Functional neuroimaging: a physiological perspective

The quest to understand the functional organization of the brain has occupied mankind for more than a century. The close relationship between cerebral blood flow (CBF) and brain function was first observed in the late nineteenth century by the Italian physiologist, Mosso (1881). Mosso recorded pulsations from the forearm and the brain, showing stronger brain pulsations during cognitive events, such as hearing the bells from his church and performing mental arithmetic ( Posner and Raichle, 1994 ). These studies suggested that measurement of CBF might be an important way to assess brain function during mental activity. Roy and Sherrington (1890), two distinguished British physiologists, further characterized the close relationship between brain function and CBF. They attributed task-induced vasodilation to an increased demand for cerebral metabolism in response to neuronal activity. The Roy–Sherrington principle has been interpreted to mean that CBF changes reflect a tight coupling between cellular energy requirements and vascular delivery of glucose and oxygen. Roy and Sherrington’s observation of focally increased blood flow during brain functional activation has been replicated thousands of times by a myriad of techniques, beginning early in the last century ( Fulton, 1928 ).

Whole-brain measurements of CBF, oxygen metabolism (cerebral metabolic rate of oxygen, CMRO ₂ ) and glucose metabolism (CMR _Glc ) also began appearing in the early part of the twentieth century ( Schmidt and Kety, 1947 ; Landau et al., 1955 ; Sokoloff et al., 1977 ). Collectively, these studies demonstrated that: the brain’s resting-state energy demand is high (although the human brain is only 2% of body’s weight, it consumes 20% of the body’s oxygen and 25% body’s glucose; Sokoloff et al., 1977 ); resting-state brain energy production is provided almost exclusively by glucose oxidation (approximately 90%; Siesjo, 1978 ); and, basal CBF and CMRO ₂ are tightly coupled across brain regions (A linear CBF-CMRO ₂ relationship was observed with a slope of approximately 0. 97; Fox and Raichle, 1986 ).

Studies using emerging, pre-imaging radiotracer techniques convincingly demonstrated that brain blood flow is dramatically increased by increased partial pressure of carbon dioxide (PaCO ₂ ) and by decreased partial pressure of oxygen (PaO ₂ ), a form of cerebrovascular autoregulation ( Kety and Schmidt, 1948 ). These observations provided strong support for the Roy and Sherrington hypothesis, as CO ₂ is the primary “ chemical product” of glucose oxidation, and extended the hypothesis to include substrate ([O ₂ ]) availability as a potent vascular regulator. With the advent of autoradiographic methods ( Schmidt and Kety, 1947 ; Landau et al., 1955 ; Sokoloff et al., 1977 ) and non-invasive radiotracer imaging methods ( Reivich et al., 1979 ; Raichle et al., 1983 ), blood flow and glucose consumption could be measured regionally, allowing the Roy and Sherrington hypothesis to be further explored. As expected, task performance reliably elicited large, highly focal increases in CBF ( Fox et al., 1988 ) and CMR _Glc ( Phelps and Mazziotta, 1985 ; Fox et al., 1988 ). The observed increases in CBF and CMR _Glc were similar in magnitude, typically in the range of 30–50%, apparently supporting the Roy and Sherrington hypothesis that neural activity focally increased metabolic rate and thereby increased blood flow.

The first imaging-based measurements of CMRO ₂ during task performance were reported in the early 1980s, using 15-O positron emission tomography (PET) ( Frackowiak et al., 1980 ; Mintun et al., 1984 ). In two different brain systems (visual and somatosensory), Fox et al., observed that task-induced increases in CMRO ₂ were much lower than those in CBF or CMR _Glc ( Fox and Raichle, 1986 ; Fox et al., 1988 ). The CMRO ₂ shortfall during focal neuronal activation, in fact, caused a local oxygen surplus, with the oxygen extraction fraction (OEF) falling from a resting value of approximately 40% to a task-state value of approximately 20%. These findings clearly contradicted the Roy and Sherrington hypothesis. Since glucose can be metabolized by either oxidative or non-oxidative (i. e, lactate-producing) pathways and since the increase of CMRO ₂ was minimal, Fox and colleagues suggested that: (i) the glucose is predominately metabolized by anaerobic glycolysis; (ii) the energy demand associated with neuronal activation is small (as opposed to resting-state demand) and glycolysis alone may provide the energy needed for the transient changes in brain activity; and (iii) CBF response must be regulated by factors other than oxidative metabolism and total energy demand. The observation that the stimulus-evoked increase in glucose consumption observed with PET is at least partially non-oxidative has been confirmed with ¹ H NMR spectroscopic (MRS) measurements of tissue lactate concentration [Lac] ( Prichard et al., 1991 ; Frahm et al., 1996 ). The increase in lactate production (i. e., non-oxidative metabolism) was found in later studies to be a modulator of CBF increase ( Mintun et al., 2004 ). Such uncoupling of CBF and CMRO ₂ is the basis for the blood oxygenation level-dependent (BOLD) functional MRI (fMRI) contrast ( Kwong et al., 1992 ; Ogawa et al., 1992 ). These PET and MRS observations raise a general question: does the evoked neuronal activity drive oxidative or non-oxidative metabolism?

To further clarify this issue, we performed concurrent fMRI and ¹ H MRS measurements to identify the relationship between task-evoked increases in CBF, CMRO ₂ , [Lac] and ATP production (J _ATP ) during graded visual stimulation (4, 8, and 16 Hz; 4 min for each condition) ( Lin et al., 2010 ). Percent changes (%Δ) in CBF, CMRO ₂ and [Lac] varied with frequency, with %ΔCBF and %Δ[Lac] peaking at 8 Hz, while %ΔCMRO ₂ reached a maximum at 4 Hz ( Vafaee and Gjedde, 2000 ; Lin et al., 2008 ). The magnitude of %ΔCBF (57. 1–65. 1%) and %Δ[Lac] (31. 3–50. 0%) were much larger than that of %ΔCMRO ₂ (12. 2–17. 0%). As a result, %ΔCBF was tightly coupled with lactate production rate (J _Lac ; [Lac] divided by stimulation period; r = 0. 91, P < 0. 001) ( Gjedde, 1997 ; Lin et al., 2010 ), but negatively correlated with %ΔCMRO ₂ ( r = −0. 64, P = 0. 024). J _ATP , determined with changes in CMRO ₂ and J _Lac by a stoichiometric relationship, was found predominately contributed by oxidative metabolism (approximately 98%) at each stimulus condition. Consequently, %ΔJ _ATP was linearly correlated to %ΔCMRO ₂ ( r = 1. 00, P < 0. 001). Similar findings were also reported by PET studies ( Gjedde, 1997 ). The fMRI-MRS observations confirm that (i) CBF response to neuronal activity is driven more by anaerobic glycolysis, rather than oxygen demand, and (ii) energy demand is predominately met through oxidative metabolic pathway regardless the CMRO ₂ increases are much lower than those of [Lac].

The collective evidence from the functional imaging literature (PET, fMRI, and MRS) has forced the development of alternatives to the Roy–Sherrington hypothesis. Of these, the astrocyte-neuron lactate shuttle (ANLS) model is the most conceptually evolved and widely accepted ( Pellerin and Magistretti, 1994 ). The ANLS model posits a cooperation between neurons and astrocytes in meeting the activation-induced needs both for energy production and for neurotransmitter production. Upon neuronal firing, glucose is taken up by both neurons and astrocytes. The majority of the glucose is taken up by the astrocytes and the remainder by neurons. Glucose metabolism in neurons is small but entirely aerobic, to support neurotransmission ( Brand, 2005 ; Hyder et al., 2006 ). Astrocytic glucose consumption, on the other hand, is large but much less energetically efficient by virtue of being predominately anaerobic. Astrocytic glycolysis (2 ATP) is used to support Na ⁺/K ⁺ ion pumping and glutamate(Glu)-glutamine(Gln) conversion. Lactate generated by astrocytic glycolysis is eventually transported to neurons as fuel, but with some loss into the circulation, which increases hyperemia ( Mintun et al., 2004 ; Hyder et al., 2006 ).

The fMRI-MRS observations, described above ( Lin et al., 2010 ), are in line with the ANLS model. First, CBF increases are not regulated by oxidative metabolism. %ΔCBF and %ΔCMRO ₂ are negatively correlated. In contrast, non-oxidative metabolism is a more likely candidate. %ΔCBF and %ΔJ _Lac are positively correlated. But other factors (e. g., Ca ²⁺, K ⁺ and adenosine signaling pathway) may also play a role. Second, the increases in CMR _Glc are for purposes other than energy demand, e. g., for astrocyte-mediated neurotransmitter recycling, with the evidence being that increases in [Lac] are far more than that of CMRO ₂ . Third, the two metabolic pathways (oxidative and non-oxidative) are co-existent, dissociable, and serve different purposes in maintaining neuronal functions during visual stimulation. Oxidative metabolism is predominately neuronal and supports ATP production for the release of neurotransmitters; with the evidence being that the energy demand (J _ATP ) was predominately (approximately 98%) met through oxidative metabolism in all stimulus conditions. Non-oxidative metabolism, on the other hand, mainly occurs in astrocytes to support the Glu-Gln conversion and lactogenesis-mediated hyperemia. Since astrocytic lactate is eventually taken up into the tricarboxylic acid cycle as a fuel substrate by neurons, it has to be pointed out that oxidative metabolism is expected to increase as neuronal activation continues. In support of this formulation, prolonged visual stimulation (> 20 min) has been reported to induce gradually rising levels of CMRO ₂ and gradually decreasing CMR _Glc , J _Lac and CBF under a high-frequency stimulation (e. g., 8 Hz) ( Prichard et al., 1991 ; Gjedde and Marrett, 2001 ; Mintun et al., 2002 ; Vlassenko et al., 2006 ; Lin et al., 2009 ). Consequently, %ΔCBF and %ΔCMRO ₂ were re-coupled (the coupling ratio, n = %ΔCBF/%ΔCMRO ₂ , decreased from 8 to 2) as stimulation continued. However, inconsistent observations have also been reported in prior fMRI studies ( Hoge et al., 1999 ) that the coupling ratio already reached to 2–3 during acute, transient visual stimulation (approximately 20–60 s). The discrepancy could be due to the stimulation frequency or to the modeling strategy used in the studies. For example, a low coupling ratio (2–3) was observed with low frequencies (e. g., 1–4 Hz), while a high ratio (6–10) was observed with high frequencies, during short-term visual stimulation (20 s to 6 min) ( Lin et al., 2008 ). As a result, ratio of 2–3 is expected if low frequencies are used. Details of the discrepancy regarding modeling strategy can be found in our previous publication ( Lin et al., 2009 ).

Metabolic physiology and functional neuroimaging are highly complementary fields of inquiry. An in-depth understanding of neuronal metabolic physiology will enhance the interpretation of functional neuroimaging research, and vice versa. The evidence above addressed the cooperation of functional neuroimaging and metabolic physiology in understanding the coordination between neurovasculature, neurons and astrocytes during steady-state . For future studies, more effort should be invested in exploring their coordination during transient state . For instance, the dynamic mechanism of the BOLD signal may be explained by the asynchrony of task-induced neuronal and glial responses, as follows. Because neuronal responses precede those of astrocytes (approximately 4 s; Schummers et al., 2008 ), the increase in oxidative metabolism precedes that of non-oxidative metabolism ( Kasischke et al., 2004 ) and, consequently, the CBF response. CMRO ₂ increases that precede CBF increases result in the “ initial dip” of the BOLD signal ( Menon et al., 1995 ; Malonek and Grinvald, 1996 ). Astrocytic activity, following the neuronal activity, results in a significant increase in CBF and, consequently, the increase in BOLD signal. On the other hand, the post-stimulus “ undershoot” phenomenon (the negative signal following the cessation of stimulation; Buxton et al., 1998 ; Mandeville et al., 1999 ; Lu et al., 2004 ) observed in BOLD and CBF signals contradicts the notion of “ watering the entire garden for the sake of one thirsty flower” ( Malonek and Grinvald, 1996 ), but may pave a way for further understanding the temporal relationship between the neuronal and astrocytic activities after the stimulus termination.

Further developments in neuroimaging techniques and metabolic theories are crucial for future research. As regards neuroimaging techniques, it would be important to determine quantitative ATP production, CMRO ₂ and CMR _Glc using other MR methods, such as Phosphorous-31, Oxygen-17 and Carbon-13 MRS, respectively. In addition, direct observations of the differential roles of neurons and astrocytes associated with ATP-CMRO ₂ and CBF-lactate couples would be significant. Concurrent MRI, MRS and optical imaging measurements may help achieve this goal. As regards metabolic physiology, theories of neurovascular and neurometabolic mechanisms are evolving. Some issues proposed by the ANLS model need further investigation. For example, whether the lactate transferred to neurons as a fuel substrate is from astrocytic or neuronal activity, and whether lactate is the preferential substrates of neurons for neurotransmission-related energy needs is still under debate. Further, whether the small increase in CMRO ₂ during neuronal activation is due to the small fraction of glucose undergoing oxidative phosphorylation or due to other reasons is controversial. Brand proposed that ATP can be synthesized by means of deactivation of mitochondrial uncoupling protein (UCP) to elevate oxidative phosphorylation without raising oxygen consumption, which may provide an alternative explanation for relative low levels of CMRO ₂ changes during brain activation ( Brand, 2005 ).

The concurrent developments of neuroimaging methods and physiological theories will also pave the way for the investigation of cerebral hemodynamics and metabolism in disease states. For example, the most well-documented example of a mitochondrial-failure-based neurodegenerative disorder is Huntington’s disease (HD) ( Jenkins et al., 1993 ; Koroshetz et al., 1997 ). Nonetheless, Powers et al. (2007) recently reported PET evidence that the well-documented regional decreases in CMR _Glc associated with HD are not accompanied by comparable decreases in CMRO ₂ , which led them to conclude that HD is not a mitochondrial disorder. (We would argue, however, that this conclusion is not yet warranted, as Powers’ study did not include a challenge, in which neuronal activation was used to elevate MRO ₂ above resting levels). Similar neuroimaging approaches may apply to other neurodegenerative disorders, including Alzheimer’s disease (AD), Down’s Syndrome-related AD and Parkinson’s disease (PD), to investigate possible underlying metabolic dysfunctions of those diseases. In addition to human studies, animal models also play an essential role since they allow more flexibility for neurovascular-metabolic coupling investigations of both normal and disease states. For example, treatments of rapamycin (a drug developed as an immunosuppressant) and calorie restriction are currently only available for animals in aging and AD studies ( Van Remmen et al., 2001 ; Richardson, 2009 ; Spilman et al., 2010 ). Neuroimaging methods can help clarify the pathophysiology of these diseases and identify the mechanism of action of these effective treatments (in aging and AD) by defining the correlation between changes in CBF, CMRO ₂ , CMR _Glc and ATP.

In summary, we addressed our perspective on the interplay of metabolic physiology and functional neuroimaging over the past century; the replacement of the Roy–Sherrington principle by the ANLS model; and, the future direction of the developments of neuroimaging techniques and physiological theories. These developments should provide the bases for predicting causes and consequences of deregulation in neurological diseases, including neurodegenerative disorders, in the near future.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

This work was supported by National Institute of Health (NIH) and UTHSCSA General Clinical Research Center (GCRC) grants M01 RR01346.

References

Brand, M. D. (2005). The efficiency and plasticity of mitochondrial energy transduction. Biochem. Soc. Trans. 33, 897–904.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Buxton, R. B., Wong, E. C., and Frank, L. R. (1998). Dynamics of blood flow and oxygen metabolism during brain activation: the balloon model. Magn. Reson. Med. 39, 855–864.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Fox, P. T., and Raichle, M. E. (1986). Focal physiological uncoupling of cerebral blood flow and oxidative metabolism during somatosensory stimulation in human subjects. Proc. Natl. Acad. Sci. U. S. A. 83, 1140–1144.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Fox, P. T., Raichle, M. E., Mintun, M. A., and Dence, C. (1988). Nonoxidative glucose consumption during focal physiologic neural activity. Science 241, 462–464.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Frackowiak, R. S., Lenzi, G. L., Jones, T., and Heather, J. D. (1980). Quantitative measurement of regional cerebral blood flow and oxygen metabolism in man using 15O and positron emission tomography: theory, procedure, and normal values. J. Comput. Assist. Tomogr. 4, 727–736.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Frahm, J., Kruger, G., Merboldt, K. D., and Kleinschmidt, A. (1996). Dynamic uncoupling and recoupling of perfusion and oxidative metabolism during focal brain activation in man. Magn. Reson. Med. 35, 143–148.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Fulton, J. (1928). Observation upon the vascularity of the human occipital lobe during visual activity. Brain 51, 310–320.

CrossRef Full Text

Gjedde, A. (1997). “ The relation between brain function and cerebral blood flow and metabolism,” in Cerebrovascular Disease , eds H. Bajter and L. Caplan (Philadelphia, PA: Lippincott-Raven Publishers), 23–40.

Gjedde, A., and Marrett, S. (2001). Glycolysis in neurons, not astrocytes, delays oxidative metabolism of human visual cortex during sustained checkerboard stimulation in vivo. J. Cereb. Blood Flow Metab. 21, 1384–1392.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Hoge, R. D., Atkinson, J., Gill, B., Crelier, G. R., Marrett, S., and Pike, G. B. (1999). Investigation of BOLD signal dependence on cerebral blood flow and oxygen consumption: the deoxyhemoglobin dilution model. Magn. Reson. Med. 42, 849–863.

Pubmed Abstract | Pubmed Full Text | Hyder, F., Patel, A. B., Gjedde, A., Rothman, D. L., Behar, K. L., and Shulman, R. G. (2006). Neuronal-glial glucose oxidation and glutamatergic-GABAergic function. J. Cereb. Blood Flow Metab. 26, 865–877.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Jenkins, B. G., Koroshetz, W. J., Beal, M. F., and Rosen, B. R. (1993). Evidence for impairment of energy metabolism in vivo in Huntington’s disease using localized 1H NMR spectroscopy. Neurology 43, 2689–2695.

Pubmed Abstract | Pubmed Full Text

Kasischke, K. A., Vishwasrao, H. D., Fisher, P. J., Zipfel, W. R., and Webb, W. W. (2004). Neural activity triggers neuronal oxidative metabolism followed by astrocytic glycolysis. Science 305, 99–103.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Kety, S. S., and Schmidt, C. F. (1948). The effects of altered arterial tensions of carbon dioxide and oxygen on cerebral blood flow and cerebral oxygen consumption of normal young men. J. Clin. Invest. 27, 484–492.

CrossRef Full Text

Koroshetz, W. J., Jenkins, B. G., Rosen, B. R., and Beal, M. F. (1997). Energy metabolism defects in Huntington’s disease and effects of coenzyme Q10. Ann. Neurol. 41, 160–165.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Kwong, K. K., Belliveau, J. W., Chesler, D. A., Goldberg, I. E., Weisskoff, R. M., Poncelet, B. P., Kennedy, D. N., Hoppel, B. E., Cohen, M. S., Turner, R., Cheng, H. M., Brady, T. J., and Rosen, B. R. (1992). Dynamic magnetic resonance imaging of human brain activity during primary sensory stimulation. Proc. Natl. Acad. Sci. U. S. A. 89, 5675–5679.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Landau, W. M., Freygang, W. H. J., Roland, L. P., Sokoloff, L., and Kety, S. S. (1955). The local circulation of the living brain: values in the unanesthetized and anesthetized cat. Trans. Am. Neurol. Assoc. 80, 125–129.

Lin, A.-L., Fox, P. T., Hardies, J., Duong, T. Q., and Gao, J.-H. (2010). Nonlinear coupling between cerebral blood flow, oxygen consumption, and ATP production in human visual cortex. Proc. Natl. Acad. Sci. U. S. A. 107, 8446–8451.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Lin, A.-L., Fox, P. T., Yang, Y., Lu, H., Tan, L.-H., and Gao, J.-H. (2009). Time-dependent correlation of cerebral blood flow with oxygen metabolism in activated human visual cortex as measured by fMRI. Neuroimage 44, 16–22.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Lin, A.-L., Fox, P. T., Yang, Y., Lu, H., Tan, L.-H., and Gao, J.-H. (2008). Evaluation of MRI models in the measurement of CMRO2 and its relationship with CBF. Magn. Reson. Med. 60, 380–389.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Lu, H., Golay, X., Pekar, J. J., and Van Zijl, P. C. (2004). Sustained poststimulus elevation in cerebral oxygen utilization after vascular recovery. J. Cereb. Blood Flow Metab. 24, 764–770.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Malonek, D., and Grinvald, A. (1996). Interactions between electrical activity and cortical microcirculation revealed by imaging spectroscopy: implications for functional brain mapping. Science 272, 551–554.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Mandeville, J. B., Marota, J. J., Ayata, C., Zaharchuk, G., Moskowitz, M. A., Rosen, B. R., and Weisskoff, R. M. (1999). Evidence of a cerebrovascular postarteriole windkessel with delayed compliance. J. Cereb. Blood Flow Metab. 19, 679–689.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Menon, R. S., Ogawa, S., Hu, X., Strupp, J. P., Anderson, P., and Ugurbil, K. (1995). BOLD based functional MRI at 4 Tesla includes a capillary bed contribution: echo-planar imaging correlates with previous optical imaging using intrinsic signals. Magn. Reson. Med. 33, 453–459.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Mintun, M. A., Raichle, M. E., Martin, W. R., and Herscovitch, P. (1984). Brain oxygen utilization measured with O-15 radiotracers and positron emission tomography. J. Nucl. Med. 25, 177–187.

Pubmed Abstract | Pubmed Full Text

Mintun, M. A., Vlassenko, A. G., Rundle, M. M., and Raichle, M. E. (2004). Increased lactate/pyruvate ratio augments blood flow in physiologically activated human brain. Proc. Natl. Acad. Sci. U. S. A. 101, 659–664.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Mintun, M. A., Vlassenko, A. G., Shulman, G. L., and Snyder, A. Z. (2002). Time-related increase of oxygen utilization in continuously activated human visual cortex. Neuroimage 16, 531–537.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Mosso, A. (1881). Ueber den Kreislauf des Blutes im menschlichen Gehirn . Leipzig: Verlag von Veit.

Ogawa, S., Tank, D. W., Menon, R., Ellermann, J. M., Kim, S. G., Merkle, H., and Ugurbil, K. (1992). Intrinsic signal changes accompanying sensory stimulation: functional brain mapping with magnetic resonance imaging. Proc. Natl. Acad. Sci. U. S. A. 89, 5951–5955.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Pellerin, L., and Magistretti, P. J. (1994). Glutamate uptake into astrocytes stimulates aerobic glycolysis: a mechanism coupling neuronal activity to glucose utilization. Proc. Natl. Acad. Sci. U. S. A. 91, 10625–10629.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Phelps, M. E., and Mazziotta, J. C. (1985). Positron emission tomography: human brain function and biochemistry. Science 228, 799–809.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Posner, M. I., and Raichle, M. E. (1994). Images of Mind . New York: Scientific American Library.

Powers, W. J., Videen, T. O., Markham, J., McGee-Minnich, L., Antenor-Dorsey, J. V., Hershey, T., and Perlmutter, J. S. (2007). Selective defect of in vivo glycolysis in early huntington’s disease striatum. Proc. Natl. Acad. Sci. U. S. A. 104, 2945–2949.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Prichard, J., Rothman, D., Novotny, E., Petroff, O., Kuwabara, T., Avison, M., Howseman, A., Hanstock, C., and Shulman, R. (1991). Lactate rise detected by 1H NMR in human visual cortex during physiologic stimulation. Proc. Natl. Acad. Sci. U. S. A. 88, 5829–5831.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Raichle, M. E., Martin, W. R., Herscovitch, P., Mintun, M. A., and Markham, J. (1983). Brain blood flow measured with intravenous H2(15)O. II. Implementation and validation. J. Nucl. Med. 24, 790–798.

Pubmed Abstract | Pubmed Full Text

Reivich, M., Kuhl, D., Wolf, A., Greenberg, J., Phelps, M., Ido, T., Casella, V., Fowler, J., Hoffman, E., Alavi, A., Som, P., and Sokoloff, L. (1979). The [18F]fluorodeoxyglucose method for the measurement of local cerebral glucose utilization in man. Circ. Res. 44, 127–137.

Pubmed Abstract | Pubmed Full Text

Richardson, R. B. (2009). Ionizing radiation and aging: rejuvenating an old idea. Aging 1, 887–902.

Pubmed Abstract | Pubmed Full Text

Roy, C. S., and Sherrington, C. S. (1890). On the regulation of the blood-supply of the brain. J. Physiol. (Lond.) 11, 85–108.

Pubmed Abstract | Pubmed Full Text

Schmidt, C. F., and Kety, S. S. (1947). Recent studies of cerebral blood flow and cerebral metabolism in man. Trans. Assoc. Am. Physicians 60, 52–58.

Pubmed Abstract | Pubmed Full Text

Schummers, J., Yu, H., and Sur, M. (2008). Tuned responses of astrocytes and their influence on hemodynamic signals in the visual cortex. Science 320, 1638–1643.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Siesjo, B. (1978). Brain Energy Metabolism . New York: Wiley, 101–110.

Sokoloff, L., Reivich, M., Kennedy, C., Des Rosiers, M. H., Patlak, C. S., Pettigrew, K. D., Sakurada, O., and Shinohara, M. (1977). The [14C]deoxyglucose method for the measurement of local cerebral glucose utilization: theory, procedure, and normal values in the conscious and anesthetized albino rat. J. Neurochem. 28, 897–916.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Spilman, P., Podlutskaya, N., Hart, M. J., Debnath, J., Gorostiza, O., Bredesen, D., Richardson, A., Strong, R., and Galvan, V. (2010). Inhibition of mTOR by rapamycin abolishes cognitive deficits and reduces amyloid-beta levels in a mouse model of Alzheimer’s disease. PLoS ONE 5, e9979. doi: 10. 1371/journal. pone. 0009979.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Vafaee, M. S., and Gjedde, A. (2000). Model of blood-brain transfer of oxygen explains nonlinear flow-metabolism coupling during stimulation of visual cortex. J. Cereb. Blood Flow Metab. 20, 747–754.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Van Remmen, H., Guo, Z., and Richardson, A. (2001). The anti-ageing action of dietary restriction. Novartis Found. Symp. 235, 221–230.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text

Vlassenko, A. G., Rundle, M. M., Raichle, M. E., and Mintun, M. A. (2006). Regulation of blood flow in activated human brain by cytosolic NADH/NAD + ratio. Proc. Natl. Acad. Sci. U. S. A. 103, 1964–1969.

Pubmed Abstract | Pubmed Full Text | CrossRef Full Text