Schlesinger Nailed It! Assessing a Key Primary Pharmacodynamic Property of Phages for Phage Therapy: Virion Encounter Rates with Motionless Bacterial Targets

Drugs and Drug Candidates Pub Date : 2023-08-18 DOI:10.3390/ddc2030034

S. Abedon

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Abstract

Bacteriophages (phages) are viruses of bacteria and have been used as antibacterial agents now for over one-hundred years. The primary pharmacodynamics of therapeutic phages can be summed up as follows: phages at a certain concentration can reach bacteria at a certain rate, attach to bacteria that display appropriate receptors on their surfaces, infect, and (ideally) kill those now-adsorbed bacteria. Here, I consider the rate at which phages reach bacteria, during what can be dubbed as an ‘extracellular search’. This search is driven by diffusion and can be described by what is known as the phage adsorption rate constant. That constant in turn is thought to be derivable from knowledge of bacterial size, virion diffusion rates, and the likelihood of phage adsorption given this diffusion-driven encounter with a bacterium. Here, I consider only the role of bacterial size in encounter rates. In 1932, Schlesinger hypothesized that bacterial size can be described as a function of cell radius (R, or R1), as based on the non-phage-based theorizing of Smoluchowski (1917). The surface area of a cell—what is actually encountered—varies however instead as a function R2. Here, I both provide and review evidence indicating that Schlesinger’s assertion seems to have been correct.

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施莱辛格做到了!评估噬菌体治疗的关键初级药效学特性:病毒粒子与静止细菌靶标的相遇率

噬菌体(噬菌体)是细菌的病毒，被用作抗菌剂已有一百多年的历史。治疗性噬菌体的主要药效学可以总结如下:一定浓度的噬菌体可以以一定的速度到达细菌，附着在表面显示合适受体的细菌上，感染并(理想情况下)杀死那些已经被吸附的细菌。在这里，我考虑的是噬菌体到达细菌的速度，这可以被称为“细胞外搜索”。这种搜索是由扩散驱动的，可以用所谓的噬菌体吸附速率常数来描述。这个常数反过来又被认为可以从细菌大小、病毒粒子扩散速率以及噬菌体在与细菌的扩散驱动下吸附的可能性的知识中推导出来。在这里，我只考虑细菌大小在接触率中的作用。1932年，Schlesinger基于Smoluchowski(1917)的非噬菌体理论，假设细菌的大小可以被描述为细胞半径(R，或R1)的函数。然而，单元格的表面积——实际遇到的面积——作为一个函数R2而变化。在这里，我提供并回顾了证明施莱辛格的断言似乎是正确的证据。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Drugs and Drug Candidates

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