I'm not sure what type of data you're dealing with, but here's a method I've used for processing speech data that could help you locate local maxima. It uses three functions from the Signal Processing Toolbox: HILBERT, BUTTER, and FILTFILT.
data = (...the waveform of noisy data...);
Fs = (...the sampling rate of the data...);
[b,a] = butter(5,20/(Fs/2),'low'); % Create a low-pass butterworth filter;
% adjust the values as needed.
smoothData = filtfilt(b,a,abs(hilbert(data))); % Apply a hilbert transform
% and filter the data.
You would then perform your maxima finding on smoothData. The use of HILBERT first creates a positive envelope on the data, then FILTFILT uses the filter coefficients from BUTTER to low-pass filter the data envelope.
For an example of how this processing works, here are some images showing the results for a segment of recorded speech. The blue line is the original speech signal, the red line is the envelope (gotten using HILBERT), and the green line is the low-pass filtered result. The bottom figure is a zoomed in version of the first.
SOMETHING RANDOM TO TRY:
This was a random idea I had at first... you could try repeating the process by finding the maximas of the maximas:
index = find(diff(sign(diff([0; x(:); 0]))) < 0);
maxIndex = index(find(diff(sign(diff([0; x(index); 0]))) < 0));
However, depending on the signal-to-noise ratio, it would be unclear how many times this would need to be repeated to get the local maxima you are interested in. It's just a random non-filtering option to try. =)
Just in case you're curious, another one-line maxima-finding algorithm that I've seen (in addition to the one you listed) is:
index = find((x > [x(1) x(1:(end-1))]) & (x >= [x(2:end) x(end)]));