B Pharmacy Sem 4: Pharmacognosy & Phytochemistry I
Subject 3. Pharmacognosy & Phytochemistry I
1. Introduction to Pharmacognosy (History, Scope & Sources of Drugs)
2. Biosynthesis & Classification of Secondary Metabolites
3. Carbohydrates & Glycosides (Structure, Occurrence & Pharmacological Importance)
4. Alkaloids (Classification, Isolation Techniques & Pharmacological Activities)
5. Terpenoids & Essential Oils (Extraction, Analysis & Therapeutic Uses)
6. Phytochemical Screening & Chromatographic Techniques (TLC, HPTLC, GC, HPLC)
Unit 1: Introduction to Pharmacognosy (History, Scope & Sources of Drugs)
A foundational exploration into the study of natural drugs—covering its definition, historical development, breadth of activities, and the diverse origins of pharmacologically active substances.
1.1 Definition & Core Concepts
1.1.1 Pharmacognosy
Derived from Greek pharmakon (drug) and gnosis (knowledge)
Pharmacognosy: Science of drugs of natural origin, encompassing their biological sources, chemical constituents, extraction, isolation, and standardization.
1.1.2 Key Terms
Crude Drug: Unrefined plant, animal, or mineral material containing therapeutic constituents.
Active Constituent: Specific chemical moiety responsible for pharmacological activity.
Herbal Medicine: Preparations from plant materials for therapeutic use.
1.2 Historical Evolution
1.2.1 Ancient Civilizations
Egypt & Mesopotamia (c. 3000 BCE): Ebers Papyrus listing >700 plant remedies (e.g., willow bark for pain).
India & China:
Ayurveda (
Charaka Samhita, ~1st millennium BCE)—herbal formulations;Traditional Chinese Medicine (
Shennong Ben Cao Jing, ~1st century CE)—365 materia medica entries.
1.2.2 Medieval to Renaissance
Islamic Golden Age: Avicenna’s Canon of Medicine (1025 CE) systematized drug monographs.
European Herbals: 16th–17th centuries—Dioscorides’s De Materia Medica resurgence; Paracelsus’s chemical remedies.
1.2.3 Modern Era
19th Century: Isolation of morphine (1804), quinine (1820)—birth of alkaloid chemistry.
20th Century:
Discovery of penicillin (1928) launching microbial pharmacognosy.
Standardization protocols (pharmacopoeias) and bioassay development.
21st Century: Integration with genomics, metabolomics, and sustainable sourcing.
1.3 Scope of Pharmacognosy
1.3.1 Drug Discovery & Lead Identification
Bioprospecting—screening biodiversity for novel bioactive compounds.
Ethnopharmacology—leveraging traditional knowledge to guide research.
1.3.2 Phytochemistry & Bioactive Profiling
Isolation, structure elucidation (NMR, MS) of secondary metabolites.
Quantitative analysis for standardization (marker compounds in plant extracts).
1.3.3 Quality Control & Standardization
Macroscopic/macroscopic authentication of raw materials.
Physicochemical parameters: moisture content, ash values, extractive values.
1.3.4 Formulation & Dosage Forms
Development of herbal formulations: tinctures, extracts, capsules, topical gels.
Ensuring stability, bioavailability, and reproducibility.
1.3.5 Regulatory & Conservation Aspects
Compliance with WHO guidelines, national pharmacopeias, and Good Agricultural and Collection Practices (GACP).
Conservation of endangered species and sustainable harvesting.
1.4 Sources of Natural Drugs
1.4.1 Plant Sources
Leaves (e.g., digitalis leaves → cardiac glycosides)
Bark (e.g., Cinchona → quinine)
Roots & Rhizomes (e.g., ginseng → ginsenosides)
Flowers & Fruits (e.g., saffron stigmas → crocin; citrus peels → flavonoids)
Whole Plant (e.g., St. John’s wort for hypericin)
1.4.2 Animal Sources
Venoms & Toxins (e.g., captopril development from Bothrops jararaca venom peptides)
Glandular Products (e.g., insulin from porcine pancreas)
Marine Invertebrates (e.g., ziconotide from cone snail toxin)
1.4.3 Microbial Sources
Antibiotics: Penicillium spp. (penicillin), Streptomyces spp. (streptomycin, tetracyclines)
Mycoproteins & Metabolites: Lovastatin from Aspergillus terreus
1.4.4 Mineral & Inorganic Sources
Clays & Earths: Kaolin, bentonite in antidiarrheals
Heavy Metals: Bismuth subsalicylate in gastrointestinal therapies
1.5 Integration in Pharmaceutical Sciences
1.5.1 Interdisciplinary Collaboration
Coordination among botanists, chemists, pharmacologists, and process engineers.
1.5.2 Modern Technologies
High‑throughput screening of natural extracts.
Metabolomics & Cheminformatics for rapid dereplication and lead optimization.
1.5.3 Ethical & Sustainability Considerations
Fair benefit sharing with indigenous communities.
Cultivation and tissue culture to reduce wild‐harvest pressure.
1.6 Key Points for Exams
Define pharmacognosy and list its principal activities.
Trace History: Match key milestones (e.g., morphine isolation, Canon of Medicine).
Classify Sources: Provide two examples each of plant, animal, microbial, and mineral drugs.
Quality Tests: Describe three physicochemical parameters used to standardize crude plant drugs.
Scope Essay: Outline how ethnopharmacology informs modern drug discovery and the role of sustainability.
Unit 2: Biosynthesis & Classification of Secondary Metabolites
A comprehensive analysis of how plants and other organisms synthesize bioactive “secondary” metabolites—detailing their biosynthetic pathways, structural classes, and relevance to drug discovery.
2.1 Definition & Biological Role
2.1.1 Primary vs. Secondary Metabolites
Primary Metabolites: Universal compounds essential for growth (e.g., sugars, amino acids, lipids).
Secondary Metabolites: Species‑ or tissue‑specific compounds not directly required for basic metabolism but conferring ecological advantages—defense, signaling, attraction.
2.1.2 Physiological Functions
Defense: Phytoalexins (e.g., camalexin), tannins deter herbivores and pathogens.
Attraction: Pigments (anthocyanins), volatile terpenes attract pollinators.
Allelopathy: Release of compounds (e.g., juglone) to inhibit neighboring plants.
2.2 Major Biosynthetic Pathways
2.2.1 Shikimate Pathway
Precursor: Phosphoenolpyruvate + Erythrose‑4‑phosphate → chorismate.
Produces: Aromatic amino acids (phenylalanine, tyrosine, tryptophan) → phenolics, flavonoids, alkaloids.
Key Enzymes: DAHP synthase, chorismate mutase, phenylalanine ammonia‑lyase (PAL).
2.2.2 Acetate (Polyketide) Pathway
Precursor: Acetyl‑CoA units → polyketide chains via successive Claisen condensations.
Produces: Tetracyclines, anthraquinones (e.g., emodin), macrolides (via polyketide synthases in microbes).
Key Features: Modular enzyme complexes (PKS I, II, III) dictate chain length and cyclization pattern.
2.2.3 Mevalonate & Methylerythritol Phosphate (MEP) Pathways
Mevalonate Pathway (cytosolic in plants, most animals): Acetyl‑CoA → mevalonate → isopentenyl pyrophosphate (IPP).
MEP Pathway (plastidic in plants, bacteria): Glyceraldehyde‑3‑P + pyruvate → 1‑deoxyxylulose phosphate → IPP.
Produces: Terpenoids (monoterpenes, diterpenes, triterpenes, steroids), carotenoids.
Key Enzymes: HMG‑CoA reductase (mevalonate), DXS (DXP synthase in MEP).
2.3 Classification of Secondary Metabolites
2.3.1 Alkaloids
Definition: Nitrogen‑containing, basic compounds derived mainly from amino acids.
Subclasses:
Tropane (e.g., atropine, scopolamine)
Isoquinoline (e.g., morphine, berberine)
Indole (e.g., reserpine, vinblastine)
Biosynthetic Origin: Tyrosine (isoquinolines), tryptophan (indoles), ornithine (tropanes).
2.3.2 Phenolics & Polyphenols
Definition: Aromatic ring compounds with one or more hydroxyl groups, derived from phenylalanine via the shikimate pathway.
Subclasses:
Simple Phenols (e.g., eugenol)
Flavonoids (e.g., quercetin, rutin)
Tannins (hydrolyzable: gallotannins; condensed: procyanidins)
Functions: Antioxidant, UV protection, enzyme inhibition.
2.3.3 Terpenoids (Isoprenoids)
Definition: Structures built from C₅ isoprene units (IPP and DMAPP).
Subclasses:
Monoterpenes (C₁₀; e.g., limonene, menthol)
Sesquiterpenes (C₁₅; e.g., artemisinin)
Diterpenes (C₂₀; e.g., taxol)
Triterpenes/Steroids (C₃₀; e.g., saponins, cholesterol)
Roles: Membrane components, hormones, fragrance, defense.
2.3.4 Glycosides
Definition: Aglycone (non‑sugar moiety) linked to one or more sugar residues.
Subclasses:
Cardiac Glycosides (e.g., digoxin—steroid aglycone + digitoxose)
Anthraquinone Glycosides (e.g., senna)
Cyanogenic Glycosides (e.g., amygdalin)
2.4 Integration & Pharmaceutical Relevance
2.4.1 Lead Discovery & Semi‑Synthesis
Understanding biosynthetic route enables pathway engineering (e.g., overexpressing taxadiene synthase for taxol).
Precursor‑Directed Biosynthesis: Feeding analogs to cultures to generate novel derivatives.
2.4.2 Metabolic Engineering
Transfer of entire biosynthetic clusters into microbial hosts (e.g., artemisinic acid in yeast).
2.4.3 Chemodiversity & SAR
Structural diversification via tailoring enzymes (hydroxylases, methyltransferases, glycosyltransferases) yields analog libraries.
2.5 Key Points for Exams
Pathway Mapping: Draw schematic of shikimate vs. mevalonate pathways, showing key intermediates.
Classify Examples: Given structures, identify as alkaloid, terpenoid, or phenolic and state precursor.
Biosynthetic Enzymes: Describe role of HMG‑CoA reductase and phenylalanine ammonia‑lyase in secondary metabolism.
Pharma Applications: Explain how artemisinin biosynthesis understanding led to improved production in yeast.
Integrative Question: Propose a semi‑synthetic modification on a polyketide scaffold to enhance water solubility.
Unit 3: Carbohydrates & Glycosides (Structure, Occurrence & Pharmacological Importance)
An in‑depth treatment of plant‑derived carbohydrates and their glycosidic derivatives—covering structural features, natural distribution, types of glycosides, biological roles, and therapeutic applications.
3.1 Carbohydrate Fundamentals
3.1.1 Definition & General Formula
Carbohydrates: Polyhydroxy aldehydes or ketones (monosaccharides) and their oligomeric/polysaccharide forms.
General empirical formula: Cₙ(H₂O)ₘ, where typically m = n or closely related.
3.1.2 Monosaccharide Classification
By Carbon Number: Trioses (n=3), tetroses, pentoses (e.g., D‑ribose), hexoses (e.g., D‑glucose, D‑fructose).
By Functional Group: Aldoses (aldehyde at C‑1) vs. ketoses (ketone at C‑2).
3.1.3 Ring Structures & Stereochemistry
Haworth Projections: Five‑membered furanoses vs. six‑membered pyranoses.
Anomeric Carbon: C‑1 in aldopyranoses; gives rise to α/β anomers via hemiacetal formation.
Epimers & Enantiomers: Difference at one stereocenter (e.g., glucose vs. galactose at C‑4); mirror‑image D/L forms.
3.2 Occurrence of Carbohydrates in Plants
3.2.1 Storage Polysaccharides
Starch: Amylose (linear α(1→4)) and amylopectin (branched α(1→4), α(1→6)); energy reserve in seeds/tubers.
Inulin: Fructan polymer in chicory and artichoke—prebiotic and diuretic uses.
3.2.2 Structural Polysaccharides
Cellulose: Linear β(1→4)-linked glucose in cell walls—industrial source of microcrystalline cellulose.
Hemicelluloses & Pectins: Heteropolysaccharides (galacturonans, arabinoxylans) with gelling properties (e.g., jam setting).
3.2.3 Oligosaccharides
Raffinose Family: Raffinose, stachyose in legumes—implicated in flatulence but potential prebiotic effects.
3.3 Glycoside Definition & Formation
3.3.1 Glycosides
Definition: Compounds in which a sugar moiety (glycone) is O‑, N‑, or C‑linked to a non‑sugar aglycone (genin).
Biosynthesis: Catalyzed by glycosyltransferases using activated sugar donors (e.g., UDP‑glucose).
3.3.2 Glycosidic Bond
O‑Glycosides: Sugar–OH bonds to aglycone (most common).
N‑Glycosides: Sugar attached via nitrogen (e.g., cyanogenic glycosides).
C‑Glycosides: Direct C–C linkage (stable to acid hydrolysis, e.g., puerarin).
3.4 Major Glycoside Classes & Examples
| Class | Aglycone Type | Example & Source | Pharmacological Importance |
|---|---|---|---|
| Cardiac Glycosides | Steroid nucleus | Digoxin (Digitalis lanata) | Positive inotrope for CHF management |
| Anthraquinone Glycosides | Anthracene derivatives | Aloe‑emodin (Aloe vera), Senna glycosides | Laxative via colonic stimulation |
| Flavonoid Glycosides | Flavone/flavonol core | Rutin (buckwheat), quercetrin (oak) | Antioxidant, vascular protector |
| Cyanogenic Glycosides | Cyanohydrin moiety | Amygdalin (Prunus seeds) | Releases HCN—historical anticancer claims |
| Saponin Glycosides | Triterpenoid or steroid | Ginsenosides (Panax ginseng) | Adaptogenic, immunomodulatory |
3.5 Pharmacological Roles & Mechanisms
3.5.1 Cardiac Glycosides
Inhibit Na⁺/K⁺‑ATPase in myocytes → increased intracellular Ca²⁺ → enhanced cardiac contractility.
Narrow therapeutic index; monitoring of plasma levels essential.
3.5.2 Anthraquinone Glycosides
Hydrolyzed by colonic flora → aglycone induces peristalsis and inhibits water absorption.
Used as stimulant laxatives; dosing adjusted to avoid cramping.
3.5.3 Flavonoid Glycosides
Scavenge free radicals; stabilize capillary walls and reduce permeability.
Employed in venotonic and anti‑inflammatory herbal preparations.
3.5.4 Cyanogenic Glycosides
Upon tissue damage, β‑glucosidase cleaves to release HCN → toxic at high doses.
Low‑dose dietary exposure underlie traditional uses and safety concerns.
3.5.5 Saponin Glycosides
Amphipathic; form soap‑like foams.
Exhibit membrane‑permeabilizing, cholesterol‑binding activities → adjuvant or expectorant effects.
3.6 Isolation & Analysis
3.6.1 Extraction
Aqueous/Alcoholic Decoction & Infusion for polar glycosides.
Percolation under controlled pH to preserve labile bonds.
3.6.2 Hydrolysis & Derivatization
Acid/Base Hydrolysis: Releases aglycone for identification; sugar analysis by TLC or GC (as alditol acetates).
3.6.3 Chromatographic Techniques
TLC/HPTLC: Identification via Rf values and color reagents (e.g., Ehrlich’s reagent for cardiac glycosides).
HPLC–DAD/MS: Quantitative marker assays (e.g., digoxin in Digitalis extract).
GC–MS: Volatile sugar derivatives or aglycones after silylation.
3.7 Key Points for Exams
Draw & Explain: Structure of an O‑glycosidic bond and mechanism of enzymatic hydrolysis by β‑glucosidase.
Classify: Given an aglycone structure, predict appropriate glycoside class and likely sugar donor.
Describe: Pharmacodynamics of digoxin and monitoring parameters.
Outline Extraction: Step‑by‑step procedure to isolate anthraquinone glycosides from senna leaves.
Analytical Plan: Design an HPLC method to quantify rutin in a herbal preparation, including choice of column, mobile phase, and detection wavelength.
Unit 4: Alkaloids (Classification, Isolation Techniques & Pharmacological Activities)
An exhaustive exploration of nitrogen‑containing plant secondary metabolites—covering their structural definition, biosynthetic classes, isolation and purification methods, diverse pharmacological actions, analytical techniques, and exam‑relevant summaries.
4.1 Definition & General Properties
4.1.1 Definition
Alkaloids: Naturally occurring organic compounds containing one or more basic nitrogen atoms—usually heterocyclic—and biosynthesized from amino acids.
4.1.2 Physicochemical Characteristics
Basicity: pKₐ typically 7–10; exist as salts under slightly acidic to neutral pH.
Solubility: Free bases are lipophilic (soluble in organic solvents); salts are water‑soluble.
Optical Activity: Many are chiral with significant stereochemical complexity.
4.2 Classification of Alkaloids
4.2.1 Based on Biosynthetic Precursors
| Class | Precursor Amino Acid | Representative Alkaloids |
|---|---|---|
| Tropane | Ornithine | Atropine, Scopolamine |
| Pyrrolidine/Pyrrolizidine | Ornithine/Arginine | Hyoscyamine, Senecionine |
| Indole | Tryptophan | Reserpine, Vincristine |
| Isoquinoline | Tyrosine | Morphine, Codeine, Papaverine |
| Piperidine | Lysine | Coniine |
| Purine | Adenine/Guanine | Caffeine, Theobromine |
4.2.2 Based on Ring Structure
Monocyclic: Coniine
Bicyclic: Tropane alkaloids
Polycyclic: Indole‑diterpenoid alkaloids (e.g., vinblastine)
4.3 Occurrence & Examples
4.3.1 Plant Families & Sources
Solanaceae: Atropa, Datura (tropanes)
Papaveraceae: Papaver somniferum (isoquinolines)
Rubiaceae: Rauwolfia serpentina (indoles)
Leguminosae: Conium maculatum (piperidines)
Theaceae & Malvaceae: Camellia sinensis, Theobroma cacao (purines)
4.3.2 Ecological Functions
Defense against herbivores and pathogens
Allelopathic interactions
4.4 Isolation & Purification Techniques
4.4.1 Extraction
Defatting: Remove lipids with nonpolar solvents (hexane).
Acidic Extraction: Grind plant material in dilute HCl → convert alkaloids to water‑soluble salts.
Basification & Back‑Extraction: Raise pH (pH 9–10) to free base → extract into organic solvent (chloroform, dichloromethane).
4.4.2 Purification
Liquid–Liquid Partitioning: Stepwise pH adjustments to separate alkaloid classes by pKₐ differences.
Vacuum Distillation: For volatile alkaloids (e.g., nicotine).
Chromatography:
Column Chromatography on silica gel or alumina with gradient elution (ethyl acetate–methanol).
Preparative HPLC for high‑purity isolation.
4.5 Pharmacological Activities & Mechanisms
| Alkaloid Class | Representative Agents | Primary Action | Mechanism of Action |
|---|---|---|---|
| Tropanes | Atropine, Scopolamine | Anticholinergic | Competitive blockade of muscarinic acetylcholine receptors |
| Isoquinolines | Morphine, Codeine | Analgesic, sedative | Agonism at μ‑opioid receptors; codeine metabolized to morphine |
| Indoles | Reserpine, Vincristine | Antihypertensive; anticancer | VMAT2 inhibition (depletes monoamines); microtubule inhibition |
| Pyrrolizidines | Senecionine | Hepatotoxic | Bioactivation to reactive pyrroles causing liver injury |
| Purines | Caffeine, Theobromine | CNS stimulant; diuretic | Adenosine receptor antagonism; phosphodiesterase inhibition |
4.5.1 Dose & Therapeutic Index
Many alkaloids have narrow therapeutic indices—dose titration and monitoring essential (e.g., morphine).
4.6 Analytical & Standardization Methods
4.6.1 Qualitative Tests
Dragendorff’s Reagent: Orange‑red precipitate with alkaloid salts.
Mayer’s & Wagner’s Reagents: White or brown precipitates.
4.6.2 Quantitative Analysis
HPLC–UV/DAD: Gradient elution and detection at characteristic λ_max (e.g., morphine at 285 nm).
GC–MS: For volatile alkaloids after derivatization (e.g., N‑acetylation).
LC–MS/MS: Sensitive quantitation in complex matrices (biological fluids).
4.7 Key Points for Exams
Draw & Classify: Structures of atropine and morphine; assign to correct biosynthetic class.
Isolation Flowchart: Outline extraction and purification steps for a generic plant alkaloid.
Mechanism Description: Explain how reserpine lowers blood pressure via VMAT2 inhibition.
Analytical Protocol: Design an HPLC method to quantify codeine in a cough syrup, including sample prep and detection wavelength.
Safety Considerations: Discuss the narrow therapeutic window of tropane alkaloids and strategies to mitigate overdose risk.
Unit 5: Terpenoids & Essential Oils (Extraction, Analysis & Therapeutic Uses)
A comprehensive examination of terpenoid natural products and their volatile essential oils—covering structural principles, biosynthetic origins, extraction methods, analytical techniques, pharmacological applications, and exam‑worthy summaries.
5.1 Terpenoid Fundamentals & Classification
5.1.1 Isoprene Rule (C₅ Building Blocks)
Isoprene Unit: C₅H₈ monomer; terpenoids arise from head‑to‑tail and head‑to‑head linkages of isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP).
5.1.2 Major Terpenoid Classes
| Class | Carbon Count | Representative Compounds | Core Skeleton |
|---|---|---|---|
| Monoterpenes | C₁₀ | Limonene, Menthol, Geraniol | Two isoprene units |
| Sesquiterpenes | C₁₅ | Farnesol, Artemisinin | Three isoprene units |
| Diterpenes | C₂₀ | Taxol (Paclitaxel), Phytol | Four isoprene units |
| Triterpenes | C₃₀ | Saponins, Betulinic acid | Six isoprene units (often cyclized to steroids) |
| Tetraterpenes | C₄₀ | Carotenoids (β‑carotene) | Eight isoprene units |
5.1.3 Structural Diversity
Cyclization Patterns: Linear chains vs. mono‑, bi‑, polycyclic frameworks.
Functionalization: Hydroxylation, oxidation, glycosylation yield alcohols, ketones, acids, glycosides.
5.2 Biosynthesis & Occurrence
5.2.1 Biosynthetic Pathways
Mevalonate Pathway (cytosol): Acetyl‑CoA → HMG‑CoA → mevalonate → IPP → DMAPP.
MEP Pathway (plastidic in plants, bacteria): Pyruvate + G3P → DXP → MEP → IPP/DMAPP.
5.2.2 Natural Sources
Plants: Essential oils in glandular trichomes (mint, lemon), resins (pine), latex (taxus).
Microbes: Actinomycetes produce sesquiterpene antibiotics (e.g., albaflavenone).
Marine Organisms: Diterpene macrolides with antitumor activity.
5.3 Essential Oils
5.3.1 Definition & Composition
Essential Oil: Complex mixture of volatile terpenoids (monoterpenes, sesquiterpenes) and small phenolics.
Principal Components: Major 70–90% (e.g., limonene in citrus); minor constituents impart aroma nuances.
5.3.2 Physicochemical Properties
Volatility: Boiling points between 150–300 °C; vapor pressure suited for diffusive aroma.
Solubility: Insoluble in water; soluble in ethanol, fixed oils.
5.4 Extraction Methods
5.4.1 Steam Distillation
Principle: Co‑distillation of volatiles with water vapor at reduced effective boiling points; widely used for mint, lavender.
5.4.2 Hydro‑ or Dry‑Distillation
Hydrodistillation: Plant material immersed in water; simple apparatus (Clevenger).
Dry Distillation: Pyrolysis of resins (e.g., olibanum) to yield oleoresins.
5.4.3 Solvent Extraction & Enfleurage
Cold Solvent: Hexane or supercritical CO₂ for temperature‑sensitive constituents.
Enfleurage: Fat‐based absorption of aroma compounds; historically used for jasmine.
5.4.4 Expression (Cold Pressing)
Mechanical rupture of oil glands (e.g., citrus peel) without heat.
5.5 Analytical Techniques
5.5.1 Gas Chromatography (GC & GC‑MS)
GC‑FID: Quantitative profiling of major terpenoids.
GC‑MS: Structural identification via fragmentation patterns; essential for fingerprinting.
5.5.2 High‑Performance Thin‑Layer Chromatography (HPTLC)
Qualitative: Rapid screening of essential‑oil profiles; visible/derivatized spots.
5.5.3 HPLC & LC‑MS
Non‑Volatile Terpenoids: Analysis of diterpene glycosides and triterpenoid saponins.
5.5.4 Spectroscopic Methods
IR: Functional‑group analysis (C=C, OH) in terpenoids.
NMR: Detailed structural elucidation (1D/2D) for novel diterpenes.
5.6 Therapeutic Uses & Mechanisms
| Compound/Class | Source Plant | Pharmacological Action | Mechanism |
|---|---|---|---|
| Menthol | Mentha × piperita | Analgesic, cooling | TRPM8 receptor activation |
| Limonene | Citrus spp. | Gastroprotective, lipid‑lowering | Modulation of gastric mucosa, cytokines |
| Artemisinin | Artemisia annua | Antimalarial | Endoperoxide cleavage → reactive radicals |
| Taxol (Paclitaxel) | Taxus brevifolia | Antineoplastic | Microtubule stabilization |
| Boswellic Acids | Boswellia serrata | Anti‑inflammatory | 5‑LOX inhibition |
5.7 Quality Control & Standardization
5.7.1 Organoleptic Evaluation
Aroma & Color: Sensory profiling against reference oils.
5.7.2 Physicochemical Parameters
Refractive Index, Optical Rotation, Density: Indicators of purity and adulteration.
Specific Gravity: Measured at 20 °C for standardization.
5.7.3 Chromatographic Fingerprinting
GC Profile: Match retention time and relative abundance of marker terpenoids.
Chemometric Analysis: Multivariate statistics for geographical or cultivar differentiation.
5.8 Key Points for Exams
Define & Classify: Explain the isoprene rule and classify terpenoids by carbon number.
Extraction Rationale: Justify choice of steam distillation vs. supercritical CO₂ for temperature‑sensitive oils.
Analytical Design: Outline a GC‑MS method to fingerprint lavender oil, including column type and detector settings.
Mechanism Discussion: Describe how artemisinin’s endoperoxide moiety mediates antimalarial activity.
Quality Criteria: List three physicochemical tests to confirm purity of a commercial essential oil and interpret typical values.
Unit 6: Phytochemical Screening & Chromatographic Techniques (TLC, HPTLC, GC, HPLC)
A detailed overview of qualitative and quantitative methods for identifying and standardizing plant constituents—covering preliminary phytochemical tests and advanced chromatographic analyses.
6.1 Phytochemical Screening: Purpose & Preliminary Tests
6.1.1 Objectives of Screening
Rapid identification of major secondary metabolite classes in crude extracts.
Guidance for targeted isolation and bioactivity assays.
6.1.2 Common Phytochemical Tests
| Metabolite Class | Test | Positive Indication |
|---|---|---|
| Alkaloids | Mayer’s, Dragendorff’s | Creamy white (Mayer’s) or orange‑red ppt. |
| Flavonoids | Shinoda (Mg/HCl), NaOH | Pink/red coloration or yellow → color change |
| Tannins | Ferric chloride | Blue‑black or green coloration |
| Saponins | Froth test | Persistent foam (>1 cm layer) |
| Anthraquinones | Bornträger’s (NaOH extract) | Pink/red coloration on aque. layer |
| Glycosides | Keller–Killiani (cardiac) | Brown ring at interface; blue‑green upper layer |
| Terpenoids | Salkowski (CHCl₃/H₂SO₄) | Reddish‑brown interface |
| Phenolics | Ferric chloride | Deep blue or green coloration |
6.2 Chromatography: Fundamental Principles
6.2.1 Definition & Modes
Chromatography: Separation of components between a mobile phase and a stationary phase based on differential affinity.
Modes:
Adsorption: Silica/alumina stationary phase (TLC, HPTLC).
Partition: Liquid–liquid distribution (HPLC with reversed phase).
Gas–Liquid: Volatile analytes partition into stationary liquid film (GC).
6.2.2 Key Parameters
Retention Factor (R_f) for TLC:
Retention Time (t_R) for GC/HPLC
Selectivity (α), Resolution (R_s), Efficiency (N)
6.3 Thin‑Layer Chromatography (TLC & HPTLC)
6.3.1 Plate Composition & Preparation
TLC: Silica gel or alumina on glass/plastic sheets.
HPTLC: Higher‑performance plates with finer particles and uniform layers.
6.3.2 Sample Application & Development
Spotting: Microliter bands vs. discrete spots using capillary or automatic applicator.
Mobile Phase Selection: Binary/ternary solvent systems optimized for polarity (e.g., toluene–ethyl acetate–formic acid).
Development: Vertical chamber saturated with mobile phase vapor; allow capillary ascent.
6.3.3 Detection & Visualization
UV Light (254/366 nm) for native fluorescence or after derivatization (e.g., NP/PEG for flavonoids).
Chemical Reagents:
Dragendorff’s for alkaloids
Anisaldehyde–sulfuric acid for terpenoids (color development on heating)
Densitometry (HPTLC) for semi‑quantitative measurement of band intensity.
6.4 Gas Chromatography (GC)**
6.4.1 Instrument Components
Injector: Split/splitless for sample introduction.
Column: Capillary fused‑silica coated with stationary phase (e.g., 5% phenyl–95% methyl polysiloxane).
Detector:
FID (Flame Ionization) for hydrocarbons and terpenoids.
MS (Mass Spectrometry) for structural identification.
6.4.2 Sample Preparation
Volatile Oils: Direct injection or dilution in solvent (e.g., hexane).
Non‑Volatile Metabolites: Derivatization (silylation, methylation) to increase volatility and thermal stability.
6.4.3 Data Interpretation
Chromatogram: Peaks identified by t_R and mass spectra; quantification via peak area relative to internal standard.
6.5 High‑Performance Liquid Chromatography (HPLC)**
6.5.1 Modes & Columns
Reversed‑Phase (RP‑HPLC): C₁₈/C₈ columns; water–acetonitrile or water–methanol gradients for polar to non‑polar analytes.
Normal‑Phase (NP‑HPLC): Silica columns for non‑polar compounds.
6.5.2 Detectors
UV–Vis/DAD: Monitoring at characteristic λ_max (e.g., polyphenols at 280 nm).
Fluorescence: High sensitivity for native or derivatized analytes.
MS: LC–MS for structural confirmation and trace-level quantitation.
6.5.3 Method Development
Mobile Phase Composition & pH: Buffer choice (phosphate, acetate) to control analyte ionization.
Gradient vs. Isocratic: Gradient elution for complex mixtures; isocratic for routine assays.
Flow Rate & Temperature: Optimize for resolution vs. analysis time.
6.6 Method Validation & Quality Assurance
6.6.1 Validation Parameters (ICH Q2(R1))
Specificity: Distinct separation of analyte from matrix.
Linearity & Range: Correlation coefficient (r² > 0.999).
Accuracy & Precision: Recovery (90–110%), %RSD <2%.
LOD & LOQ: Based on signal‑to‑noise ratios (3:1 and 10:1).
Robustness: Small deliberate changes in method parameters.
6.6.2 Documentation & Reporting
Standard Operating Procedures (SOPs) for each technique.
Batch records, chromatographic logs, calibration curves.
6.7 Integration into Standardization
TLC Fingerprinting: Rapid batch-to-batch consistency check for herbal extracts.
HPTLC Quantification: Semi‑automated assay of marker compounds (e.g., curcumin in turmeric).
GC Profiling: Authentication of essential‑oil composition; detection of adulterants.
HPLC Assays: Official monograph methods for quantifying active constituents (e.g., glycyrrhizin in licorice).
6.8 Key Points for Exams
Describe & Compare: Advantages and limitations of TLC vs. HPTLC.
Calculate R_f: Given solvent front and spot distances, compute retention factors for three phytoconstituents.
Design Chromatogram: Outline an HPLC method (column, mobile phase, detection λ) to quantify quercetin in an extract.
Method Validation: List five validation parameters and describe acceptance criteria.
Case Scenario: Propose a workflow—screening, isolation, and quantification—for alkaloids in an unknown plant sample using TLC and HPLC.