Book Volume 7
Preface
Page: ii-ii (1)
Author: Hafiz Ishfaq Ahmad and Muhammad Hamid
DOI: 10.2174/9789815165074123070002
Livestock Domestication
Page: 1-16 (16)
Author: Hafiz Ishfaq Ahmad*, Musarrat Abbas Khan and Aftab Shaukat
DOI: 10.2174/9789815165074123070004
PDF Price: $15
Abstract
Domestication of animals was one of the most significant changes in human
history, beginning with a long-term connection between hunter–gatherers and wolves
more than 15,000 years ago. Between 11,000 and 4,000 years ago (approximately the
Neolithic to the Bronze Age), when mixed-crop farming communities emerged, a
variety of additional species, including sheep, goats, cattle, pigs, poultry, and horses,
were introduced into human society. The domestication of livestock had a profound
impact on human society. It allowed humans to produce more food and live in larger,
more complex societies. It also led to the development of trade and commerce, as
surplus animals and animal products could be exchanged for other goods. Animals
have played various roles since their domestication, ranging from being tolerated to
being revered in ceremonial activities to supplying humans with additional advantages,
such as food, clothing, building materials, transportation, herding and hunting. The
diversity of phenotypes, seen in various domesticated species has provided generations
of scientists with a useful model for studying evolution. The domestication process has
led to the development of many different breeds of livestock; each adapted to specific
environments and tasks. In modern times, livestock domestication continues to play a
significant role in food production and agriculture, and it remains an important part of
many cultures worldwide.
Genomics and Biotechnological Advancements in Fisheries, Poultry
Page: 17-39 (23)
Author: Nadia Mushtaq, Aqsa Arooj, Zainab Javed, Hafiz Ishfaq Ahmad, Javaria Bashir and Abdul Jabbar*
DOI: 10.2174/9789815165074123070005
PDF Price: $15
Abstract
Biotechnological advancements have started gaining importance for
subsidizing conventional breeding strategies to the latest cost-effective techniques that
enhance the yield and are robust. This effort aims at showcasing the different strategies
adapted to bring up the production curve in fisheries, poultry and livestock by using the
latest biotechnological assays and procedures. A better understanding of disease
resiliency in animals and increasing the growth rate of fish, domestic animals and
poultry birds can help cope with the increased demand for milk, meat, eggs and
proteins worldwide. The genome engineering tools, such as CRISPR-Cas9, single
nucleotide polymorphism, somatic cell nuclear transfer, zinc-finger nucleases, Sperm
Transfection–Assisted Gene Editing (STAGE) and cloning, possess the ability to alter
the genome either by knocking in or knocking out of the genes for better selection of
the breeds. Genomic estimated breeding values (GEBVs) are devised using the gene
markers without prior knowledge of the exact gene location across the chromosome.
These predictive values help in gene insertion or gene deletion in the host. The
breeding programmes initiative can bring up advantages by managing the resources and
growing the yield. The biotechnology applications should be incorporated with
progressing customary reproducing and improvement programs to meet the growing
challenge of feeding the population of 9 billion.
Successful Genomics and Biotechnologies in Livestock Production
Page: 40-54 (15)
Author: Nimra Irem, Abdul Jabbar*, Nadia Mushtaq, Hafiz Ishfaq Ahmad and Aftab Shaukat
DOI: 10.2174/9789815165074123070006
PDF Price: $15
Abstract
Health maintenance will be considered one of the major challenges for
effective livestock production in the next decades. The demand of the world for food
products from animals is estimated to increase by more than 70% by the end of 2050.
To meet the increasing demand, such advanced methods and techniques are required,
which have minimal effect on the environment. Over the last 10 years, the selection of
genomics has been presented in various major livestock species. This selection has
shown almost double the progress in genetics. Though, extra improvements in the field
of genetics are required. The information on genomics with increased complexity
(including epigenomic, genomic, microbiome data and transcriptomic) have been
combined with the advanced biotechnologies for the purpose of a cost-effective method
of collection and use, which will be then responsible for a most important contribution.
Such technologies on implementation will permit genetic gains in the traditional traits
of milk production along with low heritable traits, i.e., fertility and health.
Application of Biotechnologies in National Livestock Development Programs
Page: 55-66 (12)
Author: Hafiz Ishfaq Ahmad*, Muhammad Hamza Zaman and Aftab Shaukat
DOI: 10.2174/9789815165074123070007
PDF Price: $15
Abstract
Globally, livestock production is growing faster than any other sector and by
2025, livestock is predicted to become the most important part of the agricultural sector
in terms of its added value to the national economy. The use of biotechnology will lead
to a distinct shift in economic returns from livestock. 43% gross value of agricultural
production is currently held by livestock. If we speak about the role of livestock in
developed countries, then it holds more than 50% of total agricultural production. At
the same time, in the case of developing countries, this share reduces to almost 30%
due to a lack of biotechnology or not using enough modern sources. In most developing
countries, biotechnological applications relating to livestock need to be suitable for
animal owners who are resource-poor small-scale operators who own little or no land
and few animals. The rapid increase, in developing countries, of livestock population is
due to a rise in population growth, and a desire to change their lifestyle. Urbanization is
also a source of passive or active income for them.
Omics and Bioinformatics for Livestock Production
Page: 67-83 (17)
Author: Muhammad Muddassir Ali, Furqan Awan* and Muhammad Hamid
DOI: 10.2174/9789815165074123070008
PDF Price: $15
Abstract
Due to increasing knowledge about the function of genes and proteins in
various living organisms, the genomics of farm animals is a major concern for
researchers. Different applications like increased milk, meat, and wool production are
the main drivers of the increase in farm animal genome activities. Data about the gene
sequences of different organisms, like fish, cows etc., can be obtained from warehouses
that are expanding quickly. However, this is protected and owned by many data
processing and storage authorities. In this chapter, we will discuss genome project
measures and animal bioinformatics that increase scientists' interest in advancing
developments in the field.
Genetic Improvement of Indigenous Sheep And Goats
Page: 84-100 (17)
Author: Bilal Ahmad, Usman Ali Ashfaq, Nazia Nahid, Muhammad Shareef Masoud, Mahmood-ur-Rahman Ansari, Rashid Bhatti and Muhammad Qasim*
DOI: 10.2174/9789815165074123070009
PDF Price: $15
Abstract
The breeding of small ruminants has a huge social and environmental impact
globally. Due to rising production costs concerning milk prices and customer desire for
harmless and superior quality food, efficient features have become crucial for effective
breeding programs. Most farmers are unaware of the strategic value of genetic
improvement and lack the incentive to support breeding projects on their own, so
government money has been the primary funding source for breeding initiatives.
Genetic markers have been employed to help with paternity determination,
confirmation, variety protection, and breeding standard selection. An integrated
strategy is required to assist in the creation of breeding programs and solve the
problems of improving indigenous breeds, like sheep and goats. Genome selection and
innovative reproductive technologies are examples of scientific progress that will allow
for quicker and more effective genetic improvement. The whole strategy should
improve the competitiveness and long-term survivability of the indigenous population.
This chapter is focused on determining particular breeding targets of sheep and goats
that represent the sector's priorities and demands, gene-assisted selection, and the
capabilities of disease-free indigenous populations.
Application of Biotechnology to Livestock Feed Improvement
Page: 101-115 (15)
Author: Irfan Ahmed*, Zahid Kamran, Muhammad Yousaf, Ahmad Kamran Khan and Shahzad Munir
DOI: 10.2174/9789815165074123070010
PDF Price: $15
Abstract
Feed and nutrition play a crucial role in the quality and quantity of livestock
production, both ruminants and non-ruminants. As a result, the supply of feedstuff
resources has not met the needs of animal populations, which might lead to decreased
performance, poorer health, increased erosion, and overgrazing, which would increase
the number of livestock animals. To meet animal protein requirements, feed availability
with a low price containing high quality is a big challenge for nutritionists in the future
quality. Conventional methods were used to increase livestock improvements,
including livestock diseases, management, nutrition, genetics and breeding that resulted
in enhancing livestock production. Currently, these methods are no longer sustainable;
modern techniques, especially biotechnology, are required for optimum productivity.
Utilizing natural and organic resources, for controlling food-borne diseases, modern
biotechnology techniques are needed to implement the bitterness of the livestock
population, increasing food safety and reducing poverty for livestock farmers. Due to
advances in livestock nutrition, there has been a focus on enhancing livestock
requirements, to understand the demand and availability of the ingredients, and
composition and formulating cost-effective diets with optimum nutrient availability.
Sensing of Nutrients and the State of Sensors for the mTORC1 Pathway that are Controlled by Amino Acids
Page: 116-125 (10)
Author: Muhammad Zahid Farooq* and Hafiz Ishfaq Ahmad
DOI: 10.2174/9789815165074123070011
PDF Price: $15
Abstract
The mechanistic target of rapamycin (mTORC1) is an expert cell production
controller which reacts to a different set of natural information sources, such as amino
acids. Various proteins have been differentiated recently to help communicate amino
acid accessibility to mTORC1. Rag guanosine triphosphatases (GTPases) transfer
amino acid accessibility to the mTORC1 duct, and the mTORC1 apprentice to the
amino acid on the Lysosome in a conventional manner. Later on, several sensors were
exposed for the amino acid-reinforced mTORC1 pathway, including Leucine, Argina,
and S-adenosyl methionine. The representation of these sensors is essential to explain
why cells change the pathways of amino acid detection requirements. Here, we survey
these new advances and feature the assortment of further inquiries that rise out of the
recognizable proof of these sensors.
Genome to Phenome: Improving Animal Health, Production, and Well-Being
Page: 126-143 (18)
Author: Amjad Islam Aqib*, Muhammad Arslan Akbar, Khazeena Atta, Maheen Murtaza and Sana Zia
DOI: 10.2174/9789815165074123070012
PDF Price: $15
Abstract
The improvement of animal health can be achieved through variations in
local and regional conditions (e.g., altitude). In addition to biotic stress, abiotic stresses
include changes in the temperature, illnesses, pests, and enhancing biotic stress.
Effective farm animals must maintain fitness as one of their main responsibilities. As
the demand for animal protein, resistance to the previous drug, and the drive to reduce
antibiotic use in agriculture grow, this task will only become more difficult. The
susceptibility to all disorders may differ genetically, but the variation has not yet been
fully utilized. It is difficult and costly to measure this alteration in part because it is
difficult and expensive. Therefore, genomics can contribute to the refinement of animal
fitness. In this chapter, we will examine the concept of resistance, variation in
susceptibility, and elasticity, as well as provide examples, present a few of the most
recent developments in livestock and pigs, and briefly discuss the application of gene
enhancement to addressing disorder resistance. Ensure clients can select from
conventional meals, healthy choices (lean meats), dietary improvements, and food
raised using preferred farming practices (natural, without antibiotics).
Monitoring Animal Behavior and Control Using Wireless Sensor Technologies
Page: 144-157 (14)
Author: Muhammad Hamid* and Hafiz Ishfaq Ahmad
DOI: 10.2174/9789815165074123070013
PDF Price: $15
Abstract
The constantly rising need for dairy productivity farm automation is a key
concern in today's world. A necessity for technology that would result in lower costs
and labor inputs while increasing agricultural output exists, and cattle health
monitoring should be given top attention to achieve this requirement. Remote
monitoring of animal behavior in the environment can aid in managing both the animal
and the animal's influence on the environment. Geographical positioning systems
(GPS) collars that record animal whereabouts with high temporal frequency enable
researchers to study animal behaviour and environmental interactions. This paper has
discussed how to track and control animals using wireless detector strategies. For a
long time, the only mode to track wildlife was to objectively check and notice the
program and habits of a beast and set a label on it, and optimism that eventually that
same beast would be recalled. But that’s not sufficient to study the performance of
animals. The study and nursing of animals have always been a subject of great
curiosity, but studying the behavior of animals is a tough task due to the problems of
shadowing and classifying their action. Currently, technology allows designing WSN,
making these tasks easier to carry out. Studying the conditioning of wild animals is
grueling due to the difficulties of shadowing and classifying their conduct. In this work,
we have discussed the behavioral and hierarchical wireless detector network mounted
in the demesne to collect information about beast behavior using a device enforced on
them. Tracking is one of the most effective ways; with minimum trouble and lower
charges, we get a detailed position or movements of similar animals through GPS on a
daily basis through computer data.
Use of Artificial Intelligence in Assessing the Livestock Management
Page: 158-169 (12)
Author: Muhammad Hamid*, Nadia Mushtaq, Hafiz Ishfaq Ahmad and Ghulam Haider
DOI: 10.2174/9789815165074123070014
PDF Price: $15
Abstract
In the livestock sector, artificial intelligence is crucial. The livestock
business needs to make improvements to artificial intelligence right away. With the aid
of artificial intelligence, livestock farms will be able to make the processes automatic
with reduced major costs and an improvement in the quality of livestock products.
Artificial intelligence assists livestock farms in gathering data and performing analysis
accurately according to consumer behaviour prediction, such as buying patterns,
leading trends, etc. The livestock business will undergo significant upheaval thanks to
artificial intelligence. Many dairy farms and local farmers utilize animal feed without
considering how it will affect the milk and the animals. AI use will undoubtedly
significantly impact the quality of the forage and the animals' way of life as AI is
increasingly widely used and accessible. Most dairy sector activities will be automated,
and data about past farm operations will be generated. Farmers are now turning to
smarter approaches to help regulate the right use of land, water, and energy needed to
feed the world's population and alleviate the global food problem in response to the
expanding population. By utilizing machinery and monitoring systems, AI technology
has changed farming and cattle-related businesses.
Next-generation Sequencing in Veterinary Medicine Technologies to Improve Diagnosis, Control, and Management of Livestock Diseases
Page: 170-187 (18)
Author: Muhammad Ijaz and Muhammad Muddassir Ali*
DOI: 10.2174/9789815165074123070015
PDF Price: $15
Abstract
Next-generation sequencing has changed the study of genetics. NGS
technology is predicted to be significant in veterinary care and animal husbandry. With
the development of modern techniques, genomes can now be sequenced considerably
more quickly and accurately. In the current review, we detail the many sequencing
techniques that are accessible and also go over a few biological topics where using
next-generation sequencing might lead to whole new directions in veterinary research.
Large volumes of genomic, transcriptomic, and proteomic data may now be analysed
by researchers thanks to the advent of high throughput molecular technologies and
accompanying bioinformatics. The volume of DNA sequence information that can be
generated using Next Generation Sequencing (NGS) technology is a glaring illustration
of this stage. The identification and quantification of proteins in a given sample have
also been made easier by recent advancements in high-precision mass spectrometry and
protein and peptide separation efficiency. The way biological and evolutionary
processes are investigated at the molecular level is beginning to change due to these
technological advancements, which are also being utilised to research infectious
illnesses in animals. To better understand how next-generation sequencing functions
and how it might be applied to veterinary medicine for the sake of disease management
and control, this chapter focuses on presenting existing and projected insights.
Use of Genomics in the Diagnosis and Treatment of Livestock and Animal Diseases
Page: 188-213 (26)
Author: Awais Ghaffar*, Muhammad Ijaz, Shahid Hussain Farooqi, Muhammad Muddassir Ali, Ahmad Ali, Ahmad Umar and Rehan Shahid
DOI: 10.2174/9789815165074123070016
PDF Price: $15
Abstract
The use of biotechnology has proved to be a key factor in handling different
livestock problems. Many issues have proved to be silent killers, and their appropriate
diagnosis and treatment are the need of the hour. Advancement in biotechnology and
genomics is being used in preventive and clinical medicine, production of recombinant
biotechnology-derived vaccines, molecular gene cloning, application of polymerase
chain reaction (PCR), Polymerase chain reaction-restriction fragment length
polymorphism (PCR-RFLP), Real-time polymerase chain reaction (RT-PCR), gene
therapy and many more. This chapter will cover the use of genomics and biotechnology
in veterinary medicine.
Role of Recombinant Vaccine in Livestock
Page: 214-228 (15)
Author: Ahmad Ali*, Muhammad Ijaz, Muhammad Anas Naeem, Ramsha Shakeel, Awais Ghaffar, Yasir Razzaq Khan, Muhammad Zeeshan Zafar, Kashif Hussain, Muhammad Shahid, Omer Naseer, Ameer Hamza Rabbani and Mahar Abdul Qudus
DOI: 10.2174/9789815165074123070017
PDF Price: $15
Abstract
A lot of diseases affect animals which need treatment. Antibiotics and other
drugs have been widely used in the treatment. Drug residues in milk and meat are the
main issues and pose health risks to humans. A vaccine is the only solution to keep
animal products safer from drug residues. Modern veterinary vaccine history started in
the 19th century when Edward Jenner used antigens from cowpox pustules. A vaccine
is a weakened organism or part of an organism that is given to animals to produce
immunity by the body. Soon after the development of vaccines, safety issue arises.
Especially live attenuated vaccine was a matter of concern as it may revert to cause
disease. Nowadays, most of the livestock vaccines are live attenuated or killed.
Vaccines have been developing against bacteria, viruses and parasites also. Animal-origin products are also contaminated with parasite infection and are a source of
infection to other animals and humans. Parasites usually stay in the gastrointestinal
tract of animals, and oocytes are disseminated through feces into the environment,
which are transmitted to other animals. Vaccines are cost-effective methods to prevent
diseases in animals and humans. It not only enhances animal meat and milk production
but also saves humans from zoonotic diseases. Without vaccines against major animal diseases, it will not be possible to feed 7 billion people with proteins. Zoonotic
diseases, such as brucellosis and Leptospirosis, will be more prevalent in the world
without the vaccination of animals. Rinderpest is almost eradicated from the globe and
will be the second disease after smallpox which is diminished through proper
vaccination and surveillance.
Role of Nanoparticles in Veterinary Medicine and as Feed Additive in Livestock
Page: 229-242 (14)
Author: Saba Saeed, Gulnaz Afzal, Shumaila Kiran*, Hafiz Ishfaq Ahmad, Muhammad Zeshan Haider and Saba Naz
DOI: 10.2174/9789815165074123070018
PDF Price: $15
Abstract
Nanotechnology is gaining more popularity in various applied fields due to
its versatile applications. Different world challenges, including pollution, resistance
against antibiotics, disorders in human/ animal digestive systems, contaminants of
feeds, health management & feed efficiency, etc., can be overcome by using
nanoparticles. Nanoparticles can be used as antibiotics, as feed additives, and can also
be used against mycotoxin and as biocidal agents. The efficiency and productivity of
various items could be improved using multiple supplements like enzymes, yeast, plant
extracts, etc. Many efforts are going on to improve productivity and efficiency using
different supplements, such as yeast, enzymes, probiotics, and plant extracts.
Nanomaterials can effectively replace all. In this chapter, we will discuss various types
of metal/metal oxide nanoparticles and their role in livestock as feed additives, pointing
out their level of toxicity as well. The current and future regarding the permissible
nanomaterials to be used in veterinary-related products will also be highlighted.
Subject Index
Page: 243-248 (6)
Author: Hafiz Ishfaq Ahmad and Muhammad Hamid
DOI: 10.2174/9789815165074123070019
Introduction
Recent Trends in Livestock Innovative Technologies explores the most recent developments and developing trends in the livestock farming industry. The book delves into the application of innovative technologies in various aspects of livestock production, management, and health through edited chapters. The book starts with an outline of the difficulties the livestock sector faces and the necessity for technological solutions to these difficulties. Subsequent chapters cover innovations in this area. Key topics include: Advances in genetics and breeding methods: Contributing authors stress the possible impact of issues like marker-assisted selection, genomic selection, and gene editing on the future of animal breeding. Precision livestock farming: The use of sensor technologies, data analytics, and automation to monitor and control livestock production systems more effectively. The authors examine how these technologies enable real-time monitoring of environmental variables, animal activity, and health, which enhances production, animal welfare, and resource use. The management of feed and nutrition in livestock production: The book explores cutting-edge feed formulations, precise feeding systems, and alternative feed sources that can increase feed efficiency, lessen negative effects on the environment, and improve animal health. Fresh methods for illness prevention and management, such as the use of vaccines, diagnostics, and biosecurity measures. Social and ethical issues related to the adoption of cutting-edge livestock technologies. The authors attempt to give a fair assessment of the advantages and drawbacks of these technologies, and address concerns about animal welfare, environmental sustainability, and public perception of current farming practices. Recent Trends in Livestock Innovative Technologies is an informative resource for researchers, professionals, and policymakers interested in staying up-to-date with the advancements and future directions of the livestock industry.