What does the 'G point' represent?

The 'G point' represents maximum intercuspation, where all teeth are touching as tightly as possible.

What is physiological rest position?

It's the position where the mandible is slightly open from maximum intercuspation.

What is the role of canine guidance?

Canine guidance ensures that posterior teeth do not touch when the mandible slides to the side.

How is the Bennett movement described?

Bennett movement refers to the lateral movement of the condyle during jaw motion.

What is a Bennett angle?

The angle formed between the line of mandibular movement and the sagittal line during lateral movements.

What are overjet and overbite?

Overjet refers to horizontal overlap of teeth, while overbite refers to vertical overlap.

What can happen if occlusion is incorrect?

Incorrect occlusion can lead to issues like impinging overbite, potentially causing periodontal disease and gingivitis.

Why is canine guidance important in mandibular motion?

It protects posterior teeth from contact during lateral movements and ensures smooth motion of the mandible.

Occlusion Part 2

00:08:58

https://www.youtube.com/watch?v=0G6xEWOUs1E

Résumé

TLDRRyan explains the dynamics of mandibular movements, focusing primarily on occlusion and related concepts. He discusses how the mandible moves from the frontal plane, elaborating on points like maximum intercuspation and physiological rest. The video emphasizes the importance of canine guidance, where maxillary and mandibular canines prevent the posterior teeth from contacting during lateral movements. Ryan uses visual aids, such as the pults diagram, to illustrate mandibular range of motion. He also introduces terms like Bennett movement and Bennett angle, explaining their relevance to mandibular lateral motion, and the working versus non-working sides of the jaw. Moreover, Ryan touches on occlusion issues such as overjet and overbite, explaining their potential complications and the need for orthodontic intervention when occlusion is compromised. This video builds on the foundational concepts from his first video on occlusion.

A retenir

🦷 Maximum intercuspation is a key point where teeth touch tightly.
📈 Physiological rest position indicates a slightly open mandible state.
🔄 Canine guidance prevents posterior teeth contact during lateral moves.
🎥 Visual aids like the pults diagram show mandibular movement range.
↔️ Bennett movement describes lateral condyle motion.
📐 Bennett angle arises from mandibular lateral motion.
🔄 Working and non-working sides affect how jaw moves.
⚠️ Overjet and overbite issues can lead to periodontal problems.
🦷 Occlusion issues require orthodontic solutions.
📚 Understanding occlusion is crucial for dental health.

Chronologie

00:00:00 - 00:08:58
In this part two video on occlusion, Ryan delves into the frontal motion of the mandible, focusing on maximum intercuspation, where all teeth are tightly touching. He explains key points: the G point for maximum intercuspation, R point for physiological rest position, and E for maximum opening. The video emphasizes understanding mandible movement from different planes and describes how canine guidance ensures posterior teeth don't touch during lateral motion, explaining the role of maxillary and mandibular canines. Ryan suggests observing canine guidance through videos or models to better grasp its concept.

Carte mentale

Questions fréquemment posées

What does the 'G point' represent?
The 'G point' represents maximum intercuspation, where all teeth are touching as tightly as possible.
What is physiological rest position?
It's the position where the mandible is slightly open from maximum intercuspation.
What is the role of canine guidance?
Canine guidance ensures that posterior teeth do not touch when the mandible slides to the side.
How is the Bennett movement described?
Bennett movement refers to the lateral movement of the condyle during jaw motion.
What is a Bennett angle?
The angle formed between the line of mandibular movement and the sagittal line during lateral movements.
What are overjet and overbite?
Overjet refers to horizontal overlap of teeth, while overbite refers to vertical overlap.
What can happen if occlusion is incorrect?
Incorrect occlusion can lead to issues like impinging overbite, potentially causing periodontal disease and gingivitis.
Why is canine guidance important in mandibular motion?
It protects posterior teeth from contact during lateral movements and ensures smooth motion of the mandible.

Voir plus de résumés vidéo

Accédez instantanément à des résumés vidéo gratuits sur YouTube grâce à l'IA !

Sous-titres

Défilement automatique:

00:00:00
hey everyone this is Ryan and this is a
00:00:03
part two video for occlusion uh make
00:00:06
sure if you haven't already seen my part
00:00:08
one on occlusion to get some some basic
00:00:13
ideas of why the mandible moves how it
00:00:17
moves and the range of motion as
00:00:21
represented by this lateral diagram uh
00:00:23
called the pult
00:00:27
diagram all right so so I already talked
00:00:30
about the lateral motion of the manable
00:00:33
let's talk a little bit about the
00:00:34
frontal motion or I should say the
00:00:37
motion of the mandible from a frontal
00:00:41
plane so this G point was maximum
00:00:47
intercuspation likewise this G point is
00:00:50
is representing maximum
00:00:53
intercuspation or the position at which
00:00:57
all of the teeth are touching are
00:01:00
including as tightly as possible and
00:01:03
this R here correlates with this R here
00:01:06
and that's physiological rest position
00:01:08
where the mandible is slightly open from
00:01:11
Mi or maximum
00:01:14
intercuspation this point down here
00:01:16
would represent e which is maximum
00:01:19
opening and you can't really see here
00:01:23
but you can imagine a line through here
00:01:26
and here would represent the
00:01:30
extended extended opening and Centric
00:01:34
relation and this protruded movement all
00:01:38
these these these planes here sort of
00:01:41
Squish back into one line so so you
00:01:44
can't really appreciate them from the
00:01:46
frontal view but what you can appreciate
00:01:49
is the lateral motion of the
00:01:51
mandible as you uh move it side to
00:01:56
side
00:01:57
so maybe you're wondering why why
00:01:59
doesn't it just go straight
00:02:01
across well this these divots here are a
00:02:05
result of what's called anterior or or
00:02:09
canine
00:02:10
guidance and canine guidance is
00:02:14
essentially when canines the the
00:02:16
maxillary canines and mandibular canines
00:02:19
together because they're the longest
00:02:22
teeth ensure that the posterior teeth do
00:02:25
not touch when the mandible is sliding
00:02:30
to the
00:02:31
side so the best way to really see this
00:02:35
uh for yourself and and I think the best
00:02:36
way to understand it is either to to
00:02:38
watch a a video of canine guidance or to
00:02:41
have in your hand that that seethrough
00:02:45
denor and slide
00:02:48
it from Slide the the maxillary or or
00:02:52
the mandibular Arch to the side and
00:02:54
you'll notice that as you slide the
00:02:56
canines are the first teeth to touch
00:03:00
and those posterior teeth won't touch at
00:03:04
all until the canines are tip to tip and
00:03:08
then after that point you lose canine
00:03:11
guidance so remember the pults diagram
00:03:14
is representing the mandip range of
00:03:16
motion so this Mand mandible you can
00:03:19
think of it as it's as it's going over
00:03:22
this cusp tip of the canine it's going
00:03:25
down and then right here is where it's
00:03:28
going to reach the tip and then this
00:03:31
rest of the way you you lose Canon
00:03:34
guidance so it's the same on this side
00:03:36
hopefully that makes
00:03:38
sense and so these two points here would
00:03:41
would represent the maximum right
00:03:45
lateral and the maximum left
00:03:51
lateral okay great so while we're
00:03:53
talking about lateral movement of the
00:03:54
jaw let's just hop down to this diagram
00:03:57
here let me change my color getting sick
00:04:00
of that
00:04:02
blue so when we talk about the lateral
00:04:07
movement of the mandible there's sort of
00:04:08
two sides we talk about the working
00:04:11
side which I I should say this would be
00:04:15
consider the working side because you're
00:04:17
the mandible moves in the direction of
00:04:21
the working side so here's where the
00:04:23
mandible was and here is where it moved
00:04:27
to and this would be the non-working or
00:04:31
balancing side of the
00:04:33
mandible and then of course if we move
00:04:36
the mandible to the left the rules would
00:04:38
be switched this would be the working
00:04:40
side and this would be the non-working
00:04:42
side for all intents and purposes this
00:04:45
diagram shows that the manable is going
00:04:47
to the right so the right side is going
00:04:48
to be the working side and this if if we
00:04:51
track one point in the in the cond head
00:04:56
you see that this W1 was the middle of
00:05:00
the cond head before motion and this is
00:05:04
where it ended up after motion so that's
00:05:07
called
00:05:09
um the Bennett
00:05:12
movement and now more important for
00:05:15
clinicians is is is H the more important
00:05:18
concept for clinicians is happening on
00:05:20
the the non-working side and that
00:05:24
involves what's called benit angle and
00:05:27
so this time we we do the same thing we
00:05:30
take one point in the m in the
00:05:33
mandibular condo or the condar head and
00:05:36
then we see where it ended up after
00:05:39
motion now you'll notice that the
00:05:43
working side stayed in its
00:05:46
faasa the non-working
00:05:48
side ironically did more work and came
00:05:53
up and down ran
00:05:56
down this articular eminence
00:06:00
as the jaw uh came out this in this
00:06:05
direction so this these two points here
00:06:09
we can draw a line through them which
00:06:12
represents this line of the angle and
00:06:14
then this line is is
00:06:16
simply um A A A sagittal line a median
00:06:22
line going um perpendicular to the
00:06:25
coronal plane of the of the body however
00:06:27
you want to think about it and this
00:06:30
angle between the median line and the
00:06:34
the line between points of man of the
00:06:36
mandible before and after movement forms
00:06:40
the benit
00:06:43
angle all right and just to briefly
00:06:46
touch on this concept um here we
00:06:50
have overjet and
00:06:53
overbite so remember that ol clusion has
00:06:57
sort of two goals one is that the teeth
00:07:00
need to need to interdigitate properly
00:07:04
and two they need to uh occlusion needs
00:07:07
to allow for the free motion of
00:07:09
teeth so there can't be obstacles or
00:07:12
teeth can't be bumping into one another
00:07:14
before all the rest
00:07:15
do and you want to obtain maximum
00:07:20
intercuspation so here we
00:07:23
have
00:07:25
um not great
00:07:28
occlusion and
00:07:30
what happens is instead of this uh
00:07:33
incisal edge of the mandibular
00:07:35
inzer
00:07:37
contacting its an
00:07:40
antagonist um more more in sizely it
00:07:44
it's contacting it more uh
00:07:48
cervically and this results in two
00:07:51
things one is this this concept of
00:07:54
overjet which which refers to horizontal
00:07:58
overlap
00:07:59
and if the overjets really
00:08:02
bad you'll also see paired with it um
00:08:06
vertical overlap which is where the the
00:08:09
bottom teeth are are coming too far up
00:08:13
and overbite could um could result in
00:08:18
impinging overbite where if this tooth
00:08:21
were slid back a little bit it would be
00:08:22
touching it wouldn't even be touching
00:08:24
this tooth it would be touching the gums
00:08:26
which has terrible consequences for
00:08:28
things like onal disease and
00:08:31
gingivitis so these are some of the
00:08:35
things that can happen when occlusion is
00:08:38
not correct and you would need to
00:08:41
undergo uh most likely orthodontic
00:08:44
treatment to get your bite
00:08:48
fixed so I hope this video is helpful
00:08:51
and I'll see you next
00:08:54
time thanks for
00:08:56
watching