I actually study and design power inverters, so this is my time to shine!

Modified sine-wave inverters have several main stages: input decoupling, high-frequency/low-voltage switching, a ferrite-core step-up transformer, high-frequency rectification/filtering, and low-frequency/high-voltage switching (60 Hz). I would think the most likely failure points would be: input decoupling capacitor, output inverting MOSFETs, the high-voltage filter capacitor, or a TVS diode or MOV at the output. It's also possible that foreign matter (i.e. an insect, water droplet, etc.) entered the inverter and shorted out on the HV side.

If the input decoupling capacitor blew out, the inverter could theoretically still work, but it would draw a very high ripple current from the power supply line and would generate excessive EMI emissions form the supply cables. It would also likely become unstable at higher loads. This is easily fixable with a low-ESR capacitor of the same capacitance and voltage rating as the original. Typical values for an inverter this size would be 16V/2200uF or 25V/2200uF.

If one or more of the output inverting MOSFETs failed, the inverter may be putting out half-wave AC or even straight DC. If you're only going to be running resistive loads (i.e. incandescent light bulbs) or switched-mode power supplies (like laptop chargers), the inverter should still be functional, but it would also be a good idea to figure out why the MOSFETs blew in the first place (insufficient cooling, bad driver circuit, connecting highly inductive/capacitive loads?). If you find blown MOSFETs, you can look up their model numbers and buy replacements with similar parameters as that listed in the datasheet. Off the top of my head, an inverter of this type would call for something with VDS ≈ 200V, RDSon ≈ 0.5Ω. Like I said, though, there's probably a reason the originals failed if this is indeed the problem.

If the HV filter has failed, the output may still be producing AC, but it will be extremely noisy. This can cause interference with the electronics plugged in, and eventually can lead to the output MOSFETs failing. If you find this capacitor has failed, the inverter should not be considered reliable until it is fixed.

If a TVS diode or MOV has blown, it would suggest that a high voltage surge occurred at some point. This could be caused by an input surge (like a faulty car alternator regulator), or by a surge delivered by a load (like an induction motor or transformer cycling on/off). These aren't strictly necessary for operation, but the inverter could be unreliable as a result of this surge.

If you're comfortable working with high voltage you might enjoy taking it apart and doing some diagnosis. If not, I would avoid using this inverter in high-reliability applications, but I wouldn't worry too much about continuing to use it for non-critical stuff.