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Analytical Chemistry Lab Experiments
Master advanced analytical chemistry techniques with our comprehensive laboratory guide. Discover proven methods for food analysis, pharmaceutical testing, and forensic chemistry that deliver accurate results.
Advanced Analytical Chemistry Lab Experiments
Determination of Fat Content in Milk
Chemicals: Concentrated H₂SO₄, Amyl alcohol, Butyrometer
Apparatus: Gerber butyrometer, Centrifuge, Water bath
Procedure: Add 10ml H₂SO₄ to butyrometer, carefully add 11ml milk sample, add 1ml amyl alcohol. Centrifuge at 1100 rpm for 5 minutes at 65°C.
Calculation Formula:
Fat % = (Reading on butyrometer scale × 100) / Volume of milk sample
Sample Problem:
If the butyrometer reading is 3.2 for 11ml milk sample, calculate fat percentage.
Solution: Fat % = (3.2 × 100) / 11 = 29.09%
Quantification of Proteins (Lowry Method)
Chemicals: Folin-Ciocalteu reagent, Copper sulfate, Sodium carbonate, BSA standard
Apparatus: Spectrophotometer, Test tubes, Pipettes, Vortex mixer
Procedure: Prepare protein standards (0-100 μg/ml BSA). Add Lowry reagent, incubate 10 min. Add Folin reagent, measure absorbance at 750nm after 30 min.
Calculation Formula:
Protein concentration = (Absorbance – y-intercept) / Slope × Dilution factor
Sample Problem:
Sample absorbance = 0.45, Standard curve: y = 0.008x + 0.02, Dilution = 1:10
Solution: Protein = (0.45 – 0.02) / 0.008 × 10 = 537.5 μg/ml
Determination of Cholesterol in Food
Chemicals: Chloroform, Methanol, Cholesterol oxidase, Peroxidase, ABTS
Apparatus: Homogenizer, Separatory funnel, Rotary evaporator, UV-Vis spectrophotometer
Procedure: Extract lipids using Folch method. Saponify with KOH. Extract unsaponifiable matter. Analyze using enzymatic method at 405nm.
Calculation Formula:
Cholesterol (mg/100g) = (Absorbance × Standard factor × Volume) / Sample weight
Sample Problem:
Absorbance = 0.32, Standard factor = 0.156, Volume = 25ml, Sample = 5g
Solution: Cholesterol = (0.32 × 0.156 × 25) / 5 = 0.25 mg/100g
Quantification of Reducing Sugars (DNS Method)
Chemicals: DNS reagent, Glucose standards, Sodium potassium tartrate
Apparatus: Water bath, Spectrophotometer, Test tubes, Pipettes
Procedure: Mix sample with DNS reagent. Heat in boiling water bath for 5 minutes. Cool and measure absorbance at 540nm.
Calculation Formula:
Sugar concentration = (Absorbance – intercept) / Slope × Dilution factor
Sample Problem:
Absorbance = 0.68, Calibration: y = 1.2x + 0.05, Dilution = 1:5
Solution: Sugar = (0.68 – 0.05) / 1.2 × 5 = 2.625 mg/ml
Water Analysis for Drinking Purpose
Parameters: pH, TDS, Hardness, Chloride, Fluoride, Heavy metals
Apparatus: pH meter, Conductivity meter, Burette, Atomic absorption spectrophotometer
Procedure: Test pH using calibrated meter. Measure TDS by conductivity. Determine hardness by EDTA titration. Analyze metals by AAS.
Hardness Calculation:
Total Hardness (mg/L as CaCO₃) = (EDTA volume × EDTA normality × 50000) / Sample volume
Sample Problem:
EDTA used = 12.5ml, EDTA normality = 0.01N, Sample = 100ml
Solution: Hardness = (12.5 × 0.01 × 50000) / 100 = 62.5 mg/L
Determination of Caffeine Content
Chemicals: Chloroform, Sodium carbonate, Caffeine standards
Apparatus: HPLC system, C18 column, UV detector, Separatory funnel
Procedure: Extract caffeine with chloroform after alkalinization. Analyze by HPLC using mobile phase acetonitrile:water (30:70). Detect at 280nm.
HPLC Calculation:
Caffeine (mg/L) = (Peak area sample / Peak area standard) × Standard concentration × Dilution factor
Sample Problem:
Sample peak area = 2500, Standard peak area = 3000, Standard = 50mg/L, Dilution = 1:2
Solution: Caffeine = (2500/3000) × 50 × 2 = 83.33 mg/L
Determination of Heavy Metals in Food
Chemicals: Nitric acid, Hydrogen peroxide, Metal standards (Pb, Cd, Hg, As)
Apparatus: Microwave digestion system, Atomic absorption spectrophotometer, Graphite furnace
Procedure: Digest samples with HNO₃ and H₂O₂ in microwave. Analyze by AAS-GF. Use standard addition method for matrix interference.
AAS Calculation:
Metal concentration (mg/kg) = (Absorbance × Slope factor × Dilution × Volume) / Sample weight
Sample Problem:
Lead absorbance = 0.045, Slope = 0.0025, Dilution = 50, Volume = 25ml, Sample = 2g
Solution: Pb = (0.045 × 0.0025 × 50 × 25) / 2 = 0.70 mg/kg
Determination of Citric Acid in Juices
Chemicals: Pyridine, Acetic anhydride, NaOH solution, Phenolphthalein
Apparatus: Burette, Conical flask, Pipettes, Water bath
Procedure: Neutralize sample to pH 8.1. Add pyridine-acetic anhydride reagent. Heat at 70°C for 30 min. Titrate excess acetic anhydride with NaOH.
Titration Calculation:
Citric acid % = [(Blank – Sample) × NaOH normality × 0.064 × 100] / Sample weight
Sample Problem:
Blank = 25ml, Sample = 18ml, NaOH = 0.1N, Sample weight = 10g
Solution: Citric acid = [(25-18) × 0.1 × 0.064 × 100] / 10 = 0.448%
Determination of Ascorbic Acid in Fruit Juices
Chemicals: 2,6-dichlorophenolindophenol, Metaphosphoric acid, Ascorbic acid standard
Apparatus: Burette, Conical flask, Pipettes, Measuring cylinder
Procedure: Extract vitamin C with metaphosphoric acid. Titrate with DCPIP solution until pink endpoint persists for 15 seconds.
Vitamin C Calculation:
Ascorbic acid (mg/100ml) = (DCPIP volume × DCPIP factor × 100) / Sample volume
Sample Problem:
DCPIP used = 8.5ml, DCPIP factor = 0.5mg/ml, Sample = 10ml
Solution: Vitamin C = (8.5 × 0.5 × 100) / 10 = 42.5 mg/100ml
Evaluation of Rancidity – Acid Value
Chemicals: Ethanol, Diethyl ether, KOH solution, Phenolphthalein
Apparatus: Burette, Conical flask, Pipettes, Measuring cylinder
Procedure: Dissolve oil sample in ethanol-ether mixture (1:1). Add phenolphthalein indicator. Titrate with 0.1N KOH until pink endpoint.
Acid Value Formula:
Acid Value = (KOH volume × KOH normality × 56.1) / Sample weight
Sample Problem:
KOH used = 3.2ml, KOH normality = 0.1N, Oil sample = 5g
Solution: Acid Value = (3.2 × 0.1 × 56.1) / 5 = 3.59 mg KOH/g
HPLC Analysis of Pharmaceutical Binary Mixture
System: HPLC with UV detector, C18 column (250×4.6mm, 5μm)
Mobile Phase: Acetonitrile:Water (60:40), Flow rate 1.0 ml/min
Validation: Linearity, Precision, Accuracy, LOD, LOQ, Resolution, Tailing factor
Statistical Parameters:
RSD% = (Standard deviation / Mean) × 100
LOD = 3.3 × (σ/S), LOQ = 10 × (σ/S)
Resolution = 2(t₂-t₁)/(W₁+W₂)
Sample Calculation:
Peak areas: 2500, 2480, 2520, 2510, 2490
Mean: 2500, SD: 16.73, RSD: 0.67%
DNA Extraction from Biological Samples
Chemicals: Lysis buffer, Proteinase K, Ethanol, TE buffer
Apparatus: Centrifuge, Micropipettes, Vortex mixer, Water bath
Procedure: Lyse cells with buffer. Add proteinase K, incubate at 56°C. Precipitate DNA with ethanol. Wash and resuspend in TE buffer.
DNA Quantification:
DNA concentration (μg/ml) = A₂₆₀ × 50 × Dilution factor
Purity ratio = A₂₆₀/A₂₈₀ (should be 1.8-2.0)
Sample Problem:
A₂₆₀ = 0.45, A₂₈₀ = 0.25, Dilution = 1:100
Solution: DNA = 0.45 × 50 × 100 = 2250 μg/ml, Purity = 1.8