Acute Unilateral Central Serous Chorioretinopathy after Immunization with Pfizer-BioNTech COVID-19 Vaccine: A Case Report and Literature Review.

INTRODUCTION: A 43-year-old Caucasian male presented to our ophthalmology clinic with blurry vision and metamorphopsia in his right eye, 24 hours after receiving the first dose of the Pfizer-BioNTech COVID-19 vaccine. METHODS: Clinical examination and imaging tests were consistent with acute unilateral central serous chorioretinopathy (CSCR) that completely resolved after 2 months without any treatment. He had no significant ophthalmic or medical history. He also lacked the classical risk factors for CSCR such as recent psychosocial stressors, Type-A personality traits, history of exogenous steroid use, connective tissue disorders and obstructive sleep apnea. RESULTS: This appears to be only the second reported case of CSCR, temporally associated with a recombinant COVID-19 mRNA vaccine. We also present a summary of published reports demonstrating intraocular complications associated with the novel recombinant COVID-19 mRNA vaccines. CONCLUSION: Findings in this report should not deter COVID-19 vaccinations given the rarity of aforementioned ocular complications and the greater benefit of protection from COVID-19 infection. Medical practitioners, however, should remain mindful of potential ocular complications, given the greater likelihood of occurrence with increasing vaccination booster rates

Towards a new method of porosimetry: principles and experiments

Current experimental methods used to determine pore size distributions (PSD) of porous media present several drawbacks such as toxicity of the employed fluids (e.g., mercury porosimetry). The theoretical basis of a new method to obtain the PSD by injecting yield stress fluids through porous media and measuring the flow rate Q at several pressure gradients ∇P was proposed in the literature. On the basis of these theoretical considerations, an intuitive approach to obtain PSD from Q(∇P) is presented in this work. It relies on considering the extra increment of Q when ∇P is increased, as a consequence of the pores of smaller radius newly incorporated to the flow. This procedure is first tested and validated on numerically generated experiments. Then, it is applied to exploit data coming from laboratory experiments and the obtained PSD showgood agreement with the PSD deduced frommercury porosimetry