Maybe you want to consider a 'spinthariscope'; cf.: Albert G. Ingalls, "The Amateur Scientist: On scintillation counters and how a group of amateurs helped to build a planetarium", Scientific American, March 1953, p. 104; https://www.scientificamerican.com/article/the-amateur-scientist-1953-03/?print=true

Thorium oxide (up to 30%) was used to improve the glass quality used to manufacture lenses. ThO2 optical properties (high refractivity and low dispersion) allows lens manufacturers to minimize chromatic aberration and lower curvature.

 NUREG-1717 estimated that the dose to the operator of a television camera using thoriated lenses could be as much as 60 mrem per year. This assumed that three of the camera’s lenses contained 30% by weight thorium and that the camera man was positioned behind the camera for 1000 hours per year. Nevertheless, there is no evidence to suggest that thoriated lenses are commonly used in television cameras.

Measurements have indicated that the exposure rate at a depth of 10 cm in the body of an individual carrying a camera containing 0.36 μCi of thorium would be approximately 0.01 mrem/hr.  Based on this value, NUREG-1717 calculated that a serious photographer might receive an annual exposure of 2 mrem. This assumed that the photographer carried the camera 30 days per year and for 6 hours per day. They also estimated an exposure of 0.7 mrem per year for an average photographer.  If the camera lens contained the maximum permitted concentration of thorium (30%), NUREG-1717 estimated that the aforementioned annual doses could triple.

 https://www.orau.org/ptp/collection/consumer%20products/cameralens.htm

Radiation interacting with glasses will scintillate. And, there will be some materials you can make glasses from that will scintillate more strongly.

However, you will get one pulse of light for each gamma ray or beta particle interacting with the glasses. Given the small mass of glasses these interactions would be rare, except in situations where radiation dose rates would be so high you wouldn't want to be there anyway. I can't see any means by which these would be visible against ambient light - ie: wearing the glasses would only show the radiation if the room was dark, or you were wearing a hood to block out other light. Being able to see radiation but nothing else wouldn't seem to be useful. 

Generally glasses will not exhibit viewable light. In case of gamma rays the interaction leads to little fluorescence which is detected by pmt. Betas if produce cerenkov radiation will be small. Not visible to us. So kilo gray doses or high activities. Some visible light may be seen in water plastic etc.

thank you for responding me

238PuO2 has such a high rate of alpha-decay that particles of this oxide bounce around like Mexican Jumping beans.