Saquinavir is an antiviral agent FDA- approved for the treatment of HIV. It inhibits HIV protease, a crucial enzyme for the HIV life cycle that cleaves viral polypeptides into essential proteins. When used in combination with nucleoside analog reverse-transcriptase inhibitors, protease inhibitors are highly effective in reducing HIV viral loads (1,2). In general, saquinavir is safe and well tolerated. Long-term exposure to protease inhibitors is associated with moderate hyperglycemia and insulin resistance in a minority of patients (3). We here report saquinavir as a causing agent of acutely developed extreme hyperglycemia in an HIV patient.

A 35-year-old HIV-infected male originating from Ghana presented with a hyperosmolar, hyperglycemic syndrome (glucose 48 mmol/L). He had been diagnosed with HIV-1 infection 2 years previously, with tenofovir, lamivudine, and saquinavir as initial combination antiretroviral therapy. He also suffered from decompensated liver cirrhosis with hepatitis B infection (Child-Pugh C). Previous glucose levels were normal, and HbA1c had not been measured before. At presentation, he used emtricitabine/tenofovir and saquinavir as combination antiretroviral therapy. He was not lipodystrophic, and there was no ketoacidosis. Signs of an acute infection were absent, and HIV viral load was 123 copies/mL (low, but not undetectable). The saquinavir concentration was 0.9 mg/L (4–5 times above the therapeutic range). Levels of HbA1c and C-peptide were 15.2% and 740 pmol/L, respectively. He was treated with insulin, and saquinavir was replaced by raltegravir to reduce pill burden. At discharge, the patient used insulin aspart 20 units t.i.d. and insulin glargine 24 units once daily. One week after the saquinavir replacement, the patient discontinued his insulin therapy because he suffered from symptoms of hypoglycemia, which disappeared after cessation of insulin therapy. Glucose concentrations then varied between 4.7 and 7.0 mmol/L, HbA1c had decreased from 15.2 to 8.3%, and C-peptide was 2,700 pmol/L in this normoglycemic situation. His viral load was undetectable.

In summary, we report an insulin-treated new-onset diabetes that recovered completely within 1 week after switching from saquinavir to raltegravir. The temporal relation of the development of diabetes during saquinavir therapy and the complete and prompt recovery after cessation thereof implicates saquinavir as the cause. The C-peptide level of 740 pmol/L in the hyperglycemic condition was relatively low and could suggest a diminished insulin production, while the subsequent level of 2,700 pmol/L in the later normoglycemic condition reflects a considerable insulin production. The duration of the evident hyperglycemia, which had developed while the patient used saquinavir, could not be determined retrospectively. The rapid recovery after cessation suggests a rather acute effect of saquinavir on the hyperglycemia. The elevated saquinavir concentration may have arisen as a consequence of deranged hepatic function since saquinavir is metabolized in the liver and adequate dosing is difficult. Most probably, the clinical diabetes emerged by the increasing insulin resistance and inhibition of insulin secretion by saquinavir (4,5) due to its diminished clearance and increased plasma levels. Caution and monitoring should be exercised when prescribing saquinavir in patients at high risk of developing diabetes and with liver dysfunction.

No potential conflicts of interest relevant to this article were reported.

M.A.D.v.Z. and H.W.d.V. drafted the manuscript with comments by A.I.M.H. H.W.d.V. is the guarantor of this work and, as such, had full access to all the data in the study and takes responsibility for the integrity of the data and the accuracy of the data analysis.

Parts of this study were presented in abstract form at the 23rd Annual Meeting of the Netherlands Association of Internal Medicine, and at the 12th International Symposium of Current Topics in Infectious Diseases, Grindelwald, Switzerland.

1.
Panel on Antiretroviral Guidelines for Adults and Adolescents. Guidelines for the use of antiretroviral agents in HIV-1-infected adults and adolescents. Department of Health and Human Services. Available from http://aidsinfo.nih.gov/contentfiles/lvguidelines/AdultandAdolescentGL.pdf. Accessed 12 July 2013
2.
Deeks
SG
,
Smith
M
,
Holodniy
M
,
Kahn
JO
.
HIV-1 protease inhibitors. A review for clinicians
.
JAMA
1997
;
277
:
145
153
3.
Dever
LL
,
Oruwari
PA
,
Figueroa
WE
,
O’Donovan
CA
,
Eng
RH
.
Hyperglycemia associated with protease inhibitors in an urban HIV-infected minority patient population
.
Ann Pharmacother
2000
;
34
:
580
584
4.
Schütt
M
,
Zhou
J
,
Meier
M
,
Klein
HH
.
Long-term effects of HIV-1 protease inhibitors on insulin secretion and insulin signaling in INS-1 beta cells
.
J Endocrinol
2004
;
183
:
445
454
5.
Gupta
AK
,
Cerniglia
GJ
,
Mick
R
,
McKenna
WG
,
Muschel
RJ
.
HIV protease inhibitors block Akt signaling and radiosensitize tumor cells both in vitro and in vivo
.
Cancer Res
2005
;
65
:
8256
8265
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