Bio-inks are materials used to produce engineered/artificial live tissue using

3D printing 3D printing or additive manufacturing is the Manufacturing, construction of a three-dimensional object from a computer-aided design, CAD model or a digital 3D modeling, 3D model. It can be done in a variety of processes in which material is ...

. These inks are mostly composed of the cells that are being used, but are often used in tandem with additional materials that envelope the cells. The combination of cells and usually

biopolymer Biopolymers are natural polymers produced by the cells of living organisms. Like other polymers, biopolymers consist of monomeric units that are covalently bonded in chains to form larger molecules. There are three main classes of biopolymers, cl ...

gels are defined as a bio-ink. They must meet certain characteristics, including such as

rheological Rheology (; ) is the study of the flow of matter, primarily in a fluid (liquid or gas) state, but also as "soft solids" or solids under conditions in which they respond with plastic flow rather than deforming elastically in response to an appli ...

, mechanical, biofunctional and biocompatibility properties, among others. Using bio-inks provides a high reproducibility and precise control over the fabricated constructs in an automated manner. These inks are considered as one of the most advanced tools for tissue engineering and regenerative medicine (TERM). Like the thermoplastics that are often utilized in traditional

, bio-inks can be extruded through printing nozzles or needles into filaments that can maintain its shape fidelity after deposition. However, bio-inks are sensitive to the normal

processing conditions. Differences from traditional 3D printing materials * Printed at a much lower temperature (37 °C or below) * Mild cross-linking conditions * Natural derivation * Bioactive * Cell manipulatable

Printability

Bioink compositions and chemistries are often inspired and derived from existing hydrogel biomaterials. However, these hydrogel biomaterials were often developed to be easily pipetted and cast into well plates and other molds. Altering the composition of these hydrogels to permit filament formation is necessary for their translation as bioprintable materials. However, the unique properties of bioinks offer new challenges in characterizing material printability. Traditional bioprinting techniques involve depositing material layer-by-layer to create the end structure, but in 2019 a new method called volumetric bioprinting was introduced. Volumetric bioprinting occurs when a bio-ink is placed in a liquid cell and is selectively irradiated by an energy source. This method will actively polymerize the irradiated material and that will comprise the final structure. Manufacturing biomaterials using volumetric bioprinting of bio-inks can greatly decrease the manufacturing time. In materials science, this is a breakthrough that allows personalized biomaterials to be quickly generated. The procedure must be developed and studied clinically before any major advances in the bioprinting industry can be realized. Unlike traditional 3D printing materials such as thermoplastics that are essentially 'fixed' once they are printed, bioinks are a dynamic system because of their high water content and often non-crystalline structure. The shape fidelity of the bioink after filament deposition must also be characterized. Finally, the printing pressure and nozzle diameter must be taken into account to minimize the shear stresses placed on the bioink and on any cells within the bioink during the printing process. Too high shear forces may damage or lyse cells, adversely affecting cell viability. Important considerations in printability include: * Uniformity in filament diameter * Angles at the interaction of filaments * "Bleeding" of filaments together at intersects * Maintenance of shape fidelity after printing but before cross-linking * Printing pressure and nozzle diameter * Printing viscosity * Gellation properties

Classification of bio Inks

Structural

Structural bio inks are used to create the framework of the desired print using materials like alginate, decellularized ECM, gelatins, and more. From the choice of material you are able to control mechanical properties, shape and size, and cell viability. These factors make this type one of the more basic but still one of the most important aspects to a Bio-printed design.

Sacrificial

Sacrificial bio inks are materials that will be used to support during printing and then will be removed from the print to create channels or empty regions within the outside structure. Channels and open spaces are massively important to allow for cellular migration and nutrient transportation lending them useful if trying to design a vascular network. These materials need to have specific properties dependent on the surrounding material that needs to stay such as water solubility, degradation under certain temperatures, or natural rapid degradation. Non Crosslinked gelatins and pluronics are examples of potential sacrificial material.

Functional

Functional bio inks are some of the more complicated forms of ink, these are used to guide cellular growth, development, and differentiation. This can be done in the form of integrating growth factors, biological cues, and physical cues such as surface texture and shape. These materials could be described as the most important as they are the biggest factor in developing a functional tissue as well as structural related function.

Support

Bio printed structures can be extremely fragile and flimsy due to intricate structures and overhangs in the early period after printing, these support structures give them the chance to get out of that phase. Once the construct is self supportive, these can be removed. In other situations, such as introducing the construct to a bioreactor after printing these structures can be used to allow for easy interface with systems used to develop the tissue at a faster rate.

Polysaccharides

Alginate

Alginate Alginic acid, also called algin, is a naturally occurring, edible polysaccharide found in brown algae. It is hydrophilic and forms a viscous gum when hydrated. With metals such as sodium and calcium, its salts are known as alginates. Its colou ...

is a naturally derived biopolymer from the cell wall of brown seaweed that has been widely used in biomedicine because of its biocompatibility, low cytotoxicity, mild gelation process and low cost. Alginates are particularly suitable for bioprinting due to their mild cross-linking conditions via incorporation of divalent ions such as calcium. These materials have been adopted as bioinks through increasing their viscosity. Additionally, these alginate-based bioinks can be blended with other materials such as nanocellulose for application in tissues such as cartilage. Since fast gelation leads to good printability,

bioprinting Three dimensional (3D) bioprinting is the utilization of 3D printing–like techniques to combine cells, growth factors, and/or biomaterials to fabricate biomedical parts, often with the aim of imitating natural tissue characteristics. Generally, 3 ...

mainly utilizes

alginate Alginic acid, also called algin, is a naturally occurring, edible polysaccharide found in brown algae. It is hydrophilic and forms a viscous gum when hydrated. With metals such as sodium and calcium, its salts are known as alginates. Its colou ...

, modified alginate alone or alginate blended with other

biomaterials A biomaterial is a substance that has been engineered to interact with biological systems for a medical purpose, either a therapeutic (treat, augment, repair, or replace a tissue function of the body) or a diagnostic one. As a science, biomateria ...

. Alginate has become the most widely used natural polymer for bioprinting and is most likely the most common material of choice for

in vivo Studies that are ''in vivo'' (Latin for "within the living"; often not italicized in English) are those in which the effects of various biological entities are tested on whole, living organisms or cells, usually animals, including humans, and ...

studies.

Gellan Gum

Gellan gum Gellan gum is a water-soluble anionic polysaccharide produced by the bacterium ''Sphingomonas elodea'' (formerly ''Pseudomonas elodea'' based on the taxonomic classification at the time of its discovery). The gellan-producing bacterium was discov ...

is a hydrophilic and high-molecular weight anionic polysaccharide produced by bacteria. It is very similar to alginate and can form a hydrogel at low temperatures. It is even approved for use in food by the

United States Food and Drug Administration The United States Food and Drug Administration (FDA or US FDA) is a federal agency of the Department of Health and Human Services. The FDA is responsible for protecting and promoting public health through the control and supervision of food s ...

(FDA). Gellan gum is mainly used as a gelling agent and stabilizer. However, it is almost never used alone for bioprinting purposes.

Agarose

Agarose Agarose is a heteropolysaccharide, generally extracted from certain red seaweed. It is a linear polymer made up of the repeating unit of agarobiose, which is a disaccharide made up of D-galactose and 3,6-anhydro-L-galactopyranose. Agarose is o ...

is a polysaccharide extracted from marine algae and red seaweed. It is commonly used in

electrophoresis Electrophoresis, from Ancient Greek ἤλεκτρον (ḗlektron, "amber") and φόρησις (phórēsis, "the act of bearing"), is the motion of dispersed particles relative to a fluid under the influence of a spatially uniform electric fie ...

applications as well as tissue engineering for its gelling properties. The melting and gelling temperatures of agarose can be modified chemically, which in turn makes its printability better. Having a bio-ink that can be modified to fit a specific need and condition is ideal.

Protein-based Bio-inks

Gelatin

Gelatin Gelatin or gelatine (from la, gelatus meaning "stiff" or "frozen") is a translucent, colorless, flavorless food ingredient, commonly derived from collagen taken from animal body parts. It is brittle when dry and rubbery when moist. It may also ...

has been widely utilized as a biomaterial for engineered tissues. The formation of gelatin scaffolds is dictated by the physical chain entanglements of the material which forms a gel at low temperatures. However, at physiological temperatures, the viscosity of gelatin drops significantly. Methacrylation of gelatin is a common approach for the fabrication of gelatin scaffolds that can be printed and maintain shape fidelity at physiological temperature.

Collagen

Collagen Collagen () is the main structural protein in the extracellular matrix found in the body's various connective tissues. As the main component of connective tissue, it is the most abundant protein in mammals, making up from 25% to 35% of the whole ...

is the main protein in the

extracellular matrix In biology, the extracellular matrix (ECM), also called intercellular matrix, is a three-dimensional network consisting of extracellular macromolecules and minerals, such as collagen, enzymes, glycoproteins and hydroxyapatite that provide stru ...

of mammalian cells. Because of this collagen possesses tissue-matching

physicochemical Physical chemistry is the study of macroscopic and microscopic phenomena in chemical systems in terms of the principles, practices, and concepts of physics such as motion, energy, force, time, thermodynamics, quantum chemistry, statistical mecha ...

properties and biocompatibility. On top of this, collagen has already been used in

biomedical Biomedicine (also referred to as Western medicine, mainstream medicine or conventional medicine)

applications. Some studies that collagen has been used in are engineered skin tissue, muscle tissue and even bone tissue.

Synthetic Polymers

Pluronics

Pluronics have been utilized in printing application due to their unique gelation properties. Below physiological temperatures, the pluronics exhibit low viscosity. However, at physiological temperatures, the pluronics form a gel. However, the formed gel is dominated by physical interactions. A more permanent pluronic-based network can be formed through the modification of the pluronic chain with acrylate groups that may be chemically cross-linked.

PEG

Polyethylene glycol Polyethylene glycol (PEG; ) is a polyether compound derived from petroleum with many applications, from industrial manufacturing to medicine. PEG is also known as polyethylene oxide (PEO) or polyoxyethylene (POE), depending on its molecular we ...

(PEG) is a synthetic polymer synthesized by

ethylene oxide Ethylene oxide is an organic compound with the chemical formula, formula . It is a cyclic ether and the simplest epoxide: a three-membered Ring (chemistry), ring consisting of one oxygen atom and two carbon atoms. Ethylene oxide is a colorless a ...

polymerization In polymer chemistry, polymerization (American English), or polymerisation (British English), is a process of reacting monomer, monomer molecules together in a chemical reaction to form polymer chains or three-dimensional networks. There are ...

. It is a favorable synthetic material because of its tailorable but typically strong mechanical properties. PEG advantages also include, non-cytotoxicity and non-immunogenicity. However, PEG is bioinert and needs to be combined with other biologically active hydrogels.

Other Bio-inks

Decellularized ECM

Decellularized

based bioinks can be derived from nearly any mammalian tissue. Organs such as heart, muscle, cartilage, bone, and fat are decellularized, lyophilized, and pulverized, to created a soluble matrix that can then be formed into gels. These bioinks possess several advantages over other materials due to their derivation from mature tissue. They consist of a complex mixture of ECM structural and decorating proteins specific to their tissue origin, and provide tissue-specific cues to cells. Often these bioinks are cross-linked through thermal gelation or chemical cross-linking such as through the use of riboflavin.

References

{{Reflist Biomaterials