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Cellular mech. |
CELLULAR MECHANISMS of LOW-POWER LASER THERAPY (PHOTOBIOMODULATION)
Tina.I. KARU
1. What is photobiomodulation
(low-power laser therapy?)
More than 30
year ago the first publications about low-power laser
therapy or photobiomodulation (at that time called laser
biostimulation) appeared. Since then approximately 2000
studies have been published on this topic (analysis of these
publications can be found in [1]). Medical treatment with
coherent light sources (lasers) or noncoherent light (Light
Emitting Diodes, LED's) has passed through its childhood and
early maturity. Photobiomodulation is being used by
physiotherapists (to treat a wide variety of acute and
chronic muscosceletal aches and pains), dentists (to treat
inflamed oral tissues, and to heal diverse ulcerations),
dermatologists (to treat oedema, indolent ulcers, burns,
dermatitis), rheumatologists (relief of pain, treatment of
chronic inflammations and autoimmune diseases), and by other
specialists (e.g., for treatment of middle and inner ear
diseases, nerve regeneration). Photobiomodulation is also
used in veterinary medicine (especially in racehorse
training centers) and in sports medicine and rehabilitation
clinics (to reduce swelling and hematoma, relief of pain and
improvement of mobility and for treatment of acute soft
tissue injuries). Lasers and LED's are applied directly to
respective areas (e.g., wounds, sites of injuries) or to
various points on the body (acupuncture points, muscle
trigger points). For details of clinical applications and
techniques used, the books [ 1-3] are recommended.
2. What light sources
(lasers, LED's) can be used?
The field of
photobiomodulation is characterized by variety of
methodologies and use of various light sources (lasers,
LED's) with different parameters (wavelength, output power,
continuous wave or pulsed operation modes, pulse
parameters). These parameters are usually given in
manufacturers manuals.
The GaAlAs
diodes are used both in diode lasers and LED's, the
difference is whether the device contains the resonator (as
the laser does) or not (LED). In latter years, longer
wavelengths (-800-900 nm) and higher output powers (to 100
mW) are preferred in therapeutic devices.
Should a
medical doctor use a laser or a diode? The answer is - it
depends on what one irradiates, in other words, how deep
tissue layers must be irradiated. By light interaction with
a biotissue, coherent properties of laser light are not
manifested at the molecular level. The absorption of
low-intensity laser light by biological systems is of a
purely noncoherent (i.e., photobiological) nature. On the
cellular level, the biological responses are determined by
absorption of light with photoacceptor molecules (see the
section 3 below). Coherent properties of laser light are not
important when cellular monolayers, thin layers of cell
suspension as well as thin layers of tissue surface are
irradiated (Fig. 1). In these cases, the coherent and
noncoherent light (i.e., both lasers and LED's) with the
same wavelength, intensity and dose provides the same
biological response. Some additional (therapeutical) effects
from the coherent and polarized radiation (lasers) can occur
in deeper layers of bulk tissue only and they are connected
with random interference of light waves. An interested
reader is guided to the ref. [4] for more details. Here we
illustrate this situation by Fig. 1. Large volumes of tissue
can be irradiated by laser sources only because the length
of longitudinal coherence Lcoh is too small for noncoherent
radiation sources [4].
3. Enhancement of cellular
metabolism via activation of respiratory chain: a universal
photobiological action mechanism
A
photobiological reaction involves the absorption of a
specific wavelength of light by the functioning
photoacceptor molecule. The photobiological nature of
photobiomodulation means that some molecule (photoacceptor)
must first absorb the light used for the irradiation. After
promotion of electronically excited states, primary
molecular processes from these states can lead to a
measurable biological effect (via secondary biochemical
reaction, or photosignal transduction cascade, or cellular
signaling) at the cellular level. The question is, which
molecule is the photoacceptor.
Fig. 1. Depth
(On in which the beam coherency is manifested, and coherence
length Lcoh in various irradiated systems: (A)
monolayer of cells, (B) optically thin suspension of cells,
(C) surface layer of tissue and bulk tissue. Lcoh, -
length of temporal (longitudinal) coherence of laser
light, hw) marks the radiation.
When
considering the cellular effects, this question can be
answered by action spectra. Any graph
representing a photoresponse as a function of wavelength,
wave number, frequency, or photon energy, is called action
spectrum. Action spectra have a highest importance for
identifying the photoacceptor inasmuch as the action
spectrum of a biological response resembles the absorption
spectrum of the photoacceptor molecule. Existence of a
structured action spectrum is strong evidence that the
phenomenon under study is a photobiological one (i.e.,
primary photoacceptors and cellular signaling pathways
exist). Fig. 2 represents some examples of action spectra
for eukaryotic cells: two of them (A, B) consider the
processes occurring in cell nucleus, and one spectrum (C) is
for cell membrane. Fig. 2D shows the absorption spectrum of
the monolayer of the same cells.
Fig. 2. Action spectra of: (A) DNA and (B) RNA synthesis
rate in HeLa cells; (C) plasma membrane adhesion of HeLa
cells for red-to-near IR radiation; (D) absorption spectrum
of air-dried monolayer of HeLa cells for the same spectral
region. Original data can be found in ref. [5].
The spectra
in Fig. 2 represent the red-to-near infrared (IR) region
only, i.e. the region that is most important for
photobiomodulation. The action spectra for full
visibleto-near IR region can be found in [5]. In [5] one can
find action spectra for various cellular responses for other
eukaryotic and prokaryotic cells as well.
Two
conclusions can be drawn from action spectra in Fig. 2.
First, the similarity of the action spectra for different
cellular responses suggests that the primary photoacceptor
is the same for all these responses. Second, the existence
of the action spectra for biochemical processes occurring in
various cellular organelles (nucleus, Fig. 2A, B and plasma
membrane, Fig. 2C) assume the existence of cellular
signaling pathways inside of a cell between the
photoacceptor and the nucleus as well as between the
photoacceptor and cell membrane. Action spectra also
indicate, which wavelengths are the best for irradiation:
maximal biological responses are occurring when irradiated
at 620, 680, 760 and 820-830 nm (maxima of the spectra in
Fig. 2). Skipping over the story of identifying the
photoacceptor (described in [5]) let us conclude that
photoacceptor for eukaryotic cells in red-to-near IR region
is believed to be the terminal enzyme of the respiratory
chain cytochrome c oxidase (located in cell
mitochondrion). To be more exact, it is a mixed valence
(partially reduced) form of this enzyme, which has not yet
been identified. In the violet-to-blue spectral region,
flavoproteins (e.g., NADHdehydrogenase in the beginning of
the respiratory chain) are also among the photoacceptors as
well terminal oxidases.
An important
point has to be emphasized. When the excitable cells (e.g.,
neurons, cardiomyocites) are irradiated with monochromatic
visible light, the photoacceptors are also believed to be
components of respiratory chain. Some of the experimental
evidence concerning excitable cells is shortly summarized in
Fig. 3. It is quite clear from experimental data (reviewed
in [4]) that irradiation can cause physiological and
morphological changes in nonpigmental excitable cells via
absorption in mitochondria. Later, similar irradiation
experiments were performed with neurons in connection with
low-power laser therapy. It was shown in 80's that He-Ne
laser radiation alters the firing pattern of nerves; it was
also found that transcutaneous irradiation with HeNe laser
mimicked the effect of peripheral stimulation of a
behavioral reflex. These findings were found to be connected
with pain therapy (review [4]).
So, what
happens when the molecule of photoacceptor absorbs photons?
Answer - electronic excitation followed by photochemical
reactions occurring from lower excitation states (first
singlet and triplet). It is also known that electronic
excitation of absorbing centers alters their redox
properties. Until yet, five primary reactions have been
discussed in literature (Fig. 4). Two of them are connected
with alteration of redox properties and two mechanisms
involve generation of reactive oxygen species (ROE). Also,
induction of local transient (very short time) heating of
absorbing chromophors is possible. Details of these
mechanisms can be found in [4, 5].
There is no
ground to believe that only one of the reactions shown in
Fig. 4 occurs when a cell is irradiated and excited
electronic states are promoted. The question is, which
mechanism is decisive. It is not excluded that all
mechanisms shown in Fig. 4 lead to a similar result, to a
modulation of redox state of the mitochondria (a shift to
more oxidized direction). However, depending on the light
dose and intensity used, some mechanism(s) can prevail
significantly [5].
The next
question is, the following if photoacceptors are located in
the mitochondria, then how the primary reactions occurring
under irradiation in the respiratory chain (Fig. 4) are
connected with DNA and RNA synthesis in the nucleus (the
action spectra in Fig. 2A, B) or with changes in plasma
membrane (Fig. 2C)? The principal answer is that between
these events there are secondary (dark) reactions (cellular
signaling cascades or photosignal transduction and
amplification, Fig. 5).
Three
regulation pathways are suggested in Fig. 4. The first one
is the control of photoacceptor over the level of
intracellular ATP. It is known tat even small changes in ATP
level can alter cellular metabolism significantly. This
regulation way is especially important by irradiation of
hypoxic, starving or otherways stressed cells. However, in
many cases the regulative role of redox homeostasis is
proved to be more important than that of ATP. For example,
it is known that the susceptibility of cells to hypoxic
injury depends more on the capacity of cells to maintain the
redox homeostasis and less on their capacity to maintain the
energy status.
The second
and third regulation pathways are mediated through the
cellular redox state (Eh; Fig. 4). This way involve
redox-sensitive transcription factors (NF-KB and AP1, Fig.
4) or cellular signaling homeostatic cascades from
cytoplasma via cells membrane to the nucleus (Fig. 4). As a
whole, the scheme in Fig. 4 suggests a shift in overcell
redox potential into more oxidized direction. Modulation of
cellular redox state affects gene expression namely via
transcription factors. It is important that in spite of some
similar or even identical steps in cellular signaling, the
final cellular responses to the irradiation differ due to
existence of different modes of regulation of transcription
factors. The mechanisms of regulation are not understood
well yet.
The magnitude
of cellular responses depends on cellular redox potential
(and its physiological status, respectively) at the moment
of irradiation. The cellular response is stronger when the
redox potential of the target cell is initially shifted to a
more reduced state (and intracellular pH, pH;, is lowered,
as usually happens in injured cells). This explains why the
degrees of cellular responses can differ markedly in
different experiments or in different clinical cases, and
why the effects are sometimes nonexistent.
One should emphasize that
some biological limitations exist for photobiomodulation
effects. These are discussed in [5].
4.
Enhancement of cellular metabolism via activation of
nonmitochondrial photoacceptors. Indirect
activation/suppression
The redox regulation mechanism cannot occur solely
via respiratory chain (Section 3). Other redox chains
containing molecules, which absorb light in visible-to-near
IR radiation, and are some key structures that can regulate
a metabolic pathway, can be photoacceptors for
photobiomodulation as well. One such example is
NADPH-oxidase of phagocytic cells, which is responsible for
nonmitochondrial respiratory burst. This multicomponent
enzyme system located in the plasma membrane is a redox
chain that generates reactive oxygen species (ROS) as a
response to the microbicidal or other types of activation.
Irradiation with He-Ne laser and diode lasers and LED's can
activate this chain in various phagocytic cells. Many worked
examples can be found in [5]. In phagocytes, the activation
of respiratory chains in mitochondria occurs as well, as
NADHP-oxidase activation, but the latter is much stronger.
ROS, burst of
which is induced by direct irradiation of phagocytes, can
activate or inactivate other cells, which were not
irradiated directly. In this way, indirect activation or
suppression of metabolic pathways in non-irradiated cells
occurs. Also, lymphokines and cytokines produced by
irradiated lymphocytes can influence metabolism of other
cells. This situation is common by irradiation on tissues.
5.
Concluding Remarks
The photobiological action mechanism via activation of
respiratory chain is a universal working mechanism for
various cells. Crucial events of this type of cell
metabolism activation are occurring due to a shift of
cellular redox potential into more oxidized direction as
well as due to ATP extrasynthesis. Susceptibility to
irradiation and capability for activation depend on
physiological status of irradiated cells: the cells, which
overall redox potential is shifted to more reduced state
(example: some pathological conditions) are more sensitive
to the irradiation. The specificity of final photobiological
response is determined not at the level of primary reactions
in the respiratory chain but at the transcription level
during cellular signaling cascades. In some cells, only
partial activation of cell metabolism happens by this
mechanism (example: redox priming of lymphocytes).
All
light-induced biological effects depend on the parameters of
the irradiation (wavelength, dose, intensity, irradiation
time, and continuous wave or pulsed mode, pulse parameters).
According to action spectra, optimal wavelengths are
820-830, 760, 680, and 620 nn. Large volumes and deeper
layers of tissues can successfully irradiated by laser only
(e.g. inner and middle ear diseases, injured siatic or
optical nerves, deep inflammations etc.). The LED's are
excellent for irradiation of surface injuries.
Cited Literature
1. Tuner, J.
and Hode, L. (1999). Low Level Laser Therapy. Clinical
Practice and Scientific Background. Prima Books, Grangesberg
(Sweden).
2. Baxter,
G.D. (1994). Therapeutic Lasers. Theory and Practice.
Churchill Livingstone, London.
3. Simunovic,
Z., editor (2000). Lasers in Medicine and Dentistry, vol. I.
Vitgraf, Rijeka (Croatia).
4. Karu, T.I.
(2002). Low power laser therapy. In: CRC Biomedical
Photonics Handbook, T. Vo-Dinh, Editor- in-Chief, CRC Press,
Boca Raton (USA).
5. Karu, T.I.
(1998). The Science of Low Power Laser Therapy. Gordon and
Breach Sci. Publ., London
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