Terapie manualna kojarzyła mi się z terapia przez prace manualne a tu takie coś
Trudno o dane na ten temat.
Jest coś takiego jak hypertrophia (pol. przerost) co jak dobrze rozumiem jest po prostu wzrostem masy organu lub tkanki w warunkach niedokrwienia. Tak się np. rozwijają mięśnie pod wpływem treningu wytrzymałosciowego
https://pl.wikipedia.org/wiki/Przerost
Stosują to sportowcy przy treningach wytrzymałościowych (resistance training ).
Łatwiej doprowadzić do przeciążenia niedokrwionego mięśnia dzięki czemu nie trzeba aż tak intensywnie trenować.
http://www.kinesport.pl/Artyku%C5%82y/2 ... riction-2/
Tutaj jest artykuł o stosowaniu tego samego wobec mózgu tylko w inny sposób.
według tych badan przy intensywnych ćwiczeniach fizycznych wraz z rozwojem mięśni powstają tez nowe neurony w mózgu.
Tu streszczenie:
https://www.nfpt.com/blog/hypertrophyof-the-brain
A tutaj dokładne badania:
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6210989/
Podsumowanie:
The type of physical exercise (e.g., resistance training) in combination with related exercise variables (e.g., load, number of repetitions and sets) which efficiently enhance cognitive performance are largely unknown [39,40,41,42,43,44,45,46,47,48,49]. A promising physical exercise intervention which fends off physical and cognitive decline (e.g., due to the aging process) is resistance training. Hypothetically, the efficiency of resistance training interventions on cognition could be increased due to the application of BFR.
Resistance training with BFR is more efficient to increase muscle hypertrophy and strength as compared to the same resistance training without BFR [247,270] and for a resistance training with BFR, lower exercise loads are needed to achieve comparable muscular adaptions (e.g., increase in muscle mass) as compared to high-load resistance training [271,272]. The lower exercise load during a resistance training with BFR could be beneficial for special cohorts since those lower exercise loads pose lower mechanical stress to the joints and the risk of adverse cardiovascular effects is decreased [124,217,244,273]. The currently available evidence suggests (i) that strength gains in response to a resistance training mediate, at least partly, the cognitive improvements [274] or (ii) that strength performance per se is a more appropriate indicator regarding health outcomes (e.g., cognition) [108]. Hence, at the moment no reliable assumptions can be made whether (i) a regular participation in resistance training, (ii) a relative high individual (baseline) strength level or (iii) the combination of both (high muscular strength level and regular resistance training) are most beneficial for cognitive functions. Notably, since an optimal level of neurochemical substances (e.g., IGF-1) is beneficial for cognitive performance [275], it could be speculated that, in turn, also an optimal level of muscular strength and/or continuously performed effective resistance activities, which may contribute substantially to the maintenance of an optimal level of neurochemical substances, exists. In this manner, a low-load resistance training with BFR could be a promising strategy especially for special cohorts (e.g., older adults unable to tolerate high loads) to ensure an adequate level of strength and profit from biological mechanisms which would without BFR only be possible when (not well tolerated) high loads are applied. Furthermore, relative low muscle damage is induced by low-load resistance training with BFR [148,168,276,277], which may allow a higher training frequency than in high load-resistance training [124,125,246].
However, testing the hypothesis suggesting that short-term and long-term resistance training with BFR improve cognitive performance as well as brain health to a greater extent than resistance training without BFR may provide deeper insights into the interplay between neurobiological mechanisms and cognitive processes. A deeper understanding of underlying exercise-induced and cognition-related neurobiological mechanisms is urgently needed to develop efficient prevention strategies (e.g., decelerate cognitive decline due to aging process) and to optimize rehabilitation strategies for individuals with worsened cognitive functions (e.g., older individuals with dementia). Here, the resistance training with BFR might be a promising strategy of exercise intervention.
Podkreślenie moje.
(Nie mam czasu się zagłębiać w fachowe detale.)
Czyli ogólnie ćwiczenia wytrzymałościowe poprawiają zdolnosci kognitywne.
Dzięki ćwiczeniu z ograniczonym przepływem krwi mogą FBR można to osiągnąć łatwiej.
Prawda znana jeszcze w starożytności:
W zdrowym ciele zdrowy duch
Podejrzewam że to o czym słyszałaś to próba bezpośredniego przeniesienia FBR z mięśni na mózg.