Biotechnological Production Of Herbal Drugs Lecture 1 (PPC505)

Summary

This lecture introduces the topic of Biotechnological Production Of Herbal Drugs (PPC505), and details the course description, syllabus, learning outcomes, and assessment methods. The course covers various aspects of plant biotechnology, including four colors (red, green, white, and blue), downstream processes, and genetic engineering.

Full Transcript

Biotechnological
Production Of
Herbal Drugs
[PPC505]
Dr. Marwa Saeed Galaa
Goda | PhD
Lecturer of Pharmacognosy,
Faculty of Pharmacy, GU
[email protected]
 Course Desciption
The course is constructed to give insights on the
scope and practice of plant biotechnology. It covers the basic
principles of biotechnology and the different four colors (red,
green, white, and blue) of biotechnology. Furthermore, the
course delivers the knowledge on the downstream processes
of plant cells and tissue culture and different genetic
engineering techniques. Finally, the course concludes the
potential of biotechnological application in the market.
Syllabus
Week Lecture
1st week: 28/9/2024 Advising & registration
2nd week: 5/10/2024 Biotechnology: Four colors of biotechnology, and Pros & cons of green biotechnology
rd
3 week: 12/10/2024 I. Plant tissue culture: Advantages & disadvantages, and stages
4th week: 19/10/2024 I. Plant tissue culture: Nutritional requirements, and common problems
5th week: 26/10/2024 I. Plant tissue culture: Culture types, plant regeneration, and genetic assessment
I. Plant tissue culture: Extraction & quantification of metabolites, and strategies to increase
6th week: 2/11/2024
secondary metabolites production
Day

7th week: 9/11/2024 I. Plant tissue culture: Biotechnological application of plant callus culture
8th week: 16/11/2024 Midterm Exam
9th week: 23/11/2024 II. Plant genetic manipulation: Steps of plant genetic engineering/ transgenic biotechnology
10th week: 30/12/2024 II. Plant genetic manipulation: Advantages & disadvantages of genetically modified (GM) crops
11th week: 7/12/2024 II. Plant genetic manipulation: Different pharmaceutical applications of biotechnology 1
12th week: 14/12/2024 II. Plant genetic manipulation: Different pharmaceutical applications of biotechnology 2
13th week: 21/12/2024 Student presentations I
14th week: 28/12/2024 Student presentations II
15th week: 4/1/2025 Final Exam
Total marks
Items Marks
Midterm exam 30 marks

Semester activity
Quizzes 10 marks

(Class work)
Activity/ presentation 10 marks
Student’s attendance 5 marks
Student’s portfolio 5 marks

Final exam 40 marks

Total marks 100 marks
 Learning Outcomes (LOs)
a1. Describe different types of biotechnology, their scope and importance.
a2. Recognize the basic theories and principles of plant biotechnology.
a3. Illustrate the fundamental concepts to increase the production of pharmaceuticals.
a4. Demonstrate the relation between various growth media composition, culture environment, or
a. Knowledge and
growth regulators and the yield of phytochemicals
understanding
a5. Describe pros and cons of genetically modified crops.
a6. Record the recent advances in the fields of plant biotechnology.
a7. Explain different analytical methods that are used in the quantitative determination of the
bioactive metabolites in different in vitro cultures.
b1. Assess experimental scheme to suggest solutions for micropropagation of endangered plants.
b. Professional skills

c1. Interpret different protocols of transgenic plants for mass production of ornamental or
agricultural crops.
c. Intellectual skills c2. Analyze different methods and elicitation protocols for enhancement of natural products
productions.
c3. Categorize the different protocols of tissue cultures.
d- General and d1. Work effectively in team.
transferable skills d2. Use technology tools.
Introduction
 Introduction

- Definition of biotechnology

- Scope and importance of biotechnology
 Definition of biotechnology
Biotechnology (Biology- based technology) is any
technical application that uses biological systems or living
organisms (microorganisms, plants and animal) or their
components (derivatives) to make or modify products or processes
for the benefit of human beings.

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 Introduction

- Definition of biotechnology

- Scope and importance of biotechnology
 Scope and branches of biotechnology
Due to the rapid expansion of
biotechnology in different fields, a
color-coded system has been
developed to easily identify the primary
areas of biotechnological research.
Biotechnology can be applied
in industry, medicine, and agriculture.
There are four main branches
or “colors” of biotechnology: blue, red,
white, and green. Figure 1. Four colors (branches) of biotechnology.
 Biotechnology and Marine (Blue biotechnology):

Blue (or marine) biotechnology is a branch of
biotechnology that involves the technological utilization of marine
and aquatic organisms for developing novel compounds.

These compounds can
subsequently be utilized in the
pharmaceutical industry to create new
antioxidants, antibiotics, analgesics, and
antitumor, anti-inflammatory, and
antifungal agents.
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 Examples

1. Nutritional supplements: Cod liver oil contains omega-3 fatty acids,
vitamin A and vitamin C.

2. Wound healing agents: The use of wound dressings coated with
chitosan, a sugar derived from shrimp and crab shells. It can stop
bleeding via promoting the aggregation of platelets.

3. Cosmetics: Many cosmetic formulations use alga or their bioactive
metabolites as a moisturizing agent, anti-wrinkle agents, whitening
agents, sunscreen, anti‐cellulite, and also for hair care.

4. Analgesics: The peptide ziconotide, which is extracted from the venom
of the cone snail, displays a strong analgesic effect.
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 Biotechnology and Environment (White biotechnology):

White biotechnology (Environmental or industrial) is the
application of biotechnology to industrial processes in order to
reduce their environmental impact.

It is devoted to use living cells, from yeast, moulds, bacteria
and plants, and enzymes to synthesize products in sectors such as
paper, textiles, detergents, and energy.

White biotechnology also helps reduce waste by providing new
biodegradable plastics, for example from plants and fungi.

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 Examples
1. Textile industry: For finishing or modification processes of fibres and
fabric, the use of enzymes is cheaper or more environmentally friendly
than the conventional chemical treatments. For example: cotton scouring
(the removal of non-cellulose components) is normally done with a series
of chemical treatments. However, the recent introduction of an
enzymatic process allows the scouring to take place at a lower
temperature and gives a considerable reduction in waste water.

2. Plastic industry: Given that starch is renewable and biodegradable, it is
the most perfect raw material for biodegradable plastics (poly lactic
acid) for the packaging industry, that compete with other polyesters on
the market.
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 Examples
3. Energy source or biogas production: Biofuels (bioethanol and
biodiesel) are the focus of growing interest for transportation.
Bioethanol is an anhydrous ethyl alcohol obtained on a large scale by
alcoholic fermentation of sugar from sugar beets, sugarcane, corn, or
wheat. At present, bioethanol is used in car engines as a maximum of
15% additive to gasoline. Bio-diesel is defined mainly as methyl esters
(FAME) of long-chain fatty acids derived from vegetable oil (typically
rapeseed oil in Europe) using a process of chemical modification
(transesterification). Biomass (organic matter that comes from plants)
can also be fermented to produce methane (an efficient and established
technology) as a partial replacement of natural gas.
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 Examples
4. Detergent industry: The use of starch products for the production of
biodegradable, non-toxic and skin friendly detergents.

5. Pesticides: Bio-pesticides give environmentally safer alternative to
chemical pesticides for control of insect pests and diseases.

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 Biotechnology and Medicine (Red biotechnology):

Red biotechnology (Biopharma or medical/pharmaceutical)
is a distinct branch of biotechnology, which deals with therapeutic
and pharmaceutical applications and aims at human health
preservation.

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 Examples

It involves the production of vaccines (human hepatitis B)
and antibiotics, the discovery of new drugs, synthesis of
valuable drugs like insulin and interferon from bacteria for
treatment of human diseases, stem cell therapy, and new
diagnostics.

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 Biotechnology and Agriculture (Green biotechnology):

Among the applications of green biotechnology are the
development of transgenic and genetically modified (GM)
plants to improve the nutritional value (minerals, vitamins or
fiber contents), or quality. The technology is also used to
make or develop plants tolerant to pests and droughts etc.

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Importance of green biotechnology

(a) (b)

Figure 2. (a) Effect of global warming of crop availability; (b) Optimal outcome of using
green biotechnology

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 The world is grappling with the effects of ever-rising levels of atmospheric carbon
dioxide (CO2) resulting from emissions during the Industrial Revolution and fuels
combustion. These high levels of CO2 are a key cause of the global greenhouse effect, and
thus climate change ″global warming‶ which has resulted in low crop productivity. Low crop
productivity is also caused by attacks on crops by insects/pests and drought (Fig. 2).

Green biotechnology is a set of biological approaches that aim to provide
environmentally friendly solutions to the various reasons of low crop productivity due to
anthropogenic factors. ‶Anthropogenic″ refers to environmental change caused by people,
either directly or indirectly. This is possible because green biotechnology can be used to create
genetically modified crops that are resistant to insects/pests and consume relatively little water
during cultivation (Fig. 2).
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Figure 3. Benefits and risks of green biotechnology
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 The dual effect of green biotechnology is discussed by considering its benefits and
risks.

Potential benefits: The ability to introduce resistance to pests and diseases into
crops, maximize the yield of crops, give crops extra tolerance to adverse weather and
soil conditions, improve the nutritional value of some foods, and enhance the
durability of products when they are harvested and shipped (Fig. 3).

Potential risks: The transfer of genes from one species to another may also transfer
characteristics that cause allergic reactions [Human and health risks], and there will be
significant hazards if a developing nation does not have laws that guarantee small
farms have access to markets, infrastructure, productive resources, delivery systems,
and extension services [Socioeconomic risks] (Fig. 3).
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 Plant biotechnology
Principle of plant tissue culture.
Advantages of plant tissue culture.
Disadvantages of plant tissue culture.
Stages of plant tissue culture.
It's so lovely to
meet all of you!
Thank you for listening.