Optimizing cardiopulmonary rehabilitation duration for long COVID patients: an exercise physiology monitoring approach.

The presence of prolonged symptoms after COVID infection worsens the workability and quality of life. 200 adults with long COVID syndrome were enrolled after medical, physical, and mental screening, and were divided into two groups based on their performance. The intervention group (n = 100) received supervised rehabilitation at Department of Pulmonology, Semmelweis University with the registration number 160/2021 between 01/APR/2021-31/DEC/2022, while an age-matched control group (n = 100) received a single check-up. To evaluate the long-term effects of the rehabilitation, the intervention group was involved in a 2- and 3-month follow-up, carrying out cardiopulmonary exercise test. Our study contributes understanding long COVID rehabilitation, emphasizing the potential benefits of structured cardiopulmonary rehabilitation in enhancing patient outcomes and well-being. Significant difference was found between intervention group and control group at baseline visit in pulmonary parameters, as forced vital capacity, forced expiratory volume, forced expiratory volume, transfer factor for carbon monoxide, transfer coefficient for carbon monoxide, and oxygen saturation (all p < 0.05). Our follow-up study proved that a 2-week long, patient-centered pulmonary rehabilitation program has a positive long-term effect on people with symptomatic long COVID syndrome. Our data showed significant improvement between two and three months in maximal oxygen consumption (p < 0.05). Multidisciplinary, individualized approach may be a key element of a successful cardiopulmonary rehabilitation in long COVID conditions, which improves workload, quality of life, respiratory function, and status of patients with long COVID syndrome.

Inhibition of neuronal Na+ currents by lacosamide: Differential binding affinity and kinetics to different inactivated states.

Lacosamide is a new-generation anticonvulsant acting on Na+ channels. Compared to the classic anticonvulsants targeting Na+ channels, lacosamide is unique in structure and in its molecular action requiring longer membrane depolarization. Selective binding to the slow inactivated state of Na+ channels was then advocated for lacosamide, although slow binding to the fast inactivated state was alternatively proposed recently. In addition, quantitative characterization of lacosamide action has been deficient. We investigated the interactions between lacosamide and Na+ channels in native mammalian neurons, and found that the apparent dissociation constant (~13.7 µM) of lacosamide to the slow inactivated state is well within the therapeutic concentration range and is much (>15-fold) lower than the dissociation constant of lacosamide to the fast inactivated state. Besides, lacosamide has extremely slow binding rates (<400 M-1sec-1) to the fast but much faster binding rates (>3000 M-1sec-1) to the slow inactivated Na+ channels. Consistent with these biophysical characters, we further demonstrated that lacosamide is much more effective against the repetitive burst discharges with interburst intervals at -60 mV than -80 mV. With preponderant binding to the slow inactivation state in therapeutic concentrations and thus less propensity to affect normal discharges, lacosamide could be a drug of choice for seizure discharges characterized by relatively depolarized interburst intervals, during which more slow inactivated states could be generated and more binding of lacosamide would ensue.