Enzymes Immobilization PDF

Summary

This document provides an overview of enzymes immobilization, a process of confining enzyme molecules to a solid support for various applications. The document covers different immobilization methods like adsorption, entrapment, covalent bonding, and cross-linking, along with their advantages, disadvantages, and specific examples. It also discusses carrier types, limitations, and the importance of immobilization techniques.

Full Transcript

# Enzymes Immobilization

## What Is Enzyme Immobilization?

Enzyme immobilization is defined as a process of confining enzyme molecules to a solid support over which a substrate is passed and converted to products.

## What Is An Immobilized Enzyme?

An immobilized enzyme is one whose movement in space has been restricted either completely or to a small limited region.

## Why Immobilize Enzymes?

* Protection from degradation and deactivation.
* Re-use of enzymes for many reaction cycles, lowering the total production cost of enzyme mediated reactions.
* Ability to stop the reaction rapidly by removing the enzyme from the reaction solution.
* Enhanced stability.
* Easy separation of the enzyme from the product.
* Product is not contaminated with the enzyme.

## An Ideal Carrier Matrices For Enzyme Immobilization

* Inert
* Physically strong and stable
* Cost effective
* Regenerable
* Reduction in product inhibition

## Classification Of Carriers

| Carriers | Examples |
| ------------------------------ | ------------------------------------------------------------------------------------------------------------------- |
| Inorganic | 1. Commercially SiO2 available materials- Porous glass. Silica. <br> 2. Mineral materials (clays) Celite Centonite |
| Organic Natural | 1. Cellulose derivatives- ODEAE-cellulose OCM-cellulose. <br> 2. Dextran. <br> 3. Polysacharides Agarose, Starch Pectine, Chitosan |
| Organic Synthetic | 1. Polystyrene <br> 2. Polyvinylacetate <br> 3. Acrylic polymers |
| | |

## Methods For Enzyme Immobilization

### Physical

* Adsorption
* Entrapment
* Encapsulation

### Chemical

* Covalent binding
* Cross linking

## Physical Methods For Immobilization

### Adsorption

* Involves the physical binding of the enzyme on the surface of the carrier matrix.
* Carrier may be organic or inorganic.
* The process of adsorption involves weak interactions like Vander Waal or hydrogen bonds.
* Carriers: silica, bentonite, cellulose, etc.
* Examples: catalase & invertase

#### Advantages

* Simple and economical
* Limited loss of activity
* Can be Recycled, Regenerated & Reused.

#### Disadvantages

* Relatively low surface area for binding.
* Exposure of enzyme to microbial attack.
* Yield are often low due to inactivation and desorption.

### Entrapment

* In entrapment, the enzymes or cells are not directly attached to the support surface, but simply trapped inside the polymer matrix.
* Enzymes are held or entrapped within the suitable gels or fibres.
* It is done in such a way as to retain protein while allowing penetration of substrate. It can be classified into lattice and micro capsule types.
* Inclusion in gels: Poly acrylamide gel, Poly vinyl alcohol gels.
* Inclusion in fibers: Cellulose and Poly -acryl amide gels.
* Inclusion in micro capsules: Polyamine, Polybasic - acid chloride monomers.

#### Lattice-Type Entrapment

* Entrapment involves entrapping enzymes within the interstitial spaces of a cross-linked water-insoluble polymer. Some synthetic polymers such as polyarylamide, polyvinylalcohol, etc... and natural polymer (starch) have been used to immobilize enzymes using this technique.

#### MicrocapsuleType Entrapmet/Encapsulation/Membrane Confinement

* It involves enclosing the enzymes within semi-permeable polymer membranes e.g. semi permeable collodion or nylon membranes in the shape of spheres.

#### Advantages

* No chemical modification.
* Relatively stable forms.
* Easy handling and re-usage.

#### Disadvantages

* The enzyme may leak from the pores.

### Covalent Binding

* Based on the binding of enzymes and water-insoluble carriers by covalent bonds.
* The functional groups that may take part in this binding are Amino group, Carboxyl group, Sulfhydryl group, Hydroxyl group, Imidazole group, Phenolic group, Thiol group, etc.
* Disadvantages: covalent binding may alter the conformational structure and active center of the enzyme, resulting in major loss of activity and/or changes of the substrate.
* Advantages: the binding force between enzyme and carrier is so strong that no leakage of the enzymes occurs, even in the presence of substrate or solution of high ionic strength.

### Cross Linking

* Cross linking involves intermolecular cross linking of enzyme molecules in the presence/absence of solid support.
* The method produces a 3 dimensional cross linked enzyme aggregate (insoluble in water) by means of a multifunctional reagent that links covalently to the enzyme molecules.

#### Advantages of cross linking:-

* Very little desorption(enzyme strongly bound)
* Higher stability (i.e. ph, ionic & substrate concentration)

#### Disadvantages of cross linking:-

* Cross linking may cause significant changes in the active site.
* Not cost effective.

## Comparison Between The Methods

| Characteristics | Adsorption | Covalent binding | Entrapment | Membrane confinement |
| -------------------------- | ---------- | ---------------- | ----------- | ---------------------- |
| Preparation | Simple | Difficult | Difficult | Simple |
| Cost | Low | High | Moderate | High |
| Binding force | Variable | Strong | Weak | Strong |
| Enzyme leakage | Yes | No | Yes | No |
| Applicability | Wide | Selective | Wide | Very wide |
| Running Problems | High | Low | High | High |
| Matrix effects | Yes | Yes | Yes | No |
| Large diffusional barriers | No | No | Yes | Yes |
| Microbial protection | No | No | Yes | Yes |

## Limitations Of Enzyme Immobilization

* Cost of carriers and immobilization.
* Changes in properties (selectivity).
* Mass transfer limitations.
* Problems with cofactor and regeneration.
* Problems with multienzymes systems.
* Activity loss during immobilization.

## Conclusion

Enzyme immobilization is one of the most promising approaches for exploiting enzyme-based processes in Biotransformation, diagnostics, pharmaceutical and food industries. Several hundreds of enzymes have been immobilized in a variety of forms including penicillin G Acylase, lipases, proteases, invertase, etc. Research should be focused on overcoming the current limitations related to immobilization techniques, so as to expand the horizon from all-round application.