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Low Molecular Weight Proteins as Carriers for Renal Drug Targeting: Naproxen–Lysozyme (1991)

Franssen, Eric J. F. ; van Amsterdam, Ronald G. M. ; Visser, Jan ; [et al.]

Springer

Pharmaceutical research 8 (1991), S. 1223-1230

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ISSN: 1573-904X

Keywords: drug targeting ; low molecular weight proteins (LMWPs) ; carrier ; naproxen ; renal ; lysosomes

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology

Notes: Abstract Low molecular weight proteins (LMWPs), such as lysozyme, may be suitable carriers to target drugs to the kidney. In this study the antiinflammatory drug naproxen was covalently bound to lysozyme (1:1). Pharmacokinetics of the conjugate, naproxen–lysozyme (nap-LYSO), were compared to that of an equimolar mixture of uncoupled naproxen with lysozyme in freely moving rats. Similar plasma kinetics and organ distribution for native lysozyme and the drug conjugate were observed (Clp = 1.2 and 1.1 ml/min; $$t_{1/2,\beta } $$ = 85 and 75 min, respectively). In case of the uncoupled naproxen–lysozyme mixture, a monoexponential plasma disappearance of naproxen with a $$t_{1/2} $$ of 2.8 hr was observed, coinciding with urinary excretion of naproxen metabolites (mainly 6-desmethylnaproxen sulfate; 6-DMN-S) between 2 and 8 hr after injection. Urinary recovery of total metabolites was 59% of the naproxen dose. In contrast, after injection of covalently bound naproxen, plasma levels of the parent drug were below the detection level, whereas naproxen was recovered as 6-DMN-S in urine over a period from 4 to 30 hr. However, only 8% of the administered dose was recovered as 6-DMN-S in urine, whereas 50% of the dose was recovered as naproxen metabolites in feces. Incubation experiments using purified renal tubular lysosomal lysates revealed that naproxen–lysozyme degradation ultimately results in a stable naproxen amino acid catabolite, naproxen–lysine (nap-lys). Hepatic uptake and biliary excretion of this catabolyte were demonstrated in isolated perfused rat livers. Further, an equipotent pharmacological activity relative to parent naproxen was observed. We conclude that LMWPs such as lysozyme are indeed suitable carriers for site-specific delivery of drugs to the kidney. Although naproxen covalently bound to lysozyme did not release the parent drug, it did result in renal release of a stable and active catabolite, naproxen–lysine.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1015835325321

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Low Molecular Weight Proteins as Carriers for Renal Drug Targeting: Naproxen Coupled to Lysozyme via the Spacer L-Lactic Acid (1993)

Franssen, Eric J. F. ; Moolenaar, Frits ; de Zeeuw, Dick ; [et al.]

Springer

Pharmaceutical research 10 (1993), S. 963-969

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ISSN: 1573-904X

Keywords: drug targeting ; low molecular weight proteins ; carrier ; naproxen ; spacer engineering ; renal ; lysosomes ; L-lactic acid

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology

Notes: Abstract Low molecular weight proteins (LMWPs) are potential carriers for targeting drugs to the kidney. To test whether ester bonds are suitable for the reversible drug conjugation, the antiinflammatory drug naproxen (Nap) was conjugated to the LMWP lysozyme (LYSO) via an ester bond using an L-lactic acid spacer (Nap-lact-LYSO, 1:1:1). The distribution and degradation of the conjugate in rats were compared to those of an equimolar mixture of free drug and LMWP and of a directly coupled conjugate without spacer (Nap-LYSO). The plasma clearance of Nap-lact-LYSO closely resembled that of Nap-LYSO and LYSO itself. Its major accumulation site appeared to be the kidney as demonstrated by extracorporal -γ-camera counting of the LMWP. Renally released naproxen was excreted in the urine as 6-desmethyl-naproxen-sulfate (6-DMN-S). Apparently the kidneys represent the main sites of demethylation and sulfation after administration of the LMWP-coupled drug. In addition, the renal excretion of naproxen (including its metabolites) was significantly delayed and sustained as compared to that after injection of uncoupled naproxen. Using the L-lactic acid spacer LMWP conjugation, the renal selectivity of Nap was increased 5.6 ± 0.41-fold. Additional in vitro studies with Nap-lact-LYSO revealed that renal generation of the parent drug coincided with formation of low molecular weight catabolites, mainly as naproxen-L-lactic acid-lysine (Nap-lact-Lys). This indicated that in vitro the rate of cleavage of the ester bond is significantly slower than digestion of the carrier backbone itself. It is concluded that for drugs with free carboxyl groups the coupling to LMWPs via α-hydroxy acids can result in renal-specific delivery and endorenal drug release.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1018946219057

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