412216.
2Assistant Professor, Department of Pharmaceutics, Delight College of Pharmacy, Koregaon Bhima, Pune, Maharashtra, India 412216
The present study focuses on the formulation and development of a topical Clindamycin gel intended for the treatment of acne vulgaris. Clindamycin, a lincosamide antibiotic, exhibits potent antibacterial activity against Propionibacterium acnes, a key pathogen involved in acne pathogenesis. A gel formulation was selected due to its superior aesthetic appeal, ease of application, and ability to localize drug delivery at the site of infection. The gel was prepared using Carbopol 940 as the gelling agent, along with propylene glycol as a humectant and penetration enhancer. Methylparaben and propylparaben were incorporated as preservatives, while triethanolamine was used to neutralize the pH and activate the gelling property of Carbopol. The formulation was evaluated for various physicochemical parameters including pH, viscosity, spreadability, drug content, and in vitro drug release. The developed gel exhibited satisfactory physical characteristics, acceptable pH for topical application, and consistent drug content with sustained drug release. This study demonstrates the potential of a Clindamycin topical gel as an effective, stable, and patient compliant therapeutic system for the management of acne.
Acne vulgaris is one of the most common dermatological disorders, affecting millions of individuals worldwide, particularly adolescents and young adults. It is a multifactorial skin disease characterized by inflammation of the pilosebaceous units, leading to the formation of comedones, papules, pustules, and in severe cases, cysts and nodules. The primary causative agent involved in acne pathogenesis is Propionibacterium acnes, an anaerobic Gram-positive bacterium that colonizes the sebaceous follicles. Topical therapy remains the cornerstone for treating mild to moderate acne due to its localized action, reduced systemic side effects, and improved patient compliance. Among the various topical agents, Clindamycin—a lincosamide antibiotic—has proven effective in suppressing P. acnes by inhibiting bacterial protein synthesis through binding to the 50S ribosomal subunit. Formulating Clindamycin into a topical gel provides several advantages over other dosage forms such as creams or lotions. Gels are non-greasy, have a cooling effect upon application, and allow for better drug penetration through the skin. Moreover, they offer good spreadability, patient acceptability, and controlled drug release. The current study aims to formulate a stable and effective Clindamycin gel using Carbopol 940 as the gelling agent, along with other excipients to enhance stability, skin penetration, and antimicrobial efficacy. The formulation is evaluated for key parameters such as pH, viscosity, drug content, spread ability, and in vitro drug release to ensure optimal therapeutic performance.
Profile of Formulation Ingredients4:
Clindamycin Phosphate
Role: Active Pharmaceutical Ingredient (API)
Function: Lincosamide antibiotic; inhibits protein synthesis in Cutibacterium acnes. Provides antimicrobial and anti-inflammatory action for acne treatment.
Concentration: Typically, 1% or 2% in the gel formulation, depending on the product.
2. Purified Water
Role
Function: Acts as the main solvent and carrier for all water-soluble ingredients. Ensures the formulation is smooth, stable, and skin compatible.
Concentration: Usually, a significant part of the formulation (often 60 80%)
3.Glycerin
Role: Humectant / Moisturizer
Function: Retains moisture on the skin and prevents dryness. Enhances skin feel and helps balance the drying effect of ethanol and carbomer.
4.Propylene Glycol
Role: Penetration Enhancer / Humectant
Function: Enhances percutaneous absorption of clindamycin. Also acts as a solvent and moisturizer, improving skin hydration.
5.Carbomer 940 Role: Gelling Agent
Function: Provides gel structure and viscosity. Ensures uniform distribution of the API and improves spread ability.
6. Triethanolamine
Role: pH Adjuster / Neutralizer
Function: Used to neutralize the acidic carbomer, forming the gel matrix. Also helps maintain formulation pH within a skin compatible range (≈5.5–6.5)
7.Methylparaben
Role: Preservative
Function: Prevents microbial growth in the formulation, enhancing product stability and safety during storage and use.
8. Ethanol
Role: Antiseptic solvent
Function: Ethanol acts as a solvent, helping to dissolve clindamycin phosphate and other ingredients to form a stable and uniform gel.
1. Clindamycin Phosphate
Role: Active Pharmaceutical Ingredient (API)
Function: Lacosamide antibiotic; inhibits protein synthesis in Cutibacterium acnes. Provides antimicrobial and anti-inflammatory action for acne treatment.
Concentration: Typically, 1% or 2% in the gel formulation, depending on the product.
2. Purified Water
Role: Solvent & Base
Function: Acts as the main solvent and carrier for all water-soluble ingredients. Ensures the formulation is smooth, stable, and skin compatible.
Concentration: Usually, a significant part of the formulation (often 60 80%).
3. Glycerine
Role: Humectant / Moisturizer
Function: Retains moisture on the skin and prevents dryness. Enhances skin feel and helps balance the drying effect of ethanol and carbomer.
4. Propylene Glycol
Role: Penetration Enhancer / Humectant
Function: Enhances percutaneous absorption of clindamycin. Also acts as a solvent and moisturizer, improving skin hydration.
5. Carbomer 940
Role: Gelling Agent
Function: Provides gel structure and viscosity. Ensures uniform distribution of the API and improves spread ability.
6. Triethanolamine
Role: pH Adjuster / Neutralizer
Function: Used to neutralize the acidic carbomer, forming the gel matrix. Also helps maintain formulation pH within a skin compatible range (≈5.5–6.5).
7. Methylparaben
Role: Preservative
Function: Prevents microbial growth in the formulation, enhancing product stability and safety during storage and use.
8. Ethanol
Role: Antiseptic Solvent
Function: Acts as a solvent, helping to dissolve clindamycin phosphate and other ingredients to form a stable and uniform gel.
EXPERIMENTAL WORK:
Carbopol 940 was used as the gelling agent, dispersed in purified water and allowed to swell for several hours to form the gel base.
Clindamycin phosphate was dissolved in water and incorporated into the gel base along with preservatives (methylparaben and propylparaben) dissolved in propylene glycol. The gel was neutralized using triethanolamine to adjust the pH to 5.5–6.0, which activated gel formation. The final gel was evaluated for pH, viscosity, spreadability, drug content, and in vitro drug release using standard methods. Stability studies were conducted at different storage conditions to assess the formulation's physical and chemical stability over time.
METHODOLOGY:
The chemical and reagents apply from Delight college of pharmacy Koregaon Bhima, Pune. Maharashtra, India 412216.
|
S. No. |
Ingredients |
Quantity (per 30 g) |
Purpose |
|
1 |
Clindamycin Phosphate |
0.3 g |
Active pharmaceutical ingredient (API); anti-acne |
|
2 |
Glycerin
|
3g (Typically 10% of the total gel weight). |
Humectant |
|
3 |
Propylene Glycol |
2gm |
Solvent; penetration enhancer |
|
4 |
Carbomer (e.g., Carbomer 934) |
0.6g |
Thickener to provide the gel's consistency. |
|
5 |
Triethanolamine |
0.3g |
pH adjuster (neutralizes the carbomer and thickens the gel). |
|
6 |
Methylparaben |
0.15g (Typically 0.5% of the gel weight). |
Preservative to prevent microbial growth. |
|
7 |
Ethanol |
2.4g |
Solvent and enhances the gel's penetration on the skin. |
|
8 |
Purified Water |
21.95g |
Solvent to dissolve and mix all ingredients. |
1. Preparation of Active Ingredient Solution:
2. Gel Base Preparation:
3. Addition of Humectants and Solvents:
4. pH Adjustment and Neutralization:
5. Preservation and Final Mixing:
OBSERVATION:
1. Colour: The appearance of the gel should be aesthetically acceptable. The colour may vary from slightly cloudy to clear depending on the presence and concentration of ethanol in the formulation.
Procedure: Visually inspect a small amount of gel against a white background under natural or white light to observe its clarity and colour.
2. Odor: The gel should possess a mild and pleasant odor. If ethanol is used, an alcohol like Odor may be present, which is acceptable.
Procedure: Take a small quantity of the gel on a spatula and gently smell it to evaluate the presence of any characteristic or unpleasant odor.
3. Consistency: A good gel should have a uniform and semi solid consistency that is easy to apply and spread over the skin surface.
Procedure: Check the gel manually by pressing a small quantity between the fingers to assess its smoothness, uniformity, and feel.
4. PH: The pH of the gel should be compatible with the skin (between 6.5 to 7.0) to avoid irritation upon application.
Figure 1: PH Meter
Procedure:
1. Dissolve 1g of the gel in 10 ml of distilled water.
2. Measure the pH using a calibrated digital pH meter.
5. Spreadability
Theory: This test ensures how easily the gel spreads on the skin, which affects patient compliance and drug delivery.
Spread ability (gm./s) = M×L/T
Where:
M = Weight in grams
L = Length the slide moved (in cm)
T = Time in seconds
Procedure:
1. Place a small quantity of gel between two glass slides.
2.Apply a weight (usually 500g) on the top slide for 1 minute.
3. Measure the diameter of the spread gel area or note the time taken for the top slide to slip off.
6. Drug Solubility: The active ingredient (Diclofenac Sodium) must be fully dissolved in the gel base to ensure uniform distribution and efficacy.
Procedure:
1. Visually inspect for any undissolved particles.
Optionally, analyse using UV spectrophotometry to confirm drug solubility in the formulation.
7. Viscosity: Viscosity determines the flow properties and stability of the gel. An ideal gel should have adequate viscosity for proper application and retention.
Figure 3: Brookfield Viscometer
Procedure:
8. Simple Diffusion Test for Diclofenac Gel
MATERIALS:
1. clindamycin gel
2. Franz diffusion cell (or small glass setup)
3.Dialysis membrane or cling film
4. Warm water (37°C)
5. Phosphate buffered saline (PBS)
Figure 4: Franz Cell Diffusion Apparatus
Steps:
1. Prepare Membrane: Soak membrane in warm PBS for 10 minutes.
2. Set Up Cell: Place membrane between two compartments:
1. Top (Donor): Apply 1g diclofenac gel
2. Bottom (Receptor): Fill with PBS
3. Keep Warm & Stir: Keep setup at 37°C and stir the PBS.
4. Sample at Times: Every 30 mins, take a few drops from PBS below.
RESULT:
The Clindamycin gel prepared for topical application exhibited a clear, smooth, and homogeneous appearance, with no visible separation or clumping, indicating proper formulation. The pH of the gel was found to be 5.7, which is within the optimal range of 5.5–6.0, ensuring skin compatibility and minimizing potential irritation. The viscosity of the gel, measured at approximately 2500 cps, demonstrated the gel's ideal consistency—neither too thick nor too runny—making it easy to apply with good spreadability. The spreadability of the gel was assessed and found to be 4.2 cm, indicating that the gel can cover a large surface area with minimal effort, which is desirable for topical applications. The drug content uniformity test revealed that Clindamycin was uniformly distributed in the gel, with the drug content being 98% of the labeled claim, ensuring accurate dosing with each application. In vitro drug release studies, conducted using a Franz diffusion cell, showed a sustained release of Clindamycin over a 12-hour period, with approximately 75% of the drug released within the first 6 hours. This sustained release suggests that the gel provides prolonged therapeutic effects, suitable for acne treatment. Finally, the gel formulation underwent stability studies under accelerated conditions (40°C/75% RH) for 3 months. No significant changes were observed in the appearance, pH, viscosity, or drug content, indicating that the gel is stable and retains its effectiveness over time.
SUMMARY AND CONCLUSION:
The Clindamycin gel was successfully formulated using Clindamycin phosphate as the active pharmaceutical ingredient, combined with Carbomer 934 as a thickening agent, and other excipients including Glycerin, Propylene Glycol, Triethanolamine, Methylparaben, Ethanol, and Purified Water. The gel was evaluated for its appearance, pH, viscosity, spreadability, drug content uniformity, and in vitro drug release. The gel demonstrated clear, smooth, and homogeneous characteristics, with a pH of 5.7, which is suitable for skin application. The viscosity and spreadability tests indicated that the gel had the appropriate thickness and could be easily spread over the skin. The drug content was uniform, with 98% of the labeled Clindamycin content. The in vitro drug release study revealed a sustained release profile, indicating prolonged therapeutic action over 12 hours. Stability studies confirmed that the gel remained stable without significant changes in appearance, pH, or drug content over three months under accelerated conditions.
CONCLUSION
The formulated Clindamycin gel meets the required physicochemical properties for an effective topical treatment for acne. The gel exhibits optimal pH, viscosity, and spreadability, ensuring ease of application and skin compatibility. The sustained release of Clindamycin indicates that the gel can provide prolonged therapeutic effects, making it suitable for acne management. The uniform distribution of the active ingredient and the results of stability studies suggest that the gel is both effective and stable over time. Thus, the formulation can be considered a promising candidate for further development and potential clinical use in acne treatment.
REFERENCE
Deshmukh Ajinkya*, Dr. Priti Shinde, Formulation and Evalution of Clindamycin Gel, Int. J. Sci. R. Tech., 2025, 2 (5), 665-672. https://doi.org/10.5281/zenodo.15564901
10.5281/zenodo.15564901
