The mechanisms of action of these antimicrobial agents target areas that do not exist in the human body or those with different structures,  making them supposedly harmless to humans and animals. However, I believe this is a significant misconception. The human intestinal  tract hosts an enormous number of bacteria, ranging from 100 trillion to 1,000 trillion, which far exceeds the 60 trillion cells in the entire human  body. The total weight of these bacteria amounts to about 2 kg, and it’s said that one-third of the weight of our excretions consists of bacteria.  Carrying around 2 kg of bacteria is akin to having a four-month-old kitten living inside your abdomen.

Food is chemically transformed and broken down by these bacteria, allowing nutrients to be absorbed through the intestinal walls.  This process is a vital function, and the gut flora (the ecosystem of microorganisms within the intestines) is absolutely essential  for human health. Antimicrobial agents, including antibiotics, indiscriminately attack a wide range of microbial populations, including those  in the gut. The notion that they are harmless to humans and animals is entirely wrong. It was once thought that about 30% of the body’s immune system was concentrated in the intestines, but recent research suggests that this  figure might be over 70%.

I have been providing propolis since 40 years ago when I lived in Brazil, and for the past 25 years, I’ve been offering Manuka honey since  moving to New Zealand. During this time, I have received various consultations and reports from our customers. As a result, I have come  to believe that human health (including pets) is determined by the microbial ecosystem within the intestines. If this ecosystem is healthy,  one is unlikely to fall ill. I firmly feel that bee products are the only truly reliable means of maintaining homeostasis, and I hope that as many  customers as possible will use these products to benefit their daily health. For a beekeeper like myself, nothing could be more fulfilling.

Yesterday, I received news about antimicrobial resistance (AMR) from our staff at the headquarters in Japan. The message said, ‘The Cabinet  Secretariat has placed a government advertisement in this morning’s Nikkei newspaper about antimicrobial resistance. This is the first time  I’ve seen an advertisement directly appealing to the general public (though there may have been similar ads before).  Does this mean that such a time has arrived?’ When I opened the linked government public relations page, I saw a very basic explanation about antibiotics.  Reading it, I couldn’t help but feel frustrated. What are they saying now, after all this time?  This is something that should have been taught as part of basic education from elementary school, and should be common knowledge for everyone.  It’s not just a responsibility but a duty of the citizens to understand this issue. What has the government  been doing about this problem until now? The phrase “I’m at a loss for words” really fits here.

Furthermore, it’s already too late to address this issue, and current medicine, particularly in the field of infectious diseases, is at a complete  standstill due to how delayed our response has been. There was a time when humanity believed that the invention of antibiotics had conquered infectious diseases, especially after the discovery of  penicillin. However, it eventually became clear that this belief was misguided. The mechanism of action for penicillin (specifically its bactericidal  and bacteriostatic properties) works as follows: Many bacteria survive by maintaining internal pressure with the help of a tough shell called the cell wall. An essential enzyme is needed to construct this cell wall, which must be strong enough to withstand the internal pressure of the cell.

The cell wall is made up of a mesh-like structure, where polymers of two alternating amino acids, called peptidoglycans, are linked together by peptide chains. The enzyme responsible for creating this mesh is known as a cross-linking enzyme. Penicillin mimics the  structure of this enzyme so well that the bacteria attempt to use it in place of the cross-linking enzyme. However, since penicillin is not the  same as the real enzyme, the bacteria fail to form a proper cell wall.  As a result, they are unable to maintain internal pressure, leading to a phenomenon called lysis, which ultimately causes their death. The above  describes the mechanism of β-lactam antibiotics, represented by penicillin, which target bacteria with cell walls. In addition, there are  various other mechanisms of action for antibiotics and antibacterial agents depending on the type of bacteria.