Dr. Arthur Kornberg's comment on Penicillin

Dr. Arthur Kornberg and his family ---- from the book "For the love 

of enzymes: The odyssey of a Biochemist. Harvard University Press. 

1991.

Dr. Arthur Kornberg (1918-2007, who received the Nobel Prize

 of Physiology or Medicine in1959 and first done the chemical 

synthesis of a infectious phage, a virus of bacteria in 1967) wrote 

about penicillin.

---------------------------------------------------------------------------------

  Penicillin and other antibiotics are the most dramatic 

therapeutic advance in medicine in my lifetime. When I was a 

student and intern before the advent of antibiotics, the 

treatment of lobar pneumonia was discouraging ineffective. 

One out of four patients died. Subacute bacterial endocarditis 

was invariably fatal. Rheumatic fever and acute nephritis 

were prevent.        

Many people know that antibiotic therapy was not discovered 

at bedsides nor even in a clinical pharmacology laboratory. 

Bullrings in Spain have a statures of Alexander Fleming, 

who in 1929 noticed the inhibition of bacterial growth around 

penicillin mold contaminated his Petri plate.        

The apotheosis of Fleming gored bullfighters is exaggerated 

because the practical use of the penicillin mold was not 

discovered by Fleming. It took Ernst Chain, a biochemist, 

and Howard Florey, a pathologist, to apply this knowledge 

ten years later to isolate penicillin and demonstrated its 

clinical utility.        

   There is much more to the penicillin story than that. 

Basic inquiries and findings essential to Fleming's discovery 

started at least fifty years earlier. Fleming would never have 

made his observation without the agar Petri plate. But, more 

important, he would never have understood what he saw on 

the plate were it not for the firm foundations of bacteriology 

and immunology.       

One might assume that Chain and Florey undertook the 

isolation of penicillin because of its possible clinical potential. 

Not at all. With the encouragement of Florey, Chain started 

his research on penicillin only because he was curious about 

the dissolution of bacterial walls by enzymes such as lysozyme. 

He thought penicillin was an enzyme too and wanted to 

understand the mechanism of its action. He surprised to find 

that penicillin was a molecule small enough to pass readily 

through the pores of a dialysis membrane which stopped 

passage of molecules as large as enzymes. 

Penicillin was not enzyme at all. This discovery immediately 

presented the possibility that penicillin, as a low-molecular-

weight compound, could be administered as a drug to animals. 

With the technique of freeze-drying, which had just become 

available, Chain was able to concentrate and preserve 

penicillin and then to prove its therapeutic efficacy.       

  Why were Chain and Florey so quickly to test their very 

crude penicillin preparations for clinical efficacy?  Their 

prompt decision was likely conditioned by the discovery in 

the mid-1930s that sulfonamides inhibit microbes and yet are 

not toxic to animals. 

Thus, an agent could selectively interrupt growth of microbes 

without affecting the animal host, and this observation gave 

Chain and Florey the confidence to test their penicillin prepa-

rations in infected mice.       

It may also explain why Fleming, ten years earlier, believing 

that only the host immune system could combat infections, 

regarded chemotherapy as implausible and so failed to test 

his crude penicillin preparations for therapeutic value. 

I choose penicillin as an example of the importance of basic 

research because its history is so recent and dramatic.   

---------------------------------------------------------------------

Arthur Kornberg: For the love of enzymes: The Odyssey of a 

Biochemist. Harvard University Press. 1991.

Any questions:  write to Keiji Hagiwara, MD

                                      keijihagiwara@gmail.com

Haemophilus influenzae(2)

Photo )  Colonies of Haemophilus influenzae on the chocolate agar plate.

                 (Dr. Mizuno, Department  of Clinical Laboratory, Yamaguchi

                  University School of Medicine)

Photo )  Electron-microscopic graph of H. influenzae.

             The shape of this bacteria is round or rods like. Green colour was

             added later, not the real colour. 

             (Dr.Dennis Kunkel, Dennis Kunkel Microscopy, Inc, Kailua, HI)

Any questions:

             write to Keiji Hagiwara, MD

             Kami-Ube Pediatric Clinic,

             1) keijihagiwara@gmail.com   2) keiji-hagiwara@umin.ac.jp

           

Haemophilus influenzae (1)

Photo )  H. influenzae are observed inside of white blood cells.

               (Dr.Rebecca Buxton, Department of Pathology, University of Utah)

Photo ) H. influenzae in the sputum .

            (Dr. Rebecca Buxton, Department of Pathology, University of Utah)

~~~~~~~~~~~~~~~~~

Haemophilus influenzae

~~~~~~~~~~~~~~~~~

This bacteria( = Pfeiffer's bacilli) once thought to be a cause of  influenza(=Flu).

i) Microscopic findings: round or lods in shape, Gram stain(-)

                                       

ii)Type: divided into non-capsular type and capsular type.

             Capsular type:  Serovar (5 types; a, b, c, d, e, f )

                  ✭ type b is predominant, especially in acute meningitis and epiglottis.

iii) Type of diseases in childhood:

                   1) common cold: no data is  available.

                   2) otitis media:  non-capsular type is common.

                   3) acute epiglottis: very few in Japan.

                   4) bronchitis & pneumonia: non-capsular type is common.

                   5) meningitis: type b is dominant in Japan.

iv) Prevention: inactivated vaccine against Haemophilus influenzae type b 

                        is available.

Any questions:  write to Keiji Hagiwara, MD

                         E-mail: keijihagiwara@gmail.com