About The Aiello Protocol™

Biofield Laser Balancing Protocol

Acoustic timing testing + near‑infrared laser segmental sensory stimulus to support whole‑body regulation

Many chronic symptoms don’t behave like isolated “parts problems.” They come and go, flare under stress, shift systems, and show up as patterns, fatigue with brain fog, pain with sleep disruption, allergies with autonomic swings, dizziness with GI changes. In our clinic we view many of these patterns through a regulation-and-timing lens: the body is constantly synchronizing sensory input, internal physiology, and motor output. When that synchronization becomes strained, the body can still stabilize, but often by running compensations that cost energy and reduce resilience.

A brief introduction: biofield + thalamic timing

In this protocol, the biofield refers to the body’s organizing layer, the way living systems coordinate timing, recognition, and recovery across many tissues at once. This is not presented as mysticism. It is a practical way to describe coherent regulation: multiple systems must remain “in sync” for you to feel stable.

A central player in whole-body timing is the thalamus, a major filtering and timing hub that helps coordinate what sensory information is emphasized, how it is synchronized, and how it is routed into higher processing. When timing is stable, the system tends to behave predictably. When timing is strained, the system can become reactive, noisy, or “stuck” in protective patterns. Clinically, we describe this as a thalamocortical timing problem, not necessarily structural disease, but a regulation problem.

The Aiello Method™ is a structured way to assess and support this timing and regulation using two tools:

Acoustic timing testing (monaural beats) to reveal thalamic compensation patterns
Near‑infrared laser segmental sensory stimulus to provide a clear, targeted stability input to specific segmental levels feeding the thalamus.

Step 1: Preclear

Settling the system so testing becomes readable

Some patients arrive in a high‑gain “over stabilizing” mode where the nervous system is working hard just to hold itself together. When that happens, deeper compensation patterns may be difficult to detect reliably.

We begin with a short preclear procedure using acoustic timing cues. The purpose is simple: reduce neurologic activity and help the system settle into a state we can accurately assess. This is brief 15-20 minutes, noninvasive, and adjusted to tolerance.

Step 2: A‑Phases

A simple map of how “loaded” the regulation system is

To keep the model practical, we describe the nervous system’s operating mode in A‑phases. These phases are not diagnoses. They are a way of describing how much stabilization work the system is doing at the moment.

A0 — Baseline / Resting Stability
A low‑demand state where stability is maintained efficiently. The system can rebuild reserve.
A1 — Active Stability
Normal daily function :biofield templates are running (movement, attention, digestion, autonomic shifts), while stability is maintained without overload.
A2 — Overload / High‑Gain Stabilization
The system is strained and symptoms often appear because too many stabilization demands are running at once (brain fog, fatigue, irritability, heightened sympathetic tone, sleep disruption, influenza/cold symptoms, etc.). This is the phase we use the preclear to stabilize.
A3 — Compensated Baseline
The system can look “resting” on the surface, but it is holding baseline at a higher cost. Recovery is less reliable and the threshold to fall into A2 is lower. This is the phase we are looking to detect and treat.

Preclear helps us distinguish whether you’re truly in a stable baseline state or holding stability through compensation.

Step 3: Acoustic Timing Testing (Monaural Beats)

Revealing neurologic compensation patterns

Next we perform acoustic timing testing using monaural beats delivered through headphones. We use this timing input as a structured provocation and mapping tool. Changes in timing can temporarily reveal how your system is stabilizing in the A3 phase.

The goal is not to “chase symptoms.” The goal is to identify whether the system is:

running a stable baseline, A0 state.
running an overload pattern, A2 and even possibly A1.
or holding baseline through a compensationA3 state.

A key clinical feature is that compensation patterns often show up as side‑dominant responses. That sided response helps guide the next steps. We detect this side dominance by performing postural muscle strength testing during monaural beat provocation.

Step 4: From Timing Response to Compensation Direction

Why “which side” matters

When the system is compensating, it often does so in a lateralized way, meaning one side of the thalamocortical timing loop is carrying more of the stabilization load and the other side is suppressed.

In this model, that sided pattern helps direct us toward which side of the body and which segmental regions are most involved in the compensation strategy. Instead of treating only the location of symptoms, we are looking for where stability is being held at the level of regulation.

Step 5: Segmental Mapping with Violet Provocation

Locating segments that behave like they’ve lost stability

Once the sided compensation pattern is identified, we use brief violet laser provocation across segmental regions. This is not used as a treatment step. It is used as a mapping step to identify which segmental levels respond abnormally when challenged.

This helps us localize where the system’s segmental organization appears most strained, where stability is most expensive to maintain. This directs us to which segments will be stimulated by near infrared laser therapy.

Step 6: Correction Phase

10 Hz timing support + near‑infrared laser segmental sensory stimulus

Once the side and segmental levels are identified, we combine two inputs:

Acoustic timing support at 10 Hz
In our model, 10 Hz represents a practical reference point for stable thalamic timing.
Near‑infrared laser segmental sensory stimulus over the identified levels
Near‑infrared stimulation is applied in a targeted way to the segmental levels that mapped as unstable.

The purpose of combining these inputs is to support the system from both directions:

central timing support (thalamic timing reference), and
segmental stabilization input (targeted biofield stimulus at the levels that have lost coherence)

This pairing is the essence of the Biofield Laser Balancing Protocol: use timing to reveal how the system is compensating, then apply a coherent, segmentally targeted input to support a more efficient baseline state.

What a visit typically includes

Brief history focused on triggers, relief patterns, and recovery capacity
Preclear (sound-based timing)
A‑phase snapshot (how loaded the system is today)
Acoustic timing testing (mapping compensation patterns)
Violet provocation mapping (segmental localization)
10 Hz timing + near‑infrared segmental stimulus (correction phase)
Retest and plan (what we found, what to watch for, next steps)

Conditions people often seek care for

This method is designed for whole‑system regulation patterns, especially when symptoms involve multiple domains (sleep, stress response, sensory sensitivity, inflammation, autonomic imbalance, pain instability, and shifting symptom clusters). Patients commonly come in for concerns that fall into these categories:

Allergies, immune and inflammatory conditions
Digestive and visceral dysfunction
Headache, dizziness, and sensory disorders
Neurologic and functional disorders
Orthopedic and musculoskeletal conditions
Stress, fatigue, and autonomic imbalance
Thalamocortical timing and regulation patterns
Biofield and neurologic coherence education