Precise timing is ubiquitous, consistent, and coordinated across a comprehensive, spike-resolved flight motor program

Abstract: Sequences of action potentials, or spikes, carry information in the number of spikes and their timing. Spike timing codes are critical in many sensory systems, but there is now growing evidence that millisecond-scale changes in timing also carry information in motor brain regions, descending decision-making circuits, and individual motor units. Across all of the many signals that control a behavior, how ubiquitous, consistent, and coordinated are spike timing codes? Assessing these open questions ideally invol… Show more

“…From here, we calculated the the phase variable ψ(t) as the complex angle of H(φ)(t). This method of estimating phase from time series measurements is well established in the biology literature [39,40,18].…”

“…Manduca sexta typically fire only once per wingbeat [41,2,18], suggesting that wingbeat frequency is driven by a single event. Therefore, we defined an arbitrary phase threshold and defined wingbeat frequency as the inverse of the time between threshold crossings.…”

“…In Manduca sexta, wing kinematics are controlled by a set of 10 muscles, so any changes in wingbeat frequency likely affects the coordination of these muscles. In Manduca sexta, the downstroke is triggered by typically a single action potential to the left and right DLMs [46,2,18]. Precise changes in the activation phase of these DLMs can account for 50% of yaw torque production [2].…”

“…Because of the strong phase dependence of Manduca sexta DLMs [2], the nervous system may need to maintain precise control over muscle activation phase while the frequency of muscle strain changes from wingstroke-to-wingstroke. Further complications arise because recent work has shown that the timing of the 10 major muscles controlling wing kinematics are tightly coordinated in their activation timing [18]. Changes in wingbeat frequency may require changes in activation frequency for all ten muscles involved orchestrated through phase shifts across the entire motor program.…”

“…Insects have the capacity to change wingbeat frequency, regardless of whether they possess synchronous (neurogenic) or asynchronous (myogenic) flight strategies. In species with synchronous flight muscles such as Manduca sexta, wing motion is triggered by typically by a single action potential with sub-millisecond precision to the dorsolongitudinal muscles (DLMs) [17,2,18]. Although the nervous system can shift the timing of muscle activation [2], synchronous hawkmoths are often observed [4] and modeled [19,20] as maintaining a constant wingbeat frequency.…”

Hawkmoths use wingstroke-to-wingstroke frequency modulation for aerial recovery to vortex ring perturbations

“…From here, we calculated the the phase variable ψ(t) as the complex angle of H(φ)(t). This method of estimating phase from time series measurements is well established in the biology literature [39,40,18].…”

“…Manduca sexta typically fire only once per wingbeat [41,2,18], suggesting that wingbeat frequency is driven by a single event. Therefore, we defined an arbitrary phase threshold and defined wingbeat frequency as the inverse of the time between threshold crossings.…”

“…In Manduca sexta, wing kinematics are controlled by a set of 10 muscles, so any changes in wingbeat frequency likely affects the coordination of these muscles. In Manduca sexta, the downstroke is triggered by typically a single action potential to the left and right DLMs [46,2,18]. Precise changes in the activation phase of these DLMs can account for 50% of yaw torque production [2].…”

“…Because of the strong phase dependence of Manduca sexta DLMs [2], the nervous system may need to maintain precise control over muscle activation phase while the frequency of muscle strain changes from wingstroke-to-wingstroke. Further complications arise because recent work has shown that the timing of the 10 major muscles controlling wing kinematics are tightly coordinated in their activation timing [18]. Changes in wingbeat frequency may require changes in activation frequency for all ten muscles involved orchestrated through phase shifts across the entire motor program.…”

“…Insects have the capacity to change wingbeat frequency, regardless of whether they possess synchronous (neurogenic) or asynchronous (myogenic) flight strategies. In species with synchronous flight muscles such as Manduca sexta, wing motion is triggered by typically by a single action potential with sub-millisecond precision to the dorsolongitudinal muscles (DLMs) [17,2,18]. Although the nervous system can shift the timing of muscle activation [2], synchronous hawkmoths are often observed [4] and modeled [19,20] as maintaining a constant wingbeat frequency.…”

Hawkmoths use wingstroke-to-wingstroke frequency modulation for aerial recovery to vortex ring perturbations

Slowly activating outward membrane currents generate input-output sub-harmonic cross frequency coupling in neurons

Rapid frequency modulation in a resonant system: aerial perturbation recovery in hawkmoths