Exploring the biogenic peptide’s potential in combating bacterial zoonosis: application and future prospect

IF 1.8 4区 农林科学 Q2 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Saleha Tahir, R. Z. Abbas, Warda Qamar, M. Arshad, M. A. Alvi, M. S. Mahmood, Tean Zaheer
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Abstract

Abstract Worldwide, microbial infections have a serious impact because they cause infectious diseases, death, and significant economic losses. Zoonosis is now a major public health issue on a global scale because of the fast expansion of human exploitation of nature and animal husbandry. Notably, in the past 30 years, over 30 novel human infections have been discovered, 75% of which fall under the category of zoonosis. Resistant strains have emerged as a result of improper use of antibiotics and insufficient infection management posing a serious risk to both public health and the global economy. As alternatives, antimicrobial peptides are showing good results. The majority of living things use antibacterial peptides (ABPs) as a key part of their natural defenses against invading infections. These peptides are cationic, amphipathic, and relatively tiny with varied sequences, structures, and lengths. For the delivery of these efficacious biological peptides, nanoparticles are providing opportunities for effective, safe, and viable delivery. An innovative method of treating infectious diseases is demonstrated by nanoparticles and antibacterial peptides. When ABPs are combined with carrier nanoparticles to optimize distribution, their half-life may be increased, allowing for lower dosages and ultimately lower toxicity. For biological applications, ABPs and nanoparticle conjugates have become effective methods, enabling the treatment, prevention of disease, and detection. More than 50 peptide medications have been made available for purchase on the market as of 2018. Around 25 billion USD is spent on peptide medications each year, including ABPs. But still, there is a gap in the distribution of these ABPs as an alternative to synthetic antibiotics. It might be due to the high cost of these goods. Thus, scientists, researchers, and commercializing companies should work together so that these ABPs with a safe delivery system should be available in the market to combat resistant strains of bacteria. In doing so, we draw attention to the significant advancements made in the field as well as the difficulties still encountered in developing imaging species, active therapies, and nano-drug delivery systems that are functionalized with peptides and proteins for clinical use.
探索生物肽抗细菌性人畜共患病的潜力:应用与展望
摘要在世界范围内,微生物感染具有严重的影响,因为它们会导致传染病、死亡和重大经济损失。由于人类对自然和畜牧业的开发迅速扩大,人畜共患病现在是全球范围内的一个主要公共卫生问题。值得注意的是,在过去30年中,已经发现了30多种新型人类感染,其中75%属于人畜共患疾病。抗生素使用不当和感染管理不足导致耐药菌株出现,对公共卫生和全球经济构成严重风险。作为替代品,抗菌肽显示出良好的效果。大多数生物使用抗菌肽(ABPs)作为其抵抗入侵感染的天然防御的关键部分。这些肽是阳离子的、两亲性的,并且相对较小,具有不同的序列、结构和长度。为了递送这些有效的生物肽,纳米颗粒为有效、安全和可行的递送提供了机会。纳米颗粒和抗菌肽证明了一种治疗传染病的创新方法。当ABP与载体纳米颗粒结合以优化分布时,它们的半衰期可能会增加,从而降低剂量并最终降低毒性。对于生物学应用,ABP和纳米颗粒偶联物已成为有效的方法,能够治疗、预防疾病和检测。截至2018年,市场上已有50多种肽药物可供购买。每年约有250亿美元用于肽类药物,包括ABP。但是,作为合成抗生素的替代品,这些ABP的分布仍然存在差距。这可能是由于这些商品的价格太高。因此,科学家、研究人员和商业化公司应该共同努力,使这些具有安全递送系统的ABP能够在市场上用于对抗耐药菌株。在这样做的过程中,我们提请注意该领域取得的重大进展,以及在开发用肽和蛋白质功能化的成像物种、活性疗法和纳米药物递送系统以供临床使用方面仍然遇到的困难。
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来源期刊
Annals of Animal Science
Annals of Animal Science 农林科学-奶制品与动物科学
CiteScore
4.00
自引率
5.30%
发文量
138
审稿时长
6-12 weeks
期刊介绍: Annals of Animal Science accepts original papers and reviews from the different topics of animal science: genetic and farm animal breeding, the biology, physiology and reproduction of animals, animal nutrition and feedstuffs, environment, hygiene and animal production technology, quality of animal origin products, economics and the organization of animal production.
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