We present a minimalistic and °exible single-beam instrumen-

tation based for sensitive tunable diode laser absorption spectroscopy (TD-

LAS) and its use in structural analysis of highly scattering pharmaceu-

tical solids. By utilising a vertical-cavity surface emitting laser (VCSEL)

for sensing of molecular oxygen dispersed in tablets, we address structural

properties such as porosity. Experiments involve working with unknown

pathlengths, severe backscattering and di®use light. These unusual experi-

mental conditions has lead to the use of the term gas in scattering media

absorption spectroscopy (GASMAS). By employing fully digital wavelength

modulation spectroscopy and coherent sampling, system sensitivity in am-

bient air experiments reaches the 10¡7 range. Oxygen absorption exhibited

by our tablets, being in°uenced by both sample porosity and scattering,

were in the range 8 £ 10¡5 to 2 £ 10¡3, and corresponds to 2-50 mm of

pathlength through ambient air (Leq). The day-to-day reproducibility was

on average 1.8% (0.3 mm Leq), being limited by mechanical positioning.

This is the ¯rst time sub-millimetre sensitivity is reached in GASMAS. We

also demonstrate measurements on gas transport on a 1 s timescale. By

employing pulsed illumination and time-correlated single photon counting,

we reveal that GASMAS exhibits excellent correlation with time-domain

photon migration. In addition, we introduce an optical measure of porosity

by relating oxygen absorption to average photon time-of-°ight. Finally, the

simplicity, robustness and low cost of this novel TDLAS instrumentation

provides industrial potential.