T-Consciousness Fields (TCFs) as non-physical fields have been introduced by Mohammad Ali Taheri. Previous studies have examined the application of TCFs on various cell lines and ATP production, revealing that these fields can increase the viability and ATP concentration of cells. It is well-established that reduced gravity can have detrimental impacts on human health during space missions. In this study, two separate experiments were conducted to investigate the effects of TCFs under different gravity conditions using clinostat device to simulate microgravity (MG) condition. In the first experiment, Faradarmani Consciousness Field (FCF), as one of TCFs, was applied to Raji lymphoma cells, and cell cycle progression was evaluated under both MG environment and earth’s gravity (1G). In these experiments, the samples without TCFs treatment served as control. Flow cytometry assay revealed that MG stress considerably induced the Sub-G1 phase by up to 42% and reduced the percentage of G1 and S phases by approximately 57% and 30%, respectively, compared to 1G condition. However, the behavior of FCF-treated samples remained almost unchanged. In the second experiment, the effects of TCFs on cell cycle progression and ATP production of HEK-293 cell line were evaluated under both 1G and MG conditions. The results demonstrated that MG increased the Sub-G1 phase by around 50% percent while under TCFs the percentage of this phase was almost similar to that of control in 1G condition. Furthermore, the S phase in TCFs-treated cells was 18.5% higher compared to their clinorotated counterparts. Under earth’s gravity, TCFs induced a 29% increase in the G2 phase compared to the control. Additionally, MG significantly reduced ATP production by an average of 90%, but under TCFs the concentration of ATP was about two times higher than those samples without TCFs. In conclusion, aside from confirming the distinct effects of TCFs, the data of reduced sub-G1 phase suggest that TCFs treatment results in much better cell survival in reduced gravity by inhibiting apoptosis. According to Taheri, these observed changes in cellular behavior are attributed to information transmission through TCFs, which can compensate for the absence of gravity.