What is Lyophilization?

May 28th, 2014 by Acmas No comments »

Lyophilization/freeze drying is a method of extracting the water from Biological samples,foods and other products so that foods or products remain stable and are easier to store at room temperature. Biological materials should be dried to stabilize them for storage, preservation and shipping. In many cases this drying can cause damage and some loss of cellular or protein activity. Lyophilization significantly reduces damage to biological samples.

Principle of Lyophilization

Lyophilization is based on a simple principle of physics called “SUBLIMATION”. Sublimation is the process of transition of a substance from solid to the vapor state without passing through an intermediate liquid phase. The process of lyophilization consists of:

  • Freezing of the product to convert the water in the product to ice form,
  • Sublimation of ice directly into water vapor under vacuum.
  • Drawing off the water vapor
  • Once the ice has been sublimated, the products are freeze-dried and can be removed from machine.

The principle advantages of lyophilization as a drying process are:

  • Minimum damage and loss of activity in delicate heat-liable materials
  • Speed and completeness of rehydration
  • Possibility of accurate, clean dosing into final product containers
  • Porous, friable structure

The principle disadvantages of lyophilization are:

  • High capital cost of equipment (about three times more than other methods)
  • High energy costs (2-3 times more than other methods)
  • Long process time (typically 24 hour drying cycle)

 

Equipment used for Lyophilization – LYOPHILIZER

A lyophilizer consists of

  • A vacuum chamber containing product shelves which are capable of cooling and heating containers and their contents.
  • A vacuum pump, a refrigeration unit, which is associated controls are connected to the vacuum chamber.

Samples are generally placed in containers such as glass vials that are placed on the shelves within the vacuum chamber.

Cooling elements within the shelves freeze the product. Once the product is frozen, the vacuum pump evacuates the chamber and the product is heated. Heat is transferred by thermal conduction from the shelf, through the vial, and ultimately into the product.

Comparison with Liquid-Phase drying

Lyophilization avoid denaturation that is caused by heating the product, by maintaining it frozen throughout drying. This is the most obvious advantage over liquid-phase drying which cause the denaturation of proteins and other products.

Equally important is that in liquid-phase drying there is an undesirable shrinkage and concentration of active constituents that causes damage as well as a movement of these constituents to the surface of evaporation, where they form a dense, impermeable skin that inhibits drying, and later, rehydration. Such effects can be avoided by spray drying, but this requires brief exposure to temperatures around 100 degree C.

Advantages of the Lyophilization

Lyophilization has many advantages over the other drying and preserving techniques.

  1. It maintains food/ biochemical and chemical reagent quality because they remains at a temperature that is below the freezing-point during the process of sublimation.The use of lyophilization is particularly important when processing lactic bacteria, because these products are easily affected by heat.
  2. Food/biochemicals and chemical reagents which are lyophilized can usually be stored without refrigeration, which results in a significant reduction of storage and transportation costs.
  3. Lyophilization greatly reduces weight, and this makes the products easier to transport. For example, many foods contain as much as 90% water. These foods are 10 times lighter after lyophilization.
  4. Because they are porous, most freeze-dried products can be easily rehydrated. Lyophilization does not significantly reduce volume, therefore water quickly regains its place in the molecular structure of the food/ biochemicals and chemical reagents.

Safety Guidelines for Lyophilizer

  • Mammalian cells can not be preserved by lyophilization because it can desteoy mammalian cells. Many microorganisms and proteins survive lyophilization well,because they rehydrate easily and quickly because of the porous structure left after the ice sublimes.
  • Wear appropriate eye protection at all times when working with or near a lyophilizer.
  • Specimens shell-frozen in ampoules are dried on a vacuum manifold or in a chamber-type drier at low negative pressure. If the glass neck of the ampoule is sealed off while the ampoule is still under vacuum, it may cause implosion, either during the sealing or later when the evacuated ampoule is being opened. To avoid this, after drying is completed, and before sealing is done, bring the pressure within the ampoule back to normal by gradually introducing dry nitrogen, avoiding turbulent disturbance of the dry product.
  • The narrow or constricted neck of the ampoule is contaminated if the specimen is allowed to run down the wall of the neck during filling. Subsequently, when the ampoule is sealed with a torch, the dried material on the wall becomes charred or partially decomposed; residues of this material may adversely affect the dried material when it is reconstituted. To avoid this, a syringe with a long cannula or a Pasteur-type pipette should be used to fill the vial. Do not allow the delivery end of the cannula or pipette to touch the neck of the vial.
  • All ampoules used for freeze-drying of cultures, toxins, or other biohazardous material should be fabricated of Pyrex-type glass. This type of glass requires a high-temperature torch using an air-gas or oxygen-gas mixture for sealing. These hard glass ampoules are much less apt to form gas bubbles that burst inwardly during sealing under vacuum than the soft glass ampoules and are more resistant to breakage during handling and storage.
  • The filling of ampoules and vials with infectious specimens, the subsequent freeze-drying, and sealing or closing of ampoules and vials in the preparation of dry infectious specimens should be performed in a biological safety cabinet. The same is true for the preparation of ampoules and vials containing liquid specimens not subject to freeze-drying.

Safety precautions to be taken will depend on the agents, equipment, and containment available.

Lyophilization Its Applications

May 28th, 2014 by Acmas No comments »

Lyophilization/freeze drying is a method of extracting the water from Biological samples, foods and other products so that foods or products remain stable and are easier to store and preserved at room temperature. Biological materials should be dried to stabilize them for storage, preservation and shipping. In many cases this drying can cause damage and some loss of cellular or protein activity. Lyophilization significantly reduces damage to biological samples.

Lyophilized/freeze dried products retain their original properties. By adding water or other solvents they can be reconstituted easily and very quickly to a usable solution. For example the Proteins and many other products are presented as a freeze-dried powder in vials for reconstitution by the administering doctor or pharmacy.

Commonly, water is used as solvent, but in some pharmaceutical applications alcohol is used to dissolve or disperse the product.  The freeze dryer itself is a sterile environment, protected by air-sterilizing vent filters.Vent filters also protect the exhaust, and prevent droplets or particles of active ingredients from being carried into the environment.

There is a wide range of substances for which freeze drying/Lyophilization is used as conservation/preservation method without changing their composition. In the aseptic pharmaceutical and biotechnology production, freeze drying/Lyophilization are often applied to the following products:

  • antibiotics,
  • bacteria,
  • vaccines,
  • hormones,
  • vitamins, enzymes, and peptides,
  • liposome and collagen,
  • plants and liver extracts,
  • radio-immuno essays,
  • Blood plasma, plasma fractions, and antibodies.

Process of Lyophilization/freeze drying is recommended for the products whose composition changes on the preservation such as proteins, but in the process of Lyophilization, there is no change in the composition of any substance. Some of applications of this process are;

  • This process provides an efficient technique for preservation of temperature sensitive products, mainly those of biological origin such as proteins, enzymes, blood plasma, vaccines, etc.
  • Lyophilization helps in achieving the chemical balance, such as for biological reagents.
  • Lyophilization is very efficient for the packaging of constituents that cannot be mixed in the liquid state.
  • It helps in improving the storage life and improved marketing of the end product.

It helps in resolving certain filling problems. It may be difficult, for instance, to divide several milligrams of powder into precise vial dosages, due to the difficulty of measuring tiny amounts, homogeneity, granulation, static electricity etc. The distribution of the product from the liquid state eliminates such production problems.

LUX METER

May 23rd, 2014 by Acmas No comments »

Lux is a measurement of the overall intensity of light within an environment for any given area or distance from the source or lux is the amount of light in an environments perceived by the human eye. Quality of light in workplace, schools and public buildings affect the quantity and quality of performance in workers and students.

In other words, the lux is a unit of measurement of brightness, or more accurately, illuminance. The illumination is how level of luminous flux is falling on a surface area. The luminous flux is visible component that is defined in radiant flux (light power) divided by relative sensitivity of human eyes over the visible spectrum. This means the Lux is well fit to light level from sense of human eyes. Lux is ultimately derives from the candela, the standard unit of measurement for the power of light.

A candela is a fixed amount, roughly equivalent to the brightness of one candle.While the candela is a unit of energy, it has an equivalent unit known as the lumen, which measures the same light in terms of its perception by the human eye. One lumen is equivalent to the light produced in one direction from a light source rated at one candela. The lux takes into account the surface area over which this light is spread, which affects how bright it appears. One lux equals one lumen of light spread across a surface one square meter.

How to Measure Lighting Levels

Measuring lighting or the illumination of an environment requires the use of an incident Lux meter or foot-candlemeter A lux meter is a device for measuring brightness. It specifically measures the intensity with which the brightness appears to the human eye. This is different than measurements of the actual light energy produced by or reflected from an object or light source.

A lux meter works by using a photo cell to capture light. The meter then converts this light to an electrical current. Measuring this current allows the device to calculate the lux value of the light it captured.

The lux light meter’s calculation of illuminance is done by using the Point Source process.  The measure of the lux light meter varies depending on the light’s intensity and distance.  If a point source has no reflections, a portion of the produced light reaches a surface.

How to measure light intensity using lux light meter

  • Compute for the square of the distance and multiply it by Pi and then by four.  The outcome must be a radius identical to the specific space from the source.  This calculation is the area of sphere at a particular distance.
  • Divide the light concentration in lumens by the spherical area. The product is the illuminance in foot-candles or lux, depending on whether feet or meters were used.
  • Application of a correction factor is needed if the light reaches the surface at an angle less than 90 degrees.  This can be done by multiplying the computed illuminance value by the cosine of the off-axis angle.

Applications of Lux meter

i) Photography and Video Filming. By measuring the light in luxes, photographers can adjust their shutter speed and depth of field to get the best picture quality. The device can also be very useful for filming outdoor scenes of television programs or movies as it allows adjustments to make sure scenes filmed in different light levels have a consistent brightness on screen.

ii) Health and Safety regulations : It can be used to check whether the brightness of a room is enough to meet any rules designed to protect workers from suffering damage to their eyesight. Using a lux meter takes into account the size of the room in a way that simply measuring the intensity of the light source in lumens would not.

iii) Photographic Mesurements; It also measures the photography subject’s illuminance.  When using a lux light meter, the photographer can determine the aperture number and the exposure setting.

Types of Lux Light Meters for the photography

  • Reflected Lux Light Meter

i)         This produces a measurement of the light reflecting from the photography subject to the camera

ii)       This kind of meter is positioned near or in the camera itself

iii)      A type of meter that is commonly installed in camcorders and point-and-shoot camera

iv)     Works best for scenes where light is evenly distributed

v)       May not work for scenes with varying brightness

  • Incident Lux Light Meter

i)         This type of lux light meter must be positioned near the photography subject

ii)       Measures the light intensity falling on the photography subject

iii)      Will produce great light reading when used with light receptor facing the camera

iv)     A photographer may produce trial shots before working on the desired camera settings.

Safety Guideline

  • In case of digital Lux meter, it is necessary to replace battery when the meter shows battery low.
  • The meter should ever not be placed in water deep enough to submerge any part of the upper body of the meter. this will ruin the meter.
  • Do not store the instrument where temperature or humidity is excessively high.
  • The measurement points should not be too close to walls or obstructions
  • Daylight should be shielded by blinds or curtains when assessing artificial lighting only