Tissue penetration of antimicrobials

Summary

Class	Antimicrobial	Blood	CNS	Vitreous	Urine	Prostate	Necrotic
Antibiotics: β-Lactams
Penicillins	β-lactamase inhibitors		–
	ampicillin		+				–
	piperacillin-tazobactam					+†
Cephalosporins	first-generation cephalosporins		–				–
	second-generation cephalosporins		–
	third-generation cephalosporins					+†
	cefepime						+
	ceftazidime		+				+
Cephamycins	cephamycins		–
Cephamycins	cefoxitin						–
Carbapenems	imipenem						+
Antibiotics: Non-β-Lactams
Aminoglycosides							–
Chloramphenicol	chloramphenicol						+
Fluoroquinolones			–?			+	+
Fosfomycin	fosfomycin					+
Lincosamides	clindamycin		–				+
Lipopeptides	daptomycin	+	–		+
Macrolides	macrolides		–			+
Nitrofurans	nitrofurantoin	–	–		+	–	–
Nitroimidazoles	metronidazole						+
Rifamycins	rifampin					+
Sulfonamides	trimethoprim-sulfamethoxazole					+
Tetracyclines	tetracyclines		–			+
Tetracyclines	doxycycline					+	+
Antivirals
	acyclovir / valacyclovir			+
	ganciclovir			+
	foscarnet
Antifungals
Azoles	fluconazole						+
Echinocandins		+			–
Class	Antimicrobial	Blood	CNS		Urine	Prostate	Necrotic

† if inflammation present

Prostate

Poorly penetrated by most antibiotics
Penetration is higher with a high concentration gradient, high lipid solubility, low degree of ionization, high dissociation constant, low protein binding, and small molecular size
Fluoroquinolones are the mainstay of therapy, though there is increasing resistance
TMP-SMX often used, though conflicting data about its penetration into the prostate
Minocycline, doxycycline, and macrolides achieve high levels in the prostate but are rarely indicated for the causative organisms
Third-generation cephalosporins and carbapenems can be used
Piperacillin, aztreonam, imipenem, and some aminoglycosides are likely useful

Bone

Essentially all antibiotics achieve similar bone-to-serum levels, with the exception of oral β-lactams which nevertheless have no worse outcomes1

References

^ Cornelia B. Landersdorfer, Jürgen B. Bulitta, Martina Kinzig, Ulrike Holzgrabe, Fritz Sörgel. Penetration of Antibacterials into Bone. Clinical Pharmacokinetics. 2009;48(2):89-124. doi:10.2165/00003088-200948020-00002.
a b c d e f g h i j k l m n o p q r L. Brockhaus, D. Goldblum, L. Eggenschwiler, S. Zimmerli, C. Marzolini. Revisiting systemic treatment of bacterial endophthalmitis: a review of intravitreal penetration of systemic antibiotics. Clinical Microbiology and Infection. 2019;25(11):1364-1369. doi:10.1016/j.cmi.2019.01.017.
a b Takashi Suzuki, Toshihiko Uno, Guangming Chen, Yuichi Ohashi. Ocular distribution of intravenously administered micafungin in rabbits. Journal of Infection and Chemotherapy. 2008;14(3):204-207. doi:10.1007/s10156-008-0612-5.
a b c d e f g h Timothy Felton, Peter F. Troke, William W. Hope. Tissue Penetration of Antifungal Agents. Clinical Microbiology Reviews. 2014;27(1):68-88. doi:10.1128/cmr.00046-13.
^ Tony H. Huynh, Mark W. Johnson, Grant M. Comer, Douglas N. Fish. Vitreous Penetration of Orally Administered Valacyclovir. American Journal of Ophthalmology. 2008;145(4):682-686. doi:10.1016/j.ajo.2007.11.016.
^ Luis F. López-Cortés, R. Ruiz-Valderas, M. J. Lucero-Muñoz, E. Cordero, M. T. Pastor-Ramos, J. Marquez. Intravitreal, Retinal, and Central Nervous System Foscarnet Concentrations after Rapid Intravenous Administration to Rabbits. Antimicrobial Agents and Chemotherapy. 2000;44(3):756-759. doi:10.1128/aac.44.3.756-759.2000.