2.2.1.

Pacemaker theory and baroreceptor reflex theory

The pacemaker theory, primarily based on animal studies, suggests that the central nervous system contains a pacemaker that is responsible for the rhythmicity of LFOs.²³ Studies have shown slow SNA and ABP rhythms in the LFO frequency despite the lack of sensory inputs from peripheral structures in animals that have undergone surgical and/or medical denervation.^25–28 In tetraplegic humans with traumatic spinal cord lesions, the results have been conflicting.^29–31 While one study showed consistent LFOs,³¹ other studies failed to detect LFOs in some²⁹ or all subjects³⁰ perhaps due to different levels of the spinal lesions or differences in tetraplegia durations as one study proved significantly increased LFOs 6 months after the initial examination.²⁹

The baroreflex theory originates from the work of Guyton and Harris.³² The contribution of the baroreceptor reflex to the genesis of LFOs has since been confirmed in numerous studies of animals undergone surgical sinoaortic baroreceptor denervation^33–35 showing either strong attenuation or abolishment of LFOs. Deactivation of the baroreceptor reflex with alpha-adreno blockers shows a similar trend in animals^36–38 and humans.^39,40 These studies support that the LFOs are caused by vasomotor tone, because alpha-adrenergic antagonists block the sympathetic effect on vasomotion.⁴¹

2.2.2.

Amplitude

There are only a limited amount of studies focusing on the amplitude of the LFOs. In animal studies the amplitude follows the mean level of SNA when subjected to stimulations altering the sympathetic tone.^42–45 Human studies show the same tendency^46–50 though only in individuals and not across groups with different SNA levels⁵¹ perhaps due to age differences in the vasculature and regulation thereof. The reproducibility of LFO amplitudes is high over short-term, but low over long-term,⁵² though this could be influenced by several factors including overall stress level.⁴⁹ It has been suggested that the LFO amplitudes indicates reflectory local myogenic activity⁵³ in the terminal arteriole smooth muscle cells,⁵⁴ and is influenced by sympathetic control mechanisms.⁵⁵ It is thought that the local myogenic response deals with small changes in systemic pressure changes, while the SNS responds to larger changes,⁵⁶ but the exact relationship remains uncertain.

2.7.1.

Fourier transform

The Fourier transform is commonly used to decompose a function of time, i.e., the NIRS signal, into a frequency domain. There are many different variations of the Fourier transform. We will address a couple of them here, but will not be discussing them further in this paper. One of the variations can transform the NIRS signals in the time domain, but this will not account for specific frequency intervals, and therefore, is not suitable for analyzing LFOs and VLFOs. The frequency domain analysis generates certain frequency intervals, in which the oscillations occur and the amplitudes of the oscillations in these frequency intervals. A variation of this that is often used is called the fast Fourier transform. It generates a measure called power spectral density (PSD), which is the amplitude within a given signal in relation to the frequency of the signal. The PSD and the amplitude do not, however, say anything about the synchronicity of the oscillations.

2.7.2.

Transfer function analysis

The transfer function analysis (TFA) based on the Fourier transform is used to detect synchronization of LFOs and VFLOs and the method has been passed on from the TCD research paradigm.^60,78,91 It is a black box input–output analysis, generating ratios of the input signal that is transferred to the output signal. In this context, the input can either be the ABP, mean arterial pressure, or ${\mathrm{V}}_{\mathrm{MCA}}$, and the output being the NIRS signals. The analysis produces two certain measures, gain and phase shift. The gain is the amplitude of the input oscillations relative to the amplitude of the output NIRS oscillations. Equal amplitudes would, therefore, generate a gain of 1. The phase shift (or phase angle) is a measure of synchronization and if the oscillations occur at the exact same time the phase shift would be 0 deg. If phase shift is negative, the input oscillations occur before the output oscillations and vice versa, while a counterphase relationship would generate a phase shift of 180 deg.

The input in a TFA can also be the NIRS signal of a healthy hemisphere, which might serve as the best comparison if the individual subjects have a healthy hemisphere.

2.7.3.

Wavelet transform

The wavelet transform differs from the Fourier in that it transforms data into a time-frequency domain, whereas Fourier can only transform data into either frequency or time domain one at a time. This gives the transform some slight mathematical benefits and some other possibilities. The downside is a trade-off between spectral and temporal resolution. The wavelet transform can, therefore, generate the amplitude of examined oscillations, but also an instantaneous phase.⁹²

In the NIRS oscillation research, the most commonly used concepts are wavelet coherence (WCO) and wavelet phase coherence (WPCO). WCO is a coherence determination of both the amplitude and the relative phase shift at once. The WCO is difficult to understand in the context of LFOs and VLFOs as it is hard to dissociate the importance the amplitude and the phase shift to the WCO. Instead, WPCO determines how constant the phase difference is between to signals in a certain frequency range. A WPCO of 1 means that the phase difference between two oscillations constant over the entire time series, whereas a WPCO of 0 would only be generated from two totally independent oscillating signals.

Amplitude and phase of Fourier and wavelet transform can be compared without conversion unlike synchronization analysis (phase shift and WPCO).⁹³ To our knowledge, the only studies using the two methods on the same group of patients are conducted by Tachtsidis et al.²⁴ and Rowley et al.⁵⁵ showing similar trends in PSD, while it is difficult to assess it quantitatively from the publicized results. Other methods are described thoroughly and compared in an excellent review by Thewissen et al.⁹⁴ regarding NIRS investigations of CA in neonates.

4.2.1.

Amplitude

In ischemic stroke occurring more than 12 months ago, the amplitude of both LFOs and VLFOs was shown to be lower than in healthy age-matched controls.¹⁰⁴ Phillip et al.¹⁰⁵ investigated LFOs of acute ischemic strokes within 5 days of ictus, but did not examine a healthy control group. Thrombolysed patients, conceivably having suffered less damage to their brain, exhibited amplitudes equal to that of nonthrombolysed patients. The absolute amplitude ratio was borderline different between the two group and amplitude did not correlate with NIHSS on admission. According to the prevailing oscillation theories, decreased amplitudes would indicate a lower mean SNA or less myogenic (LFO) as well as neurogenic and metabolic (VLFO) autoregulatory activity. The former does not correlate with the common understanding of the autonomic nervous system (ANS) after stroke, where the SNS is believed to be overactive and dominating over the relatively inert parasympathetic nervous system.¹⁰⁶ However, the smooth muscle loses its tone after a stroke, which is an effect known as vasomotor paralysis.¹ The ability to contract is a prerequisite for the SNS to raise LFO amplitude not being met due to the stroke. The decline in myogenic CA activity is an indication of the vasomotor paralysis rendering the brain vulnerable to further damage and could be permanent as it can be observed at least 12 months at minimum after a stroke.

Schroeter et al.¹⁰⁷ found a decreased LFO amplitude in patients with cerebral microangiopathy (CMA), though only due to hypertension. The amplitude of VLFOs in this study increased with visual stimulation supporting the theory of VLFO amplitude as in indication of possible metabolic control mechanism (though the applied range was an aggregate of metabolic and neurogenic VLFO frequencies). As CMA patients have damaged small vessels, one would have expected altered VLFO amplitude compared to the control group as the metabolic control occurs in the small vessels, but this was not the case possibly due to the aggregate VLFO range applied.

Newly diagnosed Alzheimer’s (AD) patients exhibited a higher LFO amplitude at rest in a study by van Beek et al.¹⁰⁸ The increased myogenic activity could be explained by a higher mean SNA level as shown in studies of the ANS in AD.^109–111 The difference in LFO amplitude vanished when the groups performed a repetitive sit–stand maneuver possibly because of the SNS responding to large ABP-changes in healthy controls. VLFO amplitude was equivalent in the two groups under both conditions expressing equal neurogenic and metabolic CA activity.

A TFA of these patients showed that gain between ${\mathrm{V}}_{\mathrm{MCA}}$ and OxyHb VLFOs was increased compared to controls, which authors proposed as an indicator of reduced metabolic reserve or a reduced diffusion of oxygen as observed in positron emission tomography studies of AD. The LFO ${\mathrm{V}}_{\mathrm{MCA}}$-OxyHb gain amplitude was similar across the two groups.

4.2.2.

Synchronization

Several studies have explored the LFOs in resting patients with a chronic cerebral infarction and all found a lower interhemispheric WPCO in stroke patients suggesting a lesser stability of the phase difference between the hemispheres compared to healthy people.^112–114 This effect was interpreted as a loss of the control on myogenic CA activity in the smooth muscle of resistance vessels. Such a desynchronization was also seen in acute stroke as evidenced by a higher absolute interhemispheric phase shift.¹⁰⁵ Interestingly, the interhemispheric phase shift proved to be well correlated to the National Institutes of Health Stroke Scale (NIHSS) and so the impaired CA was due to stroke size and not to treatment (thrombolysis or not).

VLFOs in the upper range exhibited lower interhemispheric WPCO in chronic stroke than control groups in two studies,^112,114 while another showed an equal WPCO though with a smaller sample size.¹¹³ Lower WPCO would indicate a disruption of spontaneous neurogenic CA activity. Tan et al.¹¹⁴ also inspected the oscillations in the bottom VLFO range, which also had a lower WPCO and thus a reduced synchronicity of the metabolic control mechanism.

AD patients displayed a higher ${\mathrm{V}}_{\mathrm{MCA}}$-OxyHb phase shift in the VLFO range and authors explained this as differences in either active regulation mechanisms or in passive properties in the cerebral vasculature.¹⁰⁸ They also found an equal phase shift in the LFO range suggesting intact coordination of myogenic CA.

4.3.1.

Amplitude

Symptomatic carotid stenosis (CS) patients were examined by Phillip et al.,¹¹⁵ which revealed equal gain between ABP and OxyHb LFOs when comparing to both the contralateral hemisphere and the hemispheres of healthy controls. However, an interhemispheric TFA was performed and showed a higher amplitude ratio due to lower amplitude on the hypoperfusion side. This indicates lower myogenic activity in the microvasculature distal to the stenosis as an expression of compensatory dilation due to inadequate perfusion and oxygen delivery.

Moyamoya disease is characterized by intimal proliferation and stenosis of both the internal carotid arteries as well as its intracranial branches thereby creating the need for collateral angiogenesis looking like a dust cloud on angiography.¹¹⁶ The disease was inspected with NIRS, which showed lower amplitude in the LFO range and bottom VFLO range.¹¹⁷ In accordance with histological studies proving smooth muscle degeneration as the intima grows expansively,¹¹⁸ this result points to a decrease in spontaneous smooth muscle activity.

Schytz et al.¹¹⁹ examined both patients with familial hemiplegic migraine (FHM), common migraine, and OSA.¹²⁰ Patients suffering from FHM combined with common migraine had induced attacks with infusion of glyceryl trinitrate, and this was accompanied by higher LFO amplitude possibly caused by a reflectory increase in SNA and smooth muscle tone. OSA patients were examined before and 2 months after initiation of continuous positive airway pressure (CPAP) treatment. Oddly, OSA patients did not exhibit any difference to controls in LFO amplitude before CPAP despite OSA usually raising the general sympathetic tone¹²¹ and thus the smooth muscle activity, but perhaps this was disrupted by endothelial damage also associated with OSA¹²⁰. However, they displayed a significant decline after treatment, reflecting the expected modulation of sympathetic activity.

In malaria patients, no difference in LFO amplitude was detected between cerebral and noncerebral malaria.¹²² Upper VLFO amplitude, however, was lower in cerebral malaria perhaps demonstrating the changes in microvasculature flow prompted by the parasite.¹²³ Authors state an increase in VLFO amplitude after recovery, but with no mention of which patients were included in the follow-up analysis.

4.3.2.

Synchronization

CS has been under scrutiny by TFA due to the inherent nature of the disease. Reinhard et al.⁹⁸ were first to investigate it with NIRS as the output measure. Compared to both healthy controls and the contralateral hemisphere, respiratory amplified LFOs in ${\mathrm{V}}_{\mathrm{MCA}}$ and OxyHb were delayed relative to ABP LFOs, but only the phase shift to the former was statistically significant. The normal counterphase relationship of OxyHb–DeoxyHb was also abrogated. These changes point to a desynchronization and thus impaired CA. Results from such patients must be carefully treated, as it is difficult to dissociate the effect of CS from other risk factors and infarction, though only a minor portion had any symptoms in this study. Authors later solidified their findings in an examination using a multichannel NIRS system, which also showed CA being mostly impaired in the MCA/ACA (anterior cerebral artery) border zone.¹²⁴

Similarly, Philip et al.¹¹⁵ arrived at a borderline altered phase shift when comparing to the contralateral hemisphere in resting symptomatic CS patients also demonstrating an impaired CA, but no difference compared to healthy controls. Using interhemispheric OxyHb TFA, authors presented an altered absolute interhemispheric phase shift with borderline significance. Interhemispheric measures seem more intuitively correct as it would minimize anatomical variations¹²⁵ despite the noteworthy limitation of needing a healthy contralateral hemisphere to compare with.

The trend also occurs in severe unilateral MCA stenosis although the examined patients were asymptomatic. Increased LFO ABP-OxyHb phase shift was observed in the affected hemisphere over the entire hemisphere and even higher in the core MCA distribution area.¹²⁶ A subgroup was examined for CVR, which showed that diminished CVR led to higher phase shifts. The desynchronization of myogenic CA could thus be the consequence of the downstream vessels not being able to compensate for the MCA stenosis.

4.4.1.

Amplitude

Elevated ${\mathrm{V}}_{\mathrm{MCA}}$ has been recognized as a measure of intracerebral atherosclerosis, and therefore, a risk factor for stroke.¹²⁷ People with this condition displayed lower amplitude in LFO, upper and bottom VFLO ranges, though the former two were borderline significant.¹²⁸ This provides indication of decreases in myogenic, neurogenic, and metabolic activity of the cerebral vasculature with elevated ${\mathrm{V}}_{\mathrm{MCA}}$, which could all be attributed to the stiffening of vessel walls in atherosclerosis.

An important factor in the development of atherosclerosis is arterial hypertension, in which Li et al.¹²⁹ examined with half of the hypertension subjects also exhibiting elevated ${\mathrm{V}}_{\mathrm{MCA}}$. Hypertension increased the LFO amplitude as the result of myogenic autoregulatory mechanisms being activated to protect the brain in conform to general CA knowledge.¹ The group with elevated ${\mathrm{V}}_{\mathrm{MCA}}$ had amplitudes between that of the hypertension group and the healthy controls. This dampening of amplitude consolidates the findings in the former study of elevated ${\mathrm{V}}_{\mathrm{MCA}}$.¹²⁸ Noteworthy is the opposite trend of LFO amplitude in CMA patients as the result of hypertension¹⁰⁷ possibly elucidating that CMA patients do not have the ability to increase their myogenic CA in response to the challenge of hypertension. VLFO amplitudes did not show any definite trends in hypertension.

LFO amplitude has been shown to decrease with age in numerous studies with subjects both at rest^{130,131,132,133,134} and with stimulations of visual,¹³¹ cognitive,¹³⁵ and positional character.^136,133 Generally, this has been interpreted as an expression of vessel stiffening with age, and therefore, less microvascular smooth muscle activity. This trend was even more pronounced in elderly with mild cognitive impairment (MCI), though only in the parietal lobes.¹³⁰ TFA showed no difference in LFO ABP-OxyHb gain across age groups during rest^99,135 or cognitive memory task.¹³⁵

VLFO amplitude in aging exhibited a similar decline¹³² although more apparent with stimulations^131,135,133 displaying an age effect on neurogenic and metabolic CA. TFA of ABP-OxyHb VLFO during the cognitive test by Vermeij et al.¹³⁵ showed no effect of age or cognitive load on gain.

During sit–stand maneuvers performed in a study by Oudegeest-Sander et al.,¹³⁷ authors found no difference in ${\mathrm{V}}_{\mathrm{MCA}}$-OxyHb gain across age groups, but a trend toward higher gain was conveyed in their regression analysis. Reduced distensibility and thereby less damping of ${\mathrm{V}}_{\mathrm{MCA}}$ oscillations in the elderly were proposed to account for this difference.

4.4.2.

Synchronization

The interhemispheric WPCO approach was applied to hypertension patients and resulted in lower LFO WPCO and equal WPCO in the upper VLFO range.¹³⁸ This loss of synchronicity was connected to a reduced control of the microvascular smooth muscle activity. The stroke study by Han et al.¹¹² examined a subpopulation also suffering from hypertension and found an even lower WPCO in the upper VLFO range suggesting additional desynchronization of neurogenic CA activity, while hypertension did not desynchronize LFOs any further.

The synchronization of oscillations in the aging brain has been well examined. Peng et al.¹³⁶ used a synchronicity analysis called wavelet cross correlation (WCC, higher values indicating stronger synchronicity). It showed that the WCC for HR-OxyHb, ABP-OxyHb, and ${\mathrm{V}}_{\mathrm{MCA}}$-OxyHb was equal in the LFO range when subjects remained at supine rest but increased substantially more in young people with head-up tilt test and with active standing in another study.¹³⁹ This implies an increase in synchronization between systemic and CBF under sympathetic challenges such as positional changes and that this mechanism is impaired in the elderly.

ABP-OxyHb LFO phase analyses have disclosed equal phase shifts in young and elderly under rest^99,135 and during cognitive testing.¹³⁵ Wavelet studies have come to the same conclusion, as the ABP-OxyHb WPCO was homogenous across age groups at rest.^140,139 Meanwhile, interhemispheric analyses found lower WPCO with aging indicating desynchronization of myogenic CA at rest.^134,141

Oudegeest-Sander et al.¹³⁷ examined the VLFOs during a sit-stand maneuver and their regression analysis showed a trend toward higher ${\mathrm{V}}_{\mathrm{MCA}}$-OxyHb phase shift with age explained by increased vascular tortuosity. The WPCO between VLFOs of ABP and OxyHb in the elderly has also been investigated. At rest synchronization of neurogenic CA activity was higher in the elderly perhaps to compensate for the decline in myogenic CA activity.^140,139 During active standing, this difference evened out and both the neurogenic and metabolic CA synchronization was equivalent to the young.¹³⁹ Interhemispheric WPCO analysis also showed intact synchronization of metabolic and neurogenic activity.¹³⁴