Why does combining zidovudine with valganciclovir cause pancytopenia?

Both are nucleoside analogs that incorporate into DNA of rapidly dividing cells. Bone marrow progenitors divide fast, so two drugs jamming DNA replication at once overwhelm the marrow's compensatory capacity, causing all three cell lines to drop.

What is the difference between acyclovir toxicity and ganciclovir toxicity?

Acyclovir causes crystal nephropathy by precipitating in renal tubules, especially with dehydration. Ganciclovir and valganciclovir cause myelosuppression by incorporating into host cell DNA in rapidly dividing bone marrow cells. Same drug family, opposite target organs.

Which HIV drug class has the fewest drug interactions?

Integrase strand transfer inhibitors (INSTIs) like dolutegravir and bictegravir have the fewest drug interactions. They do not significantly affect CYP enzymes. The main concern is chelation with polyvalent cations like calcium and iron, which is managed by separating doses.

Why can protease inhibitors cause Cushing syndrome with inhaled steroids?

Protease inhibitors and pharmacokinetic boosters like ritonavir and cobicistat strongly inhibit CYP3A4. Inhaled fluticasone is normally cleared by CYP3A4 before reaching systemic levels. When the enzyme is blocked, even small absorbed amounts accumulate and suppress the HPA axis, causing iatrogenic Cushing syndrome.

Antiviral Drugs: Mechanisms and Interactions (Medical Education Pharm)

THE PATTERN

Two Marrow Poisons, One Patient

Why this combo is a board favorite

Here is the pattern you need to burn into memory:

⚠ Valganciclovir (treats CMV) + Zidovudine (treats HIV) = additive myelosuppression → pancytopenia

Why does this happen? Both drugs are nucleoside analogsFake building blocks that look like real DNA bases. Cells grab them during replication, but they jam the machinery because they are not the real thing. → they pretend to be normal DNA building blocks. When rapidly dividing cells (like bone marrow stem cells) grab these fakes and try to use them, DNA replication stalls. The cell cannot divide. It dies.

One drug doing this? Your marrow can usually compensate. Two drugs doing this at the same time? The marrow cannot keep up. Production of ALL cell lines drops:

Cell Line	Lab Finding	Clinical Consequence
White blood cells	Leukopenia (WBC < 4,000)	Infections, sepsis risk
Red blood cells	Anemia (low Hgb)	Fatigue, dyspnea
Platelets	Thrombocytopenia (< 150K)	Bleeding risk
All three at once	Pancytopenia	This is the board answer

From the Attending

Two nucleoside analogs hitting the same marrow at the same time. One is a thymidine analog. One is a guanosine analog. Different fake bases, same rapidly dividing target. The marrow does not care which fake base killed it. If you see pancytopenia after valganciclovir was added to a zidovudine regimen, the interaction is the answer. Every time.

HOW THEY WORK

Watch It Get Activated

Pick a drug, then press Activate (or Step) to add the phosphates one at a time. Flip the resistance switch to watch the gate fail.

Virus has lost its kinase (resistant)

MIX AND MATCH

Drug Interaction Mixer

Tap two drugs to see what happens when you combine them

💊

Zidovudine (AZT)

NRTI

Myelosuppression

💊

Valganciclovir

Anti-CMV

Myelosuppression

💊

Acyclovir

Anti-HSV/VZV

Crystal nephropathy

💊

Efavirenz

NNRTI

CNS effects

💊

Indinavir

Protease Inhibitor

Kidney stones + lipodystrophy

💊

Dolutegravir

INSTI

Well-tolerated

💊

Tenofovir

NRTI

Nephrotoxicity

💊

Lamivudine (3TC)

NRTI

Well-tolerated

Tap any two drugs above to see where they land

KNOW YOUR PLAYERS

HIV Drug Classes

One class at a time. No overwhelm.

NRTIs (Nucleoside Reverse Transcriptase Inhibitors)

These are the "fake bricks." HIV uses reverse transcriptaseHIV's personal copying machine. It takes viral RNA and makes DNA from it → the reverse of normal. NRTIs jam this machine by providing defective building blocks. to copy its RNA into DNA. NRTIs look like real nucleosides but lack a 3' hydroxyl group → they get incorporated and stop the chain cold.

The catch: human cells also use nucleosides for their own DNA. So NRTIs can accidentally interfere with our cells too → especially fast-dividing ones like bone marrow.

💡 Zidovudine (AZT) = thymidine analog. Board toxicity: myelosuppression (macrocytic anemia, neutropenia). The NRTI most likely to trash your marrow.

💡 Tenofovir = adenosine analog. Board toxicity: nephrotoxicity + Fanconi syndrome (proximal tubule damage). Kidney, not marrow.

💡 Lamivudine (3TC) = cytosine analog. Generally well-tolerated. Also used for Hep B. The chill NRTI.

NNRTIs (Non-Nucleoside RTIs)

These bind directly to reverse transcriptase and change its shape so it cannot work. They do not pretend to be nucleosides → they just physically block the machine allosterically.

💡 Efavirenz = Board toxicity: vivid dreams, nightmares, CNS effects. If a board vignette mentions a patient with HIV having wild nightmares → it is efavirenz, every time.

Protease Inhibitors (PIs)

After HIV makes its protein chains, proteaseAn enzyme that cuts long protein chains into functional pieces. Without it, HIV produces useless, unassembled viral parts. PIs block this last assembly step. has to cut them into functional pieces. PIs block this final assembly step. All PIs end in -navir.

💡 CYP3A4 interactions: PIs are strong CYP3A4 inhibitors. Ritonavir is used as a pharmacokinetic boosterLow-dose ritonavir does not fight HIV itself. It blocks the liver enzyme that would clear other PIs, keeping their blood levels high enough to work. Cobicistat works the same way. → it blocks the enzyme that clears other drugs, boosting their levels. This is why PIs interact with statins (simvastatin, lovastatin), inhaled steroids (fluticasone), and methadone.

INSTIs (Integrase Strand Transfer Inhibitors)

HIV uses integraseThe enzyme that splices HIV's newly made DNA into your chromosomes. Once integrated, the virus can hide there permanently. INSTIs prevent this insertion step. to splice its DNA into your chromosomes. INSTIs block this step. They are the newest class and generally the best tolerated. All end in -tegravir.

💡 Dolutegravir, Raltegravir → minimal side effects. Dolutegravir can falsely raise creatinine (blocks tubular secretion) but does NOT actually damage kidneys or marrow. Main concern: chelation with polyvalent cations (calcium, iron, magnesium) → separate dosing by 2 hours.

THE BOARD TRAP

Acyclovir vs Ganciclovir

Same drug family, opposite target organs

CMV (cytomegalovirus)A herpesvirus that is usually harmless in healthy people. In immunocompromised patients (HIV with low CD4, transplant recipients), it reactivates and attacks the colon, retina, or lungs. is an opportunistic infection in HIV patients with CD4 counts below ~50-100. It causes colitis (bloody diarrhea), retinitis (vision loss), and pneumonitis.

Valganciclovir is the oral prodrug of ganciclovir. It is a guanosine analogLooks like the DNA base guanosine. Gets phosphorylated by a viral kinase first (UL97 in CMV), then by host kinases. The triphosphate form jams viral DNA polymerase, but it also gets into host cell DNA, which is why it is toxic to marrow.. CMV has a kinase (UL97) that activates ganciclovir inside infected cells. But once activated, the drug also gets incorporated into host cell DNA during replication. Bone marrow progenitor cells divide rapidly → they grab more of the drug → myelosuppression.

Acyclovir is also a guanosine analog but is activated by HSV/VZV thymidine kinase (not CMV UL97). It has much less affinity for host cell kinases → less incorporation into host DNA → the marrow is spared. Instead, the poorly soluble drug can precipitate as crystals in the renal tubules, especially when the patient is dehydrated.

⚠

BOARD TRAP: The Guanosine Analog Swap

Drug	Treats	Key Toxicity	Why
Acyclovir	HSV, VZV	Crystal nephropathy	Poorly soluble → precipitates in renal tubules as crystals
Ganciclovir / Valganciclovir	CMV	Myelosuppression	Incorporates into host DNA → kills dividing marrow cells

The board loves swapping these. If the vignette says "kidney damage after starting an antiviral" → acyclovir (crystals). If it says "dropping blood counts after starting an antiviral" → ganciclovir/valganciclovir (marrow). Same drug family, opposite targets.

From the Attending

Both are guanosine analogs. Both need a viral kinase to get started. But acyclovir needs the HSV/VZV thymidine kinase → CMV does not have that kinase, so acyclovir cannot touch CMV. Ganciclovir uses the CMV UL97 kinase. No viral kinase, no activation, no antiviral effect. That is why acyclovir does not treat CMV. Know your kinases.

⚡ Acyclovir resistance: HSV can mutate its thymidine kinase gene → acyclovir cannot get phosphorylated → no activation → no effect. Salvage therapy: foscarnet (does not need viral kinase activation, but causes electrolyte wasting).

Self-test: cover the cells and recall each one. Tap a cell to check, or reveal the whole row.

Drug	Toxic organ	Mechanism of injury	Classic clue	Management
Acyclovir / valacyclovir	Kidney	Poorly soluble drug precipitates as crystals in the renal tubules	Rising creatinine with needle-shaped birefringent crystals after IV dosing in a dehydrated patient	IV hydration before and during therapy; adjust dose for renal function
Ganciclovir / valganciclovir	Bone marrow	Triphosphate is incorporated into host marrow DNA and kills dividing progenitors	Neutropenia first, then thrombocytopenia and anemia (a falling ANC)	Serial CBC monitoring; reduce dose or add G-CSF for severe neutropenia

A attacks the kidney, G guts the marrow.

MORE TOXICITIES

Other High-Yield Antiviral Toxicities

The rest of the board bait

⚡ NRTIs + Mitochondrial toxicity: NRTIs can inhibit mitochondrial DNA polymerase gammaMitochondria have their own DNA and their own copying enzyme (pol gamma). NRTIs, especially older ones like didanosine and stavudine, jam this enzyme, starving cells of energy production. → hepatic steatosis (fatty liver), lactic acidosis, peripheral neuropathy, pancreatitis. Older NRTIs (didanosine, stavudine) were the worst offenders.

⚡ Protease Inhibitors + Metabolic syndrome: PIs interfere with lipid and glucose metabolism → hyperglycemia, hyperlipidemia, lipodystrophy (fat redistribution: buffalo hump, central obesity, facial wasting).

⚡ Acyclovir + Dehydration: Low solubility + poor hydration = crystal precipitation in tubules → obstructive nephropathy. Prevention: IV hydration before and during treatment.

⚡ Neuraminidase Inhibitors (oseltamivir, zanamivir): Block neuraminidaseThe influenza surface enzyme that cuts newly formed virus particles free from the host cell. Without it, budding virions stay stuck to the cell and cannot spread. That is why oseltamivir must be started within 48 hours: the virus needs to still be actively budding. on influenza A and B → must start within 48 hours of symptoms. Side effects: nausea, vomiting. Amantadine/rimantadine (M2 blockers) are now obsolete due to near-universal resistance.

INTERACTION CHECK

Starting ART: Check for Interactions

Commit to each call before the rule shows. One co-medication at a time.

Co-medication: a statin

Your patient is starting ritonavir-boosted darunavir and needs a statin for hyperlipidemia. Which statin can you start safely?

Protease inhibitors and boosters (ritonavir, cobicistat) strongly inhibit CYP3A4. Simvastatin and lovastatin are cleared by CYP3A4, so their levels can climb 10 to 50 times and trigger rhabdomyolysis. Rosuvastatin and pravastatin are not meaningfully CYP3A4-metabolized, so they pair safely with a boosted PI. A boosted PI plus a CYP3A4 statin equals rhabdomyolysis risk; reach for rosuvastatin or pravastatin.

Co-medication: rifampin for TB

A patient on a ritonavir-boosted protease-inhibitor regimen is diagnosed with active tuberculosis and must start rifampin. What is the safest move?

Rifampin is a potent CYP3A4 and UGT inducer. It accelerates metabolism so hard that protease-inhibitor and NNRTI levels collapse, risking viral breakthrough and resistance. Stopping ART lets HIV rebound. The fix is to move to an INSTI: dolutegravir can be given 50 mg twice daily to outrun the induction. Rifampin plus a boosted PI fails; switch to twice-daily dolutegravir and never stop ART.

Co-medication: a proton pump inhibitor

A patient on antiretroviral therapy needs a PPI for reflux. Which agent is an absolute contraindication with a PPI?

Rilpivirine needs an acidic stomach to dissolve and absorb. A PPI raises gastric pH enough to drop rilpivirine into the failure range, so the pairing is contraindicated. Dolutegravir tolerates standard PPIs (its real trap is cation chelation, solved by separating doses), and efavirenz absorption does not depend on acid. PPI plus rilpivirine equals absorption failure; switch to efavirenz or an INSTI.

Co-medication: methadone maintenance

A patient on methadone maintenance is starting antiretroviral therapy. Which choice avoids precipitating opioid withdrawal?

Efavirenz and nevirapine induce CYP3A4, the enzyme that clears methadone. Methadone levels can fall 50 to 60 percent and the patient withdraws within days. INSTIs do not induce CYP enzymes, so methadone stays steady, which is why they are preferred in patients on methadone. NNRTI inducers drop methadone into withdrawal; an INSTI keeps it stable.

THE LINEUP

The Antiviral Rogues Gallery

Tap any card to flip and see the full toxicity profile

💊

NRTIs

Backbone of ART, marrow's nemesis

NRTIs

Drugs: tenofovir DF, emtricitabine, abacavir, lamivudine, zidovudine
Role: backbone of ART, fake nucleosides that jam reverse transcriptase
AZT toxicity: myelosuppression, macrocytic anemia
TDF toxicity: nephrotoxicity, Fanconi syndrome, bone loss
Abacavir: hypersensitivity in HLA-B*5701 carriers, MUST screen
Lamivudine: safest NRTI, also used for Hep B

💊

NNRTIs

CYP inducers, dream weavers

NNRTIs

Drugs: efavirenz, rilpivirine, nevirapine
How: bind RT directly, change its shape allosterically
Efavirenz: vivid dreams, nightmares, CNS effects, teratogenic
Rilpivirine: needs acidic stomach, NO PPIs
Nevirapine: hepatotoxicity, Stevens-Johnson rash

💊

Protease Inhibitors

Metabolic bombs, CYP3A4 kings

Protease Inhibitors

Drugs: ritonavir, darunavir, atazanavir, lopinavir
How: block protease, prevent HIV polyprotein cleavage
CYP3A4: strong inhibitors, metabolic syndrome, lipodystrophy
Atazanavir: indirect hyperbilirubinemia (jaundice, normal LFTs)
AVOID: simvastatin and lovastatin with PIs

💊

INSTIs

Modern backbone, fewest interactions

INSTIs (Integrase Inhibitors)

Drugs: dolutegravir, bictegravir, raltegravir, cabotegravir
How: block integrase, prevent HIV DNA insertion
Preferred: first-line modern ART, fewest drug interactions
Dolutegravir: raises creatinine (tubular secretion block), not real damage
Watch: chelation with Ca/Fe/Mg/Zn, separate by 2 hours

⚜

Acyclovir / Valacyclovir

HSV/VZV slayer, crystal maker

Acyclovir / Valacyclovir

Targets: HSV-1, HSV-2, VZV
How: guanosine analog, activated by viral thymidine kinase
Toxicity: crystal nephropathy, AKI if dehydrated
Resistance: TK mutation, switch to foscarnet
Cannot treat CMV: CMV lacks the thymidine kinase

🦠

Oseltamivir

Flu buster, 48-hour window

Oseltamivir (Tamiflu)

Target: influenza A and B
How: neuraminidase inhibitor, blocks viral release
Window: must start within 48 hours of symptoms
Prophylaxis: post-exposure in high-risk contacts
Side effects: nausea, vomiting (take with food)

🤒

Ribavirin

Hep C ally, teratogenic nightmare

Ribavirin

Uses: Hep C (with PegIFN), severe RSV in infants
How: guanosine analog, inhibits RNA-dependent RNA polymerase
Dose-limiting: hemolytic anemia (destroys RBCs)
Teratogenicity: Category X, avoid 6 months after stopping
Modern HCV: largely replaced by direct-acting antivirals

FROM THE LAB

Viruses Under the Microscope

Real electron micrographs and clinical images via Wikimedia Commons

HIV-1 transmission electron micrograph — HIV-1 particles on transmission electron microscopy

Herpes simplex virus transmission electron micrograph — Herpes simplex virions on transmission electron microscopy

Influenza A virus colorized transmission electron micrograph — Influenza A particles: neuraminidase target lives on the viral surface

Antiretroviral drugs to treat HIV infection — Antiretroviral tablets: interactions start when regimens stack

Gilead Truvada HIV prevention pills — TDF/FTC tablets: kidney monitoring matters with nephrotoxins

🔑 Memory Hooks (tap to reveal)

Acyclovir toxicityA = Attacks kidneys (crystals)

Ganciclovir toxicityG = Guts your marrow (myelosuppression)

AZT + ValganciclovirVZ Day: Victory over your marrow (WWII on the bone marrow)

Efavirenz side effectE-fairy-enz: the fairy that gives you vivid dreams

PI metabolic effectsProtease Inhibitors = PI = Paunchy and Insulin-resistant

INSTI chelationMetals grab -tegravirs: separate by 2 hours

PROVE IT

Clinical Vignettes

One patient at a time. Use the front-side tools, commit, then reveal the chain.

Antiviral Drug Interactions

Two Marrow Poisons, One Patient

Watch It Get Activated

Drug Interaction Mixer

HIV Drug Classes

Acyclovir vs Ganciclovir

Other High-Yield Antiviral Toxicities

Starting ART: Check for Interactions

The Antiviral Rogues Gallery

NRTIs

NNRTIs

Protease Inhibitors

INSTIs (Integrase Inhibitors)

Acyclovir / Valacyclovir

Oseltamivir (Tamiflu)

Ribavirin

Viruses Under the Microscope

Clinical Vignettes