Pharmacosome – A Spanking Accession in Vessicular Drug Delivery System

About Authors:
Swati Yadav¹*, Dr. S.K Prajapati¹
¹institute of pharmacy,
Bundelkhand University, Jhansi
*[email protected]

Abstract: ^{11, 12}
Pharmacosome is a neoteric amelioration in the terrain of solubility improvement of drug. Pharmacosome is a spanking accession in the vesicular drug delivery system which exposition sundry precedence over conventional drug delivery. Pharmacosome are vesicular system amphiphillic in nature having drug phospholipid complex. Drug-lipid complex chemical structure may result into ultrafine, vesicular, miceller or hexagonal aggregates. Pharmacosome vesicular system enhances drug permeation through biomembrane resulting in improved bioavalibility as well as pharmacokinetic and pharmacodynamic properties of drug. Certain properties such as small size, predetermined entrapment efficiency, amphiphillicity, active drug loading and stability are major factor for its selectivity and precision.

Reference Id: PHARMATUTOR-ART-1993

Introduction:
Solubility known as major aspect for bioavailability enhancement. As solubility property is directly proportional to bioavailability of drug lower bioavailability, requiring some support to enhance solubility as bioavailability is determining factor for the rate and the extend of absorption. Vesicular system was such a support to bioavailability enhancement.

Vesicular drug delivery system¹³:
These are concentric lipid bilayer, when ampihillic building blocks come in contact of water result in vesicular system. Bingham in 1965nfirst reported the biological origin of vesicles. A vesicular structure encapsulates drug extending therapeutic index. Vesicular delivery system proves to be useful for

Liposomal entrapment
Facilitating better drug permeability and enhanced solubilisation
Decreased adverse effect and have better site specific targeting.

Though have certain limitation such as¹²:

Vesicular system	Features	Problem
Liposome	Microscopic vesicles (25mm to 100µm) of one or more lipid separated by water or aqueous buffer compartments	Expensive to prepare, degradation by oxidation, sedimentation,leaching of drug, lack of purity of natural phospholipids.
Niosomes	Non ionic surfactant vesicles	Aqueous suspension may exhibit aggregation, fusion, leaching or hydrolysis of entrapped drug (liminting the self life)time consuming inefficient, instability
Transferosomes	Suitable for both low and high molecular weight and also for lipophilic as well as hydrophilic drugs	Expensive, chemical instability due to oxidative degradation, lack of purity of natural phospholipids

Table 1: Conventional Vesicular system limitation

These are factor responsible for development of pharmacosome.

Pharmacosome¹¹:
Pharmacosome can be defined as colloidal dispersion of drug covalently linked to lipid.theidea for the development of pharmacosome was based on surface and bulk interaction of lipid with water, Lipid-hydrogen, covalent or electrostatic binding. These are explained as coplex of phospholipid with amphiphilic, zwitterionic, stiochiometriccomplex of polyphenolic compound. Chemical structures of drug-lipid complex exist as ultrafine, vesicular, miceller or hexagonal (phospholipid – amphiphilic complex bearing active-H atom. A drug containing an active hydrogen atom or free carboxyl group (-OH, -NH₂, -COOH) with or without a spacer chain can be esterified to the hydroxyl group of a lipid molecule, producing amphillic prodrug. Pharmacosome, facilitate membrane, tissue or cell wall transfer in the organism being amphiphillic property , reduces interfacial tension and mesomorphic behaviour at higher concentration, reduce surface tension result in increase contact area, thus increasing bioavailability of drug.

FIG 1: Targeting of drug and formation of pharmacosome

Advantage^{11, 12}:
1.   Drug incorporation is high and predetermined
2.   It is covalently conjugate with lipid thus risk of drug lekage is minimal.
3.   Hydrophilic & lipophillic drug incorporation is advisable.
4.   Phase transition of temperature of vesicular and miceller pharmacosome have effect on their memberane interaction.
5.   Pharmacosome interact with biomembrane resulting in active ingredient transfer phase transition temperature of biomembrane caused by interaction improved membrane fluidity leading to enhanced permeation. Do not affect rate of release.
6.   Unentrapped drug can be removed speedily from formulation.
7.   A Physiochemical property of drug-lipid complex is responsible for its physiochemical stability.
8.   Reduced cost of therapy.
9.   Degradation of drug depend upon functional group of drug molecule, size, chain spacer and length of lipid.

Limitation of pharmacosome:
1.   For leakage protection of drug requires covalent bonding.
2.   Compound synthesis depends on amphiphillic nature.
3.   Pharmacosome require surface and bulk interaction of lipid with drug.
4.   Pharmacosome on storage undergoes aggregation, fusion as wellas chemical hydrolysis.

Component of pharmacosome^{11, 12}:

Drug
Drug having a free carboxyl group or an active hydrogen (-OH,-NH₂,-COOH) can be esterified to the lipid with or without spacer chain forming amphiphillic complex. Synthesised compound in turn provoking membrane, tissue or cell wall transfer in the organism so therapeutic efficiency of drug is enhanced i.e. pindolol maleate, bupranolol hydrochloride, taxol, acyclovir, etc.

Lipid
Lipid, phophatidylcholine are the major molecular building block of cell membrane. Drug on complexation with phospholipid which are hydrophobic or electrostatic zwitterionic molecule gives amphiphillic product which provide drugs to be lipid soluble and phospholipid, water soluble. Increase wetting and dispersion thus increasing solubility leading to enhanced bioavailability.

Solvent:
Solvent having volatile nature and high purity are being used. Solvent with intermediate polarity (between polarity of phospholipid and drug) is selected.

PARAMETER	Technique and instrument
Stability , formation of the complex	Infrared spectroscopy analysis, FTIR
Shape , size and surface morphology	Scanning electron microscopy (SEM), Transmission electron microscopy (TEM)
Solubility study	Shaking-flask method
Drug –excipient compatibility study	Thermo analytical technique , Differential scanning calorimetry (DSC)
Degree of crystallinity	X-ray powder diffraction
In vitro dissolution studies	Dissolution test apparatus
Infrared spectroscopic analysis , nuclear magnetic resonance (NMR)	Formation of complex
Drug content	UV visible spectrophotometer

Table 2: Characterization parameter of pharmacosomes¹¹

Fig 2: Method of preparation of pharmacosome¹¹

Table 3: Research on pharmacosome

Researcher	Drug	Approaches
Gracia et al	ketoprofen	Increase solubility enhancementIncrease permeation of drug using dioeylphosphatidylcholine.
Muller-Goymann and Hamann⁴	fenoprofen	Increase solubility
JIN Yi Guang et al⁵	Acyclovir	Stability from heat, absorbed by plasma protein in blood decrease haemolytic reaction
Meihua HAN et al⁶	protopanaxadiol	Increased solubility ,stable
Zhang ZR et al⁷	3’,5’-dioctnoyl-5-fluoro-2’-deoxyuridine	AUC-10.97, Entrapment efficiency 96.62%, drug loading 29.02%
Shi et al⁸	Insulin phospholipid	Improve lipophillicity, improved oral absorption
Ping et al ¹⁰	5’-cholestrylsuccinyl-dideoxyinosine	Increased bioavailability, half life-7.64min
A Semalty et al^1,2,3	Aceclofenac, diclofenac, asprin	Aceclofenac– increased release rate upto 79.78%(1:1) aceclofenac:phospholipid, 76.17% (1:2)Diclofenac– increased releaseof pharmacosome to 87.8%, drug content 96.2±1.1%Asprin- Drug content- 95.6% release rate increases after 10 hr upto 90.93.
Ping-fei Yue⁹	Geniposide	Increase absortion and permeationof biologically active constituents.

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