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    Hello everyone, welcome to another lecture of Drug Delivery Engineering and
    principles. So far in this course we have discussed several things; initially we discussed
    pharmacokinetics, pharmacodynamics of the drugs, we discussed about pro drugs. And
    then, from there on we started talking about how can we then change this free drug
    delivery to something else so, that it gives us a very high sustained release as well as
    controlled delivery.
    So, in that we have discussed, first of all, polymer drug conjugate, which is essentially
    adding the polymers to the drug which increases their size as well as prevent
    degradation. We have even talked about using some sort of a matrix so it could be a
    reservoir system. So, you have a big reservoir and then you have slow release. So, few
    drug through that either just by diffusion through a small pore or by an osmotically
    driven pressure that causes the release of this.
    Then we have also talked about matrix based delivery. So, these could be non-erodible;
    that means, they will not degrade, but then the drug can slowly diffuse out from these
    systems. Once you implant this you will have to basically do a surgery to first put them
    in and then another surgery you take them out or you can change that by then making
    them bio-erodibles and what that does is, the implant will just a erodes and as it erodes
    the drug will come out. It could be a combination of both erosion and diffusion and in
    that way, you will only have to do one surgery because once you put it in, after a certain
    period of time which could be weeks or months depending on what type of implant it is,
    it will just degrade and go away.
    Then we finally, discussed some sort of examples of these two matrix types of delivery
    using hydrogels. So, hydrogels can again be both either erodible or non erodible, but then
    depending on what you are using in terms of polymer, they might degrade or they might
    stay there forever. And then we discuss how hydrogels are being used for drug delivery,
    what is the concept there. So, this is a swelling based method and then also discuss some

    of the mathematics behind how to figure out how much swelling ratio is there, how much
    the pore size is in a hydrogel. So, that helps us in defining what kind of drug to use and
    what drug is feasible as well as what will be the release rate of the drug.
    So, now so, these were all macro devices more often than not we require surgery
    although in terms of hydrogels, we were talking about in situ cross linking, and that
    means that we do not have to do surgery we can directly inject, but for nearly all other
    types of applications we have to discussed, so far, and in terms of matrix, reservoir and
    all kinds of things. We are talking about some either small surgery or big surgery being
    performed to put these things in and in some cases also another surgery being performed
    to take them out.
    So, today we are going to talk about another class of drug release devices and these are
    macro and nano devices; and very big, famous words these days and lots and lots of
    research are going on in terms of making microparticles, nanoparticles and then using
    them for clinical applications. And so, we will talk about in discuss this in quite a bit of
    detail as to what these things are and how they are being used for different applications.
    (Refer Slide Time: 03:43)

    So let us start with the nano and microparticles. So, like what we have discussed in the
    past with all kinds of our initial systems as matrices and reservoirs, these are also control
    release depot systems.

    Very similar to these matrices, reservoirs and hydrogels, they can take any of these
    forms, but now instead of having a big macro device, you have now split that into small
    devices. And what that allows you to do now is basically directly inject these devices
    into the body using some syringe - this is let us say 1 centimeter or even higher, but now
    that these are less than, let us say, 1 millimeter, we can use standard syringes which are
    having diameters in some micron ranges and directly injected into a system whereever
    we want to put them in.
    So, this also allows you to decrease the nonspecific delivery of the drug to non-target
    tissues. So, let us say, if I want to deliver something to my brain, I cannot really put a
    device to my brain because a brain is a very sensitive organ and I do not want to damage
    it. So, maybe I was putting it under my skin somewhere and then hoping that the drug
    will then come out from this and diffuse and go into the brain. But now, with these
    injections, I can find a small pocket where I can inject without worrying about damage to
    the brain itself and so, that will basically mean that more of my drug is going to get
    release in the tissue that I want rather than they lying on the body to diffuse it or to take
    it to different organs.
    As I said, the one of the biggest advantage is their injectable. So, there is really no need
    for surgical implantation. One of the biggest issue with this is the hospital visits and the
    patient compliance every time we talk about surgery, the patients are also worried about
    their lives and that will can be lots and lots of complications that may happen, anesthesia
    is involved and those can always be little tricky. And then there are the chances of an
    more and more infections because once your body is open from the environment, you
    can contract lots and lots of different types of infections. So, all of that can be sort of
    countered using these particles.
    It is again a very convenient way to deliver things inside the cells. So far what we have
    been doing is, we have been relying on the drug to basically go and diffuse into the cell
    that is ok for small drugs which are fairly amphiphilic or hydrophobic, but for the drugs
    which are large and hydrophilic or maybe even charged, those drug molecules do not
    really diffuse into the cells. So, let us say if I want to make a device or a drug that is
    targeting the DNA of a cell, then the cell is a very good barrier - these lipid membranes
    that are represented on the cell, any kind of hydrophilic molecule will just be repelled
    away and it will not be able to enter the cell, but we will talk about how these nano- and

    micro- particles can actually help us target this intracellular niches well if we want to
    target that.
    And then, of course, they can we can also further target them. So, that what types of cells
    or what types of tissues, we want them to go to even though they might be systemically
    administered. Because they are small and they can go around and explore their way
    through different areas, you can have a situation where you can put a (ligand on them for
    extra targeting). Let us say, this is flowing in a blood vessel; let us say this is the blood
    vessel and your particles are flowing, let us say this is a healthy region, this is a healthy
    tissue and then this blood vessel is now traversing to let us say diseased tissue.
    And maybe you do to the disease, there may be a some markers that are being expressed
    on to these endothelial cells which are not present here. So, what you can put what you
    can do is, you can put a subsequent ligand on these particles and since they are flowing
    they will explore and essentially use these ligands to bind to the receptors and they can
    hence impart more specificity. Because what will happen is more and more of these
    particles will accumulate at the disease site while they continue to flow through the
    healthy tissue.
    So, that is another way that the these particles give you a lot more control and targeting,
    then let us say a big macro device. And then like the macro device, they can improve the
    stability of the drug in vivo of course, if there is enzymes that can degrade the drug, these
    particles at least till they are flowing in the blood, they will prevent this enzyme to get
    access to the drug. And only when the drug is released from the particle or when they
    reach the target site is these can act.
    So, this gives you an additional stability for the drug molecule. And then it also improves
    the shelf life for the same reason- now this drug is not really liable to degrade due to
    various processes that might be present in your storage buffer or in storage conditions.
    So, these polymers sort of act as shield, so, till they are given and administer into the
    patient they might be able to increase the shelf life of the product.
    So, let us say if a drug was very liable to degradation over time due to some particular
    contamination in your storage or due to some temperatures fluctuations, these polymers
    may increase the shelf life by any anything between 10 percent to 100 percent or just
    depends on the drug that you are using.

    (Refer Slide Time: 10:23)

    Let us further talk about particles in drug delivery. So, particles are fairly standard, these
    are some SEM images (scanning electron microscope images) the particles, which shows
    some polymeric particles of various sizes into this mixture.
    So, let us define few things. So, microparticles are typically defined in the literature for a
    size greater than 1 micron in any of the dimensions, but they can be spherical they can be
    some other shape as well. But if the micro particle size is greater than 1 micron typically
    between 1 to 100 that is typically defined as a microparticle. Nanoparticles defined in the
    size range of anything between 10 nanometer to 1000 nanometers, again these are these
    are not standards- these are something that generally the field follows, but what you will
    find is even in the literature people may have a 2 micron particle and they may have refer
    to that is nanoparticle and vice versa they may have a 500 nanometer particle which they
    might refer to as a micro particle.
    So, these definitions are bit fluidic, but this is what typically is being defined here. The
    drugs are typically small molecules- these could be proteins (which are fairly large),
    these could be nucleic acids, peptides, enzymes -they are typically encapsulated in these
    particles. But one thing that you will find different here compared to your matrices is
    they can also be adsorbed or covalently linked to the surface.
    So, because what you have done now is, earlier you had a macro device, that had a
    certain surface area, which was fairly low when you compare the amount that can be

    added here in the bulk volume in this large bulk volume versus something on the surface.
    The ratio was fairly low for the surface area, but now what you have done is you have
    now broken this down into several small small particles.
    So, the amount of the drug that can be loaded on the surface has become quite
    significant, when you compare it to the amount of drug that can be put in the bulk
    volume. So, with the microparticles and nanoparticles, you now even have that capability
    that you can put things on surface and be still be able to load quite a lot of drug. As the
    size decreases, this surface area to volume ratio will increase.
    So, let us say for a particle, what is the surface area? Let us say it is a spherical particle.
    So, we have surface area and we have volume. So, for spherical particle the volume is
    nothing, but
    V= 4πr3
    /3
    What is surface area for a sphere? It is nothing, but
    Surface Area = 4πr2
    when I say that the surface area by volume will increase as the particle size goes down.
    So, let us do that.
    Surface Area/Volume = 3/r this is for a spherical particle.
    So, as the r increases, the ratio decreases and as the r decreases, this ratio increases. So,
    eventually when you shift from this to this and further down to nanoparticles- let us say
    these are micro and then you go down further to nano what you will find is that the r is
    constantly decreasing as you are going there and your surface area to volume ratio is
    increasing. So, now, you can load more drug inside on the surface, then in the volume at
    a certain size range for a certain application. And then of course, these particles can be in
    form of as I said they can take various forms, they can either be a matrix, or reservoirs
    so, you can have sort of particles that are completely hollow - you can load your drug in
    them. So, they are sort of a mimic for reservoir system or you can have a particle which
    is completely filled with polymer and then that drug is essentially just encapsulated in
    between these polymer chains. So, this is sort of a matrix system and then, as I said,
    matrix systems can both be erodible or non erodible.

    So, these particles can also have the same form, they can either degrade and release the
    drug or the drug just has to diffuse out from these polymer matrices. So, all of those are
    fairly feasible the same applications, and the same sort of kinetics are applied just the
    surface area and the volume is changed.
    (Refer Slide Time: 15:53)

    So some more terms, definitions here- what we are looking at, is the filtration through
    kidney; so, this is the kidney that is zoomed in. And what we are looking at here is the
    interface between the blood vessels and the kidney cells. So, we have discussed this
    briefly earlier, but now we are trying to find out what will give us an enhanced
    circulation of these particles, in vivo. So, if I have a particle which is, let us say, in 100
    nanometer size range right what will happen is the endothelium itself is tight enough that
    these particles cannot go into the kidney cells or kidney tissue.
    So, these endothelial cells and whatever the surface proteins and glycoproteins that are
    present will be able to block that. Now as your size decreases from 100 nanometer down
    to 10 nanometer, this blocking will still happen but will continue to reduce. Once you go
    down below 6 nanometer where these particles are now between 2 to 6 nanometer, they
    can just pass through that and again the smaller the particles are, more the permeability.
    So, what you will find is in they will start going in the kidney tissue in higher numbers as
    it goes down. However, what happens is at a certain size range let us say below 1
    nanometer or around 1 to 2 nanometer what will happen is, now the sizes are so small

    that they might start interacting with these glycoprotein surface. So, if I zoom into this is
    essentially nothing, but a cell surface with lots and lots of proteins and sugar moieties
    that are present on the cell membrane.
    So, earlier what was happening if I have particle which is fairly big compared to all
    these, this particle was not even going in there and will just go out from some
    surrounding area. But now that the particle has decreased and it did become a size which
    can actually go into these glycocalyx or glycoproteins, what will happen is the particle
    that starts going in there gets entrapped, then has to go through a long tortuous route
    before it can go out. So, because of that now their residence time or at least the filtration
    through kidney has become lower and lower.
    So, this happens to certain extent and then there will be a time when this size becomes so
    small that even if it is interacts with it still goes right through. So, what you find is the
    filtration by the kidney essentially act as a band pass, where anything above 6 nanometer
    is not filtered at all. Whereas, as you decrease the size from 6 nanometer down to 1
    nanometer more and more particles get cleared. But if you go further down, then it gives
    much more resistance as well. So, that is just something to understand and remember.
    So, again and this is just describing what I just said. So, nanoparticles with the
    hydrodynamic diameter of greater than 100 cannot traverse to the endothelium, in
    between 6-10 nanometer, they cannot cross this basement membrane, which is fairly
    impermeable to any of these particles. Once you get down between 1 and 6 nanometer,
    they can go through this basement membrane. The basement membrane is nothing, but a
    membrane below the endothelial cells and the smaller they are the faster they will go up
    to one nanometer or so. And then the nanoparticles with the hydrodynamic diameter
    even less than 1 nanometer will then interact with this endothelial glycocalyx and that
    would mean that once they are in that size range in the similar pore size. They will
    interact more they will have a longer path, they will then have to travel and that will
    cause these smaller particles to have a larger residence in the blood vessel in this region,
    then let us say a smaller particle.

    (Refer Slide Time: 20:15)

    And let us talk about how the charge plays a role. Let us say now the particles can also
    be charged they are still moving around. So, the charge could be either negative, neutral,
    or positive. So, what happens in all three conditions? So, as we see here, if it is fairly
    neutral, there is really not a whole lot of interaction that is happening. So, it may have a
    certain sort of a flow through that, but the basement membrane itself is negatively
    charged. So, if you have positively charged particles, because of the electrostatic
    interaction more and more will come and they will have a higher flow through that.
    Weakly negative charge also does not really play a whole lot, but if it is highly
    negatively charged, they will be repelled by the basement membrane and they will have a
    higher circulation time. So, that is what is written here. So, essentially positive charge
    nanoparticles are cleared faster than the neutral ones, followed by the negative charged
    particles because of the basement membrane, which is negatively charged and that is
    why you see the effect that I just described. I will stop right here and we will continue in
    the next class.
    Thank you.