SubstanceProteinSubunit

haste_fhir_model::r4::generated::resources

Struct SubstanceProteinSubunit 

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pub struct SubstanceProteinSubunit {
    pub id: Option<String>,
    pub extension: Option<Vec<Box<Extension>>>,
    pub modifierExtension: Option<Vec<Box<Extension>>>,
    pub subunit: Option<Box<FHIRInteger>>,
    pub sequence: Option<Box<FHIRString>>,
    pub length: Option<Box<FHIRInteger>>,
    pub sequenceAttachment: Option<Box<Attachment>>,
    pub nTerminalModificationId: Option<Box<Identifier>>,
    pub nTerminalModification: Option<Box<FHIRString>>,
    pub cTerminalModificationId: Option<Box<Identifier>>,
    pub cTerminalModification: Option<Box<FHIRString>>,
}
Expand description

This subclause refers to the description of each subunit constituting the SubstanceProtein. A subunit is a linear sequence of amino acids linked through peptide bonds. The Subunit information shall be provided when the finished SubstanceProtein is a complex of multiple sequences; subunits are not used to delineate domains within a single sequence. Subunits are listed in order of decreasing length; sequences of the same length will be ordered by decreasing molecular weight; subunits that have identical sequences will be repeated multiple times.

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§id: Option<String>

Unique id for the element within a resource (for internal references). This may be any string value that does not contain spaces.

§extension: Option<Vec<Box<Extension>>>

May be used to represent additional information that is not part of the basic definition of the element. To make the use of extensions safe and manageable, there is a strict set of governance applied to the definition and use of extensions. Though any implementer can define an extension, there is a set of requirements that SHALL be met as part of the definition of the extension.

§modifierExtension: Option<Vec<Box<Extension>>>

May be used to represent additional information that is not part of the basic definition of the element and that modifies the understanding of the element in which it is contained and/or the understanding of the containing element’s descendants. Usually modifier elements provide negation or qualification. To make the use of extensions safe and manageable, there is a strict set of governance applied to the definition and use of extensions. Though any implementer can define an extension, there is a set of requirements that SHALL be met as part of the definition of the extension. Applications processing a resource are required to check for modifier extensions.

Modifier extensions SHALL NOT change the meaning of any elements on Resource or DomainResource (including cannot change the meaning of modifierExtension itself).

§subunit: Option<Box<FHIRInteger>>

Index of primary sequences of amino acids linked through peptide bonds in order of decreasing length. Sequences of the same length will be ordered by molecular weight. Subunits that have identical sequences will be repeated and have sequential subscripts.

§sequence: Option<Box<FHIRString>>

The sequence information shall be provided enumerating the amino acids from N- to C-terminal end using standard single-letter amino acid codes. Uppercase shall be used for L-amino acids and lowercase for D-amino acids. Transcribed SubstanceProteins will always be described using the translated sequence; for synthetic peptide containing amino acids that are not represented with a single letter code an X should be used within the sequence. The modified amino acids will be distinguished by their position in the sequence.

§length: Option<Box<FHIRInteger>>

Length of linear sequences of amino acids contained in the subunit.

§sequenceAttachment: Option<Box<Attachment>>

The sequence information shall be provided enumerating the amino acids from N- to C-terminal end using standard single-letter amino acid codes. Uppercase shall be used for L-amino acids and lowercase for D-amino acids. Transcribed SubstanceProteins will always be described using the translated sequence; for synthetic peptide containing amino acids that are not represented with a single letter code an X should be used within the sequence. The modified amino acids will be distinguished by their position in the sequence.

§nTerminalModificationId: Option<Box<Identifier>>

Unique identifier for molecular fragment modification based on the ISO 11238 Substance ID.

§nTerminalModification: Option<Box<FHIRString>>

The name of the fragment modified at the N-terminal of the SubstanceProtein shall be specified.

§cTerminalModificationId: Option<Box<Identifier>>

Unique identifier for molecular fragment modification based on the ISO 11238 Substance ID.

§cTerminalModification: Option<Box<FHIRString>>

The modification at the C-terminal shall be specified.

Trait Implementations§

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impl Clone for SubstanceProteinSubunit

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fn clone(&self) -> SubstanceProteinSubunit

Returns a duplicate of the value. Read more
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fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source. Read more
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impl Debug for SubstanceProteinSubunit

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fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter. Read more
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impl Default for SubstanceProteinSubunit

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fn default() -> SubstanceProteinSubunit

Returns the “default value” for a type. Read more
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impl FHIRJSONDeserializer for SubstanceProteinSubunit

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fn from_json_str(s: &str) -> Result<Self, DeserializeError>

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fn from_serde_value( obj: &Value, context: Context<'_>, ) -> Result<Self, DeserializeError>

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impl FHIRJSONSerializer for SubstanceProteinSubunit

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fn serialize_value( &self, writer: &mut dyn Write, ) -> Result<bool, SerializeError>

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fn serialize_extension( &self, writer: &mut dyn Write, ) -> Result<bool, SerializeError>

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fn serialize_field( &self, field: &str, writer: &mut dyn Write, ) -> Result<bool, SerializeError>

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fn is_fp_primitive(&self) -> bool

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impl MetaValue for SubstanceProteinSubunit

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fn fields(&self) -> Vec<&'static str>

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fn get_field<'a>(&'a self, field: &str) -> Option<&'a dyn MetaValue>

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fn get_field_mut<'a>(&'a mut self, field: &str) -> Option<&'a mut dyn MetaValue>

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fn get_index_mut<'a>( &'a mut self, index: usize, ) -> Option<&'a mut dyn MetaValue>

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fn get_index<'a>(&'a self, _index: usize) -> Option<&'a dyn MetaValue>

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fn typename(&self) -> &'static str

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fn as_any(&self) -> &dyn Any

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fn flatten(&self) -> Vec<&dyn MetaValue>

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unsafe fn clone_to_uninit(&self, dest: *mut u8)

🔬This is a nightly-only experimental API. (clone_to_uninit)
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