Together with their applicability i

Together with their applicability in oral dosage forms, HPH has also been widely used in formulating parenteral formulations of poorly water soluble drugs. This process is considered suitable for parenteral formulations since there is no risk of contamination from milling media and the high pressure environment is able to protect from microbial contamination by eliminating potential contaminants [2]. It was successfully demonstrated by Muller and Peters in 1998 that HPH can be used to formulate nanosuspensions of poorly soluble drugs like prednisolone and carbamazepine that could be considered acceptable for parenteral administration [33].

Hecq et al. have reported that HPH was successful in formulating nifedipine as nanoparticles, which showed enhanced dissolution as well as improved saturation solubility and have suggested HPH as a simple, adequate and easily scaled up technique that can have general applicability to many poorly water soluble drugs [34]. This technique is thus useful in oral as well as parenteral drug formulations and is remarkably efficient in enhancing saturation solubility, dissolution as well as bioavailability of poorly soluble drugs.

2.2. Engineered particle size control

Although conventional size reduction techniques are convenient and simple, they are sometimes undesired and unfavorable depending upon the types of drug substances and the particles to be micronized. Conventional methods of size reduction are usually known to have certain typical disadvantages of being less efficient due to high energy requirements, posing threats of thermal and chemical degradation of drugs and the end products being not uniform in the particle size distribution [35] and [36]. Conventional milling techniques, in particular, are considered to be uncontrolled processes that have limitations in controlling size, shape, morphology, surface properties and electrostatic charge and lead to heterogeneous particle shapes or even agglomerated particles as the end product [24]. To overcome these limitations and to specifically control the particle properties, several particle engineering techniques have been developed as an alternative and are utilized to produce the required particle size and carefully control the particle properties. These novel particle engineering technologies such as cryogenic spray processes and crystal engineering processes are novel methods of producing nanosized drug particles as an attempt to reduce particle size and enhance solubility, dissolution and hence the bioavailability of drugs with poor aqueous solubility.

2.2.1. Cryogenic spray processes

Cryogenic spray processes are novel size reduction techniques that can be used to enhance the dissolution rate of poorly soluble drugs by creating nanostructured amorphous drug particles with high degree of porosity at very low temperatures. These cryogenic processes can also be followed by various drying processes like spray freeze drying, atmospheric freeze drying, vacuum freeze drying and lyophilization to produce dry powders [17] and [37]. There are several types of cryogenic spray techniques like: spray freezing onto cryogenic fluids, spray freezing into cryogenic liquids (SFL), spray freezing into vapor over liquid and ultra-rapid freezing to produce smaller drug particles with improved wettability [17].