ChANgE: Intermittent Energy Restriction and Chewing on Neural Stem Cell Ageing and Adult Hippocampal Neurogenesis Associated Cognition

Study Description

Brief Summary

Extended bouts of periodic mastication and intermittent energy restriction (IER) may improve cognitive performance in the context of adult hippocampal neurogenesis in an ageing population. A randomised controlled parallel design trial will determine the impact of a 3 month IER diet (2 consecutive days of very low calorie diet and 5 days of normal eating) and a mastication intervention (1 piece of gum chewed for 10 minutes 3 times a day) in comparison to a control on neurogenesis-associated cognitive measures and circulating levels of the anti-ageing protein Klotho.

Detailed Description

Nutrition and human health are strongly related. Altering overabundance through fasting/calorie-restricted diets has profound effects on homeostasis, tissue regeneration, and cancer. Tissue stem cells respond to the physiological changes that occur during fasting through dynamic shifts in their metabolism. Restricting energy intake in mice or introducing mutations in nutrient-sensing pathways can extend lifespans by as much as 50%. Post-mortems reveal that tumours, heart problems, neurodegeneration and metabolic disease are generally reduced/delayed in long-lived mice. Therefore, extending lifespan by energy restriction (ER) also seems to increase 'healthspan', the time lived without chronic age-related conditions. These insights have hardly made a dent in human medicine. Molecular and cellular insights should be established in humans to validate interventions such as ER to delay ageing and associated conditions e.g. cognitive decline (Murphy et al., 2014).

Stem cells from the central nervous system also respond to ER. Recently, the Thuret lab have found that ER, in the absence of malnutrition, promotes hippocampal stem cells to proliferate and differentiate into new-born neurons. Because these new postnatal hippocampal neurons have been shown to play a role in cognition, ER also promoted enhanced cognition in rodents (Zainuddin et al., 2012; de Lucia et al., 2017; Thuret et al., 2012). This phenomenon of neurogenesis, the process by which new neurons are generated from neural stem cells, is also occurring in humans (Spalding et al., 2013). It is a tightly regulated process occurring in the mammalian hippocampus which is an environmentally responsive brain structure known to regulate learning, memory and mood. Proposed functions of adult hippocampal neurogenesis (AHN). include enhancing recognition memory, the ability to recognise previously encountered stimuli, and pattern separation, the ability to differentially encode small changes in similar inputs (Clelland et alk., 2009; Sahay et al., 2011). It has been posited that calorie restriction may increase neurogenesis as a "cellular relic" of intermittent feeding patterns during evolution as a response to alternating periods of famine and abundant food (Murphy & Thuret, 2015). Human trials have found significant improvements in verbal recognition memory after 30% reduction in calorie intake (Witte et al., 2009). Also, intermittent fasting in humans has been associated with significant increases in brain activation volume in areas involved in brain function control and plasticity(Belaïch et al., 2016). Food texture and mastication have also been implicated in AHN and cognitive ability (Smith et al., 2016). Decreased mastication due to the removal of molars and edentulism in both humans and animals have a negative impact on AHN and associated cognition. Human populations, in particular, have shown a close association between masticatory function, cognitive status and age-related neurodegeneration in the elderly (Miura et al., 2003). The exact mechanism by which mastication affects cognition is unknown.

Research question: In older, overweight participants does IER and/or extended periods of mastication enhance performance inhippocampus-dependent memory tasks and increase anti-ageing marker Klotho?

Objectives:

1. A randomised controlled parallel-design trial will determine the impact of an IER diet (2 consecutive days of a very low calorie diet, 5 days of normal healthy eating for 3 months) and/or extended periods of mastication (10 minutes 3 times a day for 3 months) compared to a control group (continued habitual eating behaviour, dietary patterns) on primary outcome variables (MST and Klotho) in older, healthy participants with overweight or class I obesity.

2. To assess the impact of an IER diet and extended periods of mastication on secondary outcomes variables including body composition, mood and sleep.

3. To explore whether extended periods of mastication can be utilised as a weight loss/fasting aid.

Study Design

Outcome Measures

Primary Outcome Measures

1. Serum Klotho concentration [Baseline]

   Anti-ageing longevity protein

2. Serum Klotho concentration [Day 42]

   Anti-ageing longevity protein

3. Serum Klotho concentration [Day 84]

   Anti-ageing longevity protein

4. Mnemonic Similarity Task [Baseline]

   Neurogenesis-associated cognition

5. Mnemonic Similarity Task [Day 42]

   Neurogenesis-associated cognition

Secondary Outcome Measures

1. Body weight [Baseline]

2. Body weight [Day 42]

3. Body weight [Day 84]

4. Body fat percentage [Baseline]

5. Body fat percentage [Day 42]

6. Body fat percentage [Day 84]

7. Body Mass Index [Baseline]

8. Body Mass Index [Day 42]

9. Body Mass Index [Day 84]

10. Waist circumference [Baseline]

11. Waist circumference [Day 42]

12. Waist circumference [Day 84]

13. Hip circumference [Baseline]

14. Hip circumference [Day 42]

15. Hip circumference [Day 84]

16. Patient Health Questionnaire [Baseline]

    Questionnaire

17. Patient Health Questionnaire [Day 42]

    Questionnaire

18. Patient Health Questionnaire [Day 84]

    Questionnaire

19. Zung Self-Rating Anxiety Scale [Baseline]

    Questionnaire - Scale can be scored from 20 (normal) to 80 (extreme anxiety levels). The total score is reported.

20. Zung Self-Rating Anxiety Scale [Day 42]

    Questionnaire

21. Zung Self-Rating Anxiety Scale [Day 84]

    Questionnaire

22. Pittsburgh Sleep Quality Index [Baseline]

    Questionnaire

23. Pittsburgh Sleep Quality Index [Day 42]

    Questionnaire

24. Pittsburgh Sleep Quality Index [Day 84]

    Questionnaire

25. Plasma glucose concentration [Baseline]

    Fasting

26. Plasma glucose concentration [Day 42]

    Fasting

27. Plasma glucose concentration [Day 84]

    Fasting

28. Cholesterol [Baseline]

    Fasting

29. Cholesterol [Day 42]

    Fasting

30. Cholesterol [Day 84]

    Fasting

31. Triglycerides [Baseline]

    Fasting

32. Triglycerides [Day 42]

    Fasting

33. Triglycerides [Day 84]

    Fasting

34. High Density Lipoprotein [Baseline]

    Fasting

35. High Density Lipoprotein [Day 42]

    Fasting

36. High Density Lipoprotein [Day 84]

    Fasting

37. Low Density Lipoprotein [Baseline]

    Fasting

38. Low Density Lipoprotein [Day 42]

    Fasting

39. Low Density Lipoprotein [Day 84]

    Fasting

40. Total/HDL Cholesterol Ratio [Baseline]

    Fasting

41. Total/HDL Cholesterol Ratio [Day 42]

    Fasting

42. Total/HDL Cholesterol Ratio [Day 84]

    Fasting

43. Plasma adiponectin concentration [Baseline]

    Fasting

44. Plasma adiponectin concentration [Day 42]

    Fasting

45. Plasma adiponectin concentration [Day 84]

    Fasting

46. Plasma leptin concentration [Baseline]

    Fasting

47. Plasma leptin concentration [Day 42]

    Fasting

48. Plasma leptin concentration [Day 84]

    Fasting

49. Plasma beta-hydroxybutrate concentration [Baseline]

    Fasting

50. Plasma beta-hydroxybutrate concentration [Day 42]

    Fasting

51. Plasma beta-hydroxybutrate concentration [Day 84]

    Fasting

52. Plasma total cholesterol concentration [Baseline]

    Fasting

53. Plasma total cholesterol concentration [Day 42]

    Fasting

54. Plasma total cholesterol concentration [Day 84]

    Fasting

55. Plasma low density lipoprotein (LDL) cholesterol concentration [Baseline]

    Fasting

56. Plasma LDL cholesterol concentration [Day 42]

    Fasting

57. Plasma LDL cholesterol concentration [Day 84]

    Fasting

58. Plasma high density lipoprotein (HDL) cholesterol concentration [Baseline]

    Fasting

59. Plasma HDL cholesterol concentration [Day 42]

    Fasting

60. Plasma HDL cholesterol concentration [Day 84]

    Fasting

61. Plasma triglyceride concentration [Baseline]

    Fasting

62. Plasma triglyceride concentration [Day 42]

    Fasting

63. Plasma triglyceride concentration [Day 84]

    Fasting

64. Plasma total cholesterol:HDL cholesterol ratio [Baseline]

    Fasting

65. Plasma total cholesterol:HDL cholesterol ratio [Day 42]

    Fasting

66. Plasma total cholesterol:HDL cholesterol ratio [Day 84]

    Fasting

Other Outcome Measures

1. Adverse events [Baseline until endpoint: Day 84]

Eligibility Criteria

Criteria

Inclusion Criteria:

• Male and female subjects.

• 60+ years of age at the time of consent.

• BMI 25-35.

Exclusion Criteria:

• Subject is unable to understand the participant information sheet.

• Subject is unable to understand and/or completely perform the cognitive testing.

• Chews more than 3 sticks of gum per month, including nicotine replacement gum.

• Unable to provide written informed consent.

• Impaired vision that is not corrected.

• Does not agree to maintain their habitual exercise routine.

• Is not in general good health on the basis of medical history.

• Unwilling to chew gum for 3 times a day for 12 weeks.

• Unwilling to maintain an intermittent fasting diet regime.

• Unwilling to have blood taken.

• History of or are currently diagnosed with a significant psychiatric disorder (e.g. schizophrenia, anxiety, PTSD).

• Subject has any neurological disorder that could produce cognitive deterioration (e.g. Alzheimer's disease, Parkinson's disease, stroke).

• History of traumatic brain injury, stroke or any other medical conditions causing cognitive impairment.

• Has uncontrolled epilepsy or is prone to fainting.

• Participated in a weight management drug trial in previous 3 months.

• Has undergone bariatric surgery.

• Known or suspected of alcohol abuse defined as >14 drinks per week (1 drink = 1 pint of beer, 1 large glass of wine or 50ml spirit).

• Gastrointestinal or liver disease.

• Subject has a sleep disorder or an occupation where sleep during the overnight hours is irregular.

• Subjects taking the following prescription medications: Donepezil (Aricept), Galantamine (Reminyl), Rivastigmine (Exelon), Tacrine (Cognex), Bethanechol (Urecholine), Memantine (Namenda) Selegiline (Eldepryl) or any other medication for cognitive impairment.

• Subject has a known sensitivity to the study product.

• Individual has a condition the chief investigator believes would interfere with his or her ability to provide informed consent, comply with the study protocol, might confound the interpretation of study results or put the subject at undue risk.

Contacts and Locations

Locations

Sponsors and Collaborators

• King's College London
• Medical Research Council
• Mars, Inc.

Investigators

• Principal Investigator: Sandrine Thuret, PhD, King's College London
• Principal Investigator: Wendy L Hall, PhD, King's College London

Study Documents (Full-Text)

More Information

Publications

• Akazawa Y, Kitamura T, Fujihara Y, Yoshimura Y, Mitome M, Hasegawa T. Forced mastication increases survival of adult neural stem cells in the hippocampal dentate gyrus. Int J Mol Med. 2013 Feb;31(2):307-14. doi: 10.3892/ijmm.2012.1217. Epub 2012 Dec 18.
• Murphy T, Dias GP, Thuret S. Effects of diet on brain plasticity in animal and human studies: mind the gap. Neural Plast. 2014;2014:563160. doi: 10.1155/2014/563160. Epub 2014 May 12. Review.
• Smith, N., Miquel-Kergoat, S. & Thuret, S., 2016. The impact of mastication on cognition: Evidence for intervention and the role of adult hippocampal neurogenesis. Nutrition and Aging, 3(2-4), pp.115-123
• Witte AV, Fobker M, Gellner R, Knecht S, Flöel A. Caloric restriction improves memory in elderly humans. Proc Natl Acad Sci U S A. 2009 Jan 27;106(4):1255-60. doi: 10.1073/pnas.0808587106. Epub 2009 Jan 26.